bib.bib

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@ARTICLE{Aburn_2012,
  author = {Matthew J Aburn and C. A. Holmes and James A Roberts and Tjeerd W
	Boonstra and Michael Breakspear},
  title = {Critical fluctuations in cortical models near instability.},
  journal = {Front. Physiol.},
  year = {2012},
  volume = {3},
  pages = {331},
  abstract = {Computational studies often proceed from the premise that cortical
	dynamics operate in a linearly stable domain, where fluctuations
	dissipate quickly and show only short memory. Studies of human electroencephalography
	(EEG), however, have shown significant autocorrelation at time lags
	on the scale of minutes, indicating the need to consider regimes
	where non-linearities influence the dynamics. Statistical properties
	such as increased autocorrelation length, increased variance, power
	law scaling, and bistable switching have been suggested as generic
	indicators of the approach to bifurcation in non-linear dynamical
	systems. We study temporal fluctuations in a widely-employed computational
	model (the Jansen-Rit model) of cortical activity, examining the
	statistical signatures that accompany bifurcations. Approaching supercritical
	Hopf bifurcations through tuning of the background excitatory input,
	we find a dramatic increase in the autocorrelation length that depends
	sensitively on the direction in phase space of the input fluctuations
	and hence on which neuronal subpopulation is stochastically perturbed.
	Similar dependence on the input direction is found in the distribution
	of fluctuation size and duration, which show power law scaling that
	extends over four orders of magnitude at the Hopf bifurcation. We
	conjecture that the alignment in phase space between the input noise
	vector and the center manifold of the Hopf bifurcation is directly
	linked to these changes. These results are consistent with the possibility
	of statistical indicators of linear instability being detectable
	in real EEG time series. However, even in a simple cortical model,
	we find that these indicators may not necessarily be visible even
	when bifurcations are present because their expression can depend
	sensitively on the neuronal pathway of incoming fluctuations.},
  doi = {10.3389/fphys.2012.00331},
  institution = {School of Mathematics and Physics, The University of Queensland Brisbane,
	QLD, Australia.},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {22952464},
  timestamp = {2012.12.18},
  url = {http://dx.doi.org/10.3389/fphys.2012.00331}
}

@ARTICLE{Akberdin_2007,
  author = {Ilya R Akberdin and Evgeniy A Ozonov and Victoria V Mironova and
	Nadezda A Omelyanchuk and Vitaly A Likhoshvai and Dmytry N Gorpinchenko
	and Nikolai A Kolchanov},
  title = {A cellular automaton to model the development of primary shoot meristems
	of Arabidopsis thaliana.},
  journal = {J Bioinform Comput Biol},
  year = {2007},
  volume = {5},
  pages = {641--650},
  number = {2B},
  month = {Apr},
  abstract = {Development of organisms is a very complex process in which a lot
	of gene networks of different cell types are integrated. Development
	of a cellular automaton (Ermentrout and Edelshtein-Keshet, J Theor
	Biol 160:97-133, 1993) that models the morphodynamics of different
	cell types is the first step in understanding and analysis of the
	regulatory mechanisms underlying the functioning of developmental
	gene networks. A model of a cellular automaton has been developed,
	which simulates the embryonic development of shoot meristem in Arabidopsis
	thaliana. The model adequately describes the basic stages in development
	of this organ in wild and mutant types.},
  institution = {Institute of Cytology and Genetics SB RAS, Lavrentieva ave. 10 Novosibirsk,
	630090, Russia. akberdin@bionet.nsc.ru},
  keywords = {Arabidopsis Proteins, metabolism; Arabidopsis, physiology; Computer
	Simulation; Gene Expression Regulation, Developmental, physiology;
	Gene Expression Regulation, Plant, physiology; Meristem, physiology;
	Models, Biological; Morphogenesis, physiology; Plant Shoots, physiology;
	Signal Transduction, physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S0219720007002862},
  pmid = {17636867},
  timestamp = {2013.09.04}
}

@ARTICLE{Akil_2011,
  author = {Huda Akil and Maryann E Martone and David C Van Essen},
  title = {Challenges and opportunities in mining neuroscience data.},
  journal = {Science},
  year = {2011},
  volume = {331},
  pages = {708--712},
  number = {6018},
  month = {Feb},
  abstract = {Understanding the brain requires a broad range of approaches and methods
	from the domains of biology, psychology, chemistry, physics, and
	mathematics. The fundamental challenge is to decipher the "neural
	choreography" associated with complex behaviors and functions, including
	thoughts, memories, actions, and emotions. This demands the acquisition
	and integration of vast amounts of data of many types, at multiple
	scales in time and in space. Here we discuss the need for neuroinformatics
	approaches to accelerate progress, using several illustrative examples.
	The nascent field of "connectomics" aims to comprehensively describe
	neuronal connectivity at either a macroscopic level (in long-distance
	pathways for the entire brain) or a microscopic level (among axons,
	dendrites, and synapses in a small brain region). The Neuroscience
	Information Framework (NIF) encompasses all of neuroscience and facilitates
	the integration of existing knowledge and databases of many types.
	These examples illustrate the opportunities and challenges of data
	mining across multiple tiers of neuroscience information and underscore
	the need for cultural and infrastructure changes if neuroinformatics
	is to fulfill its potential to advance our understanding of the brain.},
  doi = {10.1126/science.1199305},
  institution = {The Molecular and Behavioral Neuroscience Institute, University of
	Michigan, Ann Arbor, MI, USA. akil@umich.edu},
  keywords = {Access to Information; Animals; Brain, anatomy /&/ histology/physiology;
	Computational Biology; Data Mining; Databases, Factual; Humans; Internet;
	Neural Pathways; Neurons, physiology; Neurosciences; Online Systems;
	Terminology as Topic},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {331/6018/708},
  pmid = {21311009},
  timestamp = {2012.12.27},
  url = {http://dx.doi.org/10.1126/science.1199305}
}

@ARTICLE{Albada_2010,
  author = {S. J. van Albada and C. C. Kerr and A. K I Chiang and C. J. Rennie
	and P. A. Robinson},
  title = {Neurophysiological changes with age probed by inverse modeling of
	EEG spectra.},
  journal = {Clin Neurophysiol},
  year = {2010},
  volume = {121},
  pages = {21--38},
  number = {1},
  month = {Jan},
  abstract = {To investigate age-associated changes in physiologically-based EEG
	spectral parameters in the healthy population.Eyes-closed EEG spectra
	of 1498 healthy subjects aged 6-86 years were fitted to a mean-field
	model of thalamocortical dynamics in a cross-sectional study. Parameters
	were synaptodendritic rates, cortical wave decay rates, connection
	strengths (gains), axonal delays for thalamocortical loops, and power
	normalizations. Age trends were approximated using smooth asymptotically
	linear functions with a single turning point. We also considered
	sex differences and relationships between model parameters and traditional
	quantitative EEG measures.The cross-sectional data suggest that changes
	tend to be most rapid in childhood, generally leveling off at age
	15-20 years. Most gains decrease in magnitude with age, as does power
	normalization. Axonal and dendritic delays decrease in childhood
	and then increase. Axonal delays and gains show small but significant
	sex differences.Mean-field brain modeling allows interpretation of
	age-associated EEG trends in terms of physiological processes, including
	the growth and regression of white matter, influencing axonal delays,
	and the establishment and pruning of synaptic connections, influencing
	gains.This study demonstrates the feasibility of inverse modeling
	of EEG spectra as a noninvasive method for investigating large-scale
	corticothalamic dynamics, and provides a basis for future comparisons.},
  doi = {10.1016/j.clinph.2009.09.021},
  institution = {School of Physics, The University of Sydney, NSW 2006, Australia.
	s.van.albada@fz-juelich.de},
  keywords = {Adolescent; Adult; Aged; Aged, 80 and over; Aging, physiology; Axons;
	Cerebral Cortex, physiology; Child; Cross-Sectional Studies; Dendrites;
	Electroencephalography; Female; Humans; Male; Middle Aged; Models,
	Neurological; Sex Factors; Thalamus, physiology; Time Factors; Young
	Adult},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S1388-2457(09)00571-9},
  pmid = {19854102},
  timestamp = {2013.08.19},
  url = {http://dx.doi.org/10.1016/j.clinph.2009.09.021}
}

@ARTICLE{Albada_2013,
  author = {S. J. van Albada and P. A. Robinson},
  title = {Relationships between Electroencephalographic Spectral Peaks Across
	Frequency Bands.},
  journal = {Front Hum Neurosci},
  year = {2013},
  volume = {7},
  pages = {56},
  abstract = {The degree to which electroencephalographic spectral peaks are independent,
	and the relationships between their frequencies have been debated.
	A novel fitting method was used to determine peak parameters in the
	range 2-35 Hz from a large sample of eyes-closed spectra, and their
	interrelationships were investigated. Findings were compared with
	a mean-field model of thalamocortical activity, which predicts near-harmonic
	relationships between peaks. The subject set consisted of 1424 healthy
	subjects from the Brain Resource International Database. Peaks in
	the theta range occurred on average near half the alpha peak frequency,
	while peaks in the beta range tended to occur near twice and three
	times the alpha peak frequency on an individual-subject basis. Moreover,
	for the majority of subjects, alpha peak frequencies were significantly
	positively correlated with frequencies of peaks in the theta and
	low and high beta ranges. Such a harmonic progression agrees semiquantitatively
	with theoretical predictions from the mean-field model. These findings
	indicate a common or analogous source for different rhythms, and
	help to define appropriate individual frequency bands for peak identification.},
  doi = {10.3389/fnhum.2013.00056},
  institution = {Institute of Neuroscience and Medicine (INM-6) and Institute for
	Advanced Simulation (IAS-6), Jülich Research Centre and Jülich-Aachen
	Research Alliance Jülich, Germany ; School of Physics, The University
	of Sydney Sydney, NSW, Australia ; Brain Dynamics Center, Sydney
	Medical School - Western, University of Sydney Sydney, NSW, Australia.},
  language = {eng},
  medline-pst = {epublish},
  owner = {paula},
  pmid = {23483663},
  timestamp = {2013.08.19},
  url = {http://dx.doi.org/10.3389/fnhum.2013.00056}
}

@ARTICLE{Albada_2009,
  author = {S. J. van Albada and P. A. Robinson},
  title = {Mean-field modeling of the basal ganglia-thalamocortical system.
	I Firing rates in healthy and parkinsonian states.},
  journal = {J Theor Biol},
  year = {2009},
  volume = {257},
  pages = {642--663},
  number = {4},
  month = {Apr},
  abstract = {Parkinsonism leads to various electrophysiological changes in the
	basal ganglia-thalamocortical system (BGTCS), often including elevated
	discharge rates of the subthalamic nucleus (STN) and the output nuclei,
	and reduced activity of the globus pallidus external (GPe) segment.
	These rate changes have been explained qualitatively in terms of
	the direct/indirect pathway model, involving projections of distinct
	striatal populations to the output nuclei and GPe. Although these
	populations partly overlap, evidence suggests dopamine depletion
	differentially affects cortico-striato-pallidal connection strengths
	to the two pallidal segments. Dopamine loss may also decrease the
	striatal signal-to-noise ratio, reducing both corticostriatal coupling
	and striatal firing thresholds. Additionally, nigrostriatal degeneration
	may cause secondary changes including weakened lateral inhibition
	in the GPe, and mesocortical dopamine loss may decrease intracortical
	excitation and especially inhibition. Here a mean-field model of
	the BGTCS is presented with structure and parameter estimates closely
	based on physiology and anatomy. Changes in model rates due to the
	possible effects of dopamine loss listed above are compared with
	experiment. Our results suggest that a stronger indirect pathway,
	possibly combined with a weakened direct pathway, is compatible with
	empirical evidence. However, altered corticostriatal connection strengths
	are probably not solely responsible for substantially increased STN
	activity often found. A lower STN firing threshold, weaker intracortical
	inhibition, and stronger striato-GPe inhibition help explain the
	relatively large increase in STN rate. Reduced GPe-GPe inhibition
	and a lower GPe firing threshold can account for the comparatively
	small decrease in GPe rate frequently observed. Changes in cortex,
	GPe, and STN help normalize the cortical rate, also in accord with
	experiments. The model integrates the basal ganglia into a unified
	framework along with an existing thalamocortical model that already
	accounts for a wide range of electrophysiological phenomena. A companion
	paper discusses the dynamics and oscillations of this combined system.},
  doi = {10.1016/j.jtbi.2008.12.018},
  institution = {School of Physics, The University of Sydney, New South Wales 2006,
	Australia. albada@physics.usyd.edu.au},
  keywords = {Adult; Animals; Basal Ganglia, physiology/physiopathology; Cerebral
	Cortex, physiology/physiopathology; Humans; Models, Neurological;
	Neural Inhibition, physiology; Neural Pathways, physiology; Parkinsonian
	Disorders, physiopathology; Subthalamic Nucleus, physiology/physiopathology;
	Thalamus, physiology/physiopathology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S0022-5193(08)00648-6},
  pmid = {19168074},
  timestamp = {2013.08.19},
  url = {http://dx.doi.org/10.1016/j.jtbi.2008.12.018}
}

@ARTICLE{Amari_1977,
  author = {Amari, SI},
  title = {Dynamics of pattern formation in lateral-inhibition type neural fields.},
  journal = {Biol. Cybern.},
  year = {1977},
  volume = {22},
  pages = {77-87},
  keywords = {dynamics},
  owner = {paula},
  timestamp = {2012.10.18}
}

@ARTICLE{Amari_1975,
  author = {Amari, SI},
  title = {Homogeneous nets of neuron-like elements.},
  journal = {Biol. Cybern.},
  year = {1975},
  volume = {17},
  pages = {211--220},
  number = {4},
  month = mar,
  abstract = {{Abstract\ \ Propagation and reverberation of excitation
	patterns are investigated for 1-dimensional and 2-dimensional homogeneous
	nets of neuron-like elements. A 1-dimensional net has a proper set
	of excitation patterns which only can be conducted in the net. Such
	a net has an ability of discriminating and shaping stimulus signals.
	Two types of self-reproducing reverberatory excitation patterns are
	shown for 2-dimensional homogeneous nets. An algebraic theory of
	general homogeneous nets is also developed.}},
  citeulike-article-id = {5813013},
  citeulike-linkout-0 = {http://dx.doi.org/10.1007/bf00339367},
  citeulike-linkout-1 = {http://www.springerlink.com/content/e0v5x54827165122},
  day = {27},
  doi = {10.1007/bf00339367},
  keywords = {bump, neural\_field},
  posted-at = {2009-09-21 13:15:42},
  priority = {2},
  url = {http://dx.doi.org/10.1007/bf00339367}
}

@ARTICLE{Amunts_2013,
  author = {Katrin Amunts and Claude Lepage and Louis Borgeat and Hartmut Mohlberg
	and Timo Dickscheid and Marc-Étienne Rousseau and Sebastian Bludau
	and Pierre-Louis Bazin and Lindsay B Lewis and Ana-Maria Oros-Peusquens
	and Nadim J Shah and Thomas Lippert and Karl Zilles and Alan C Evans},
  title = {BigBrain: an ultrahigh-resolution 3D human brain model.},
  journal = {Science},
  year = {2013},
  volume = {340},
  pages = {1472--1475},
  number = {6139},
  month = {Jun},
  abstract = {Reference brains are indispensable tools in human brain mapping, enabling
	integration of multimodal data into an anatomically realistic standard
	space. Available reference brains, however, are restricted to the
	macroscopic scale and do not provide information on the functionally
	important microscopic dimension. We created an ultrahigh-resolution
	three-dimensional (3D) model of a human brain at nearly cellular
	resolution of 20 micrometers, based on the reconstruction of 7404
	histological sections. "BigBrain" is a free, publicly available tool
	that provides considerable neuroanatomical insight into the human
	brain, thereby allowing the extraction of microscopic data for modeling
	and simulation. BigBrain enables testing of hypotheses on optimal
	path lengths between interconnected cortical regions or on spatial
	organization of genetic patterning, redefining the traditional neuroanatomy
	maps such as those of Brodmann and von Economo.},
  doi = {10.1126/science.1235381},
  institution = {Institute of Neuroscience and Medicine (INM-1, INM-4), Research Centre
	Jülich, Jülich, Germany. k.amunts@fz-juelich.de},
  keywords = {Aged; Brain Mapping; Brain, anatomy /&/ histology/cytology; Cerebral
	Cortex, anatomy /&/ histology/cytology; Female; Humans; Image Processing,
	Computer-Assisted; Imaging, Three-Dimensional; Magnetic Resonance
	Imaging; Microtomy},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {340/6139/1472},
  pmid = {23788795},
  timestamp = {2013.07.04},
  url = {http://dx.doi.org/10.1126/science.1235381}
}

@ARTICLE{Aquino_2012,
  author = {Kevin M Aquino and Mark M Schira and P. A. Robinson and Peter M Drysdale
	and Michael Breakspear},
  title = {Hemodynamic traveling waves in human visual cortex.},
  journal = {PLoS Comput. Biol.},
  year = {2012},
  volume = {8},
  pages = {e1002435},
  number = {3},
  abstract = {Functional MRI (fMRI) experiments rely on precise characterization
	of the blood oxygen level dependent (BOLD) signal. As the spatial
	resolution of fMRI reaches the sub-millimeter range, the need for
	quantitative modelling of spatiotemporal properties of this hemodynamic
	signal has become pressing. Here, we find that a detailed physiologically-based
	model of spatiotemporal BOLD responses predicts traveling waves with
	velocities and spatial ranges in empirically observable ranges. Two
	measurable parameters, related to physiology, characterize these
	waves: wave velocity and damping rate. To test these predictions,
	high-resolution fMRI data are acquired from subjects viewing discrete
	visual stimuli. Predictions and experiment show strong agreement,
	in particular confirming BOLD waves propagating for at least 5-10
	mm across the cortical surface at speeds of 2-12 mm s-1. These observations
	enable fundamentally new approaches to fMRI analysis, crucial for
	fMRI data acquired at high spatial resolution.},
  doi = {10.1371/journal.pcbi.1002435},
  institution = {School of Physics, University of Sydney, New South Wales, Australia.
	aquino@physics.usyd.edu.au},
  keywords = {Biological Clocks, physiology; Blood Flow Velocity, physiology; Cerebrovascular
	Circulation, physiology; Computer Simulation; Humans; Magnetic Resonance
	Imaging, methods; Models, Cardiovascular; Models, Neurological; Visual
	Cortex, physiology; Visual Perception, physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {PCOMPBIOL-D-11-01560},
  pmid = {22457612},
  timestamp = {2013.02.18},
  url = {http://dx.doi.org/10.1371/journal.pcbi.1002435}
}

@ARTICLE{Assisi_2005,
  author = {Assisi, CG and Jirsa, VK and Kelso, JAS},
  title = {Synchrony and clustering in heterogeneous networks with global coupling
	and parameter dispersion},
  journal = {Phys. Rev. Lett.},
  year = {2005},
  volume = {94},
  pages = {94},
  number = {1},
  owner = {paula},
  timestamp = {2012.10.18}
}

@ARTICLE{Attay_2006,
  author = {Atay, F. and Hutt, A.},
  title = {Neural Fields with Distributed Transmission Speeds and Long Range
	Feedback Delays},
  journal = {SIAD},
  year = {2006},
  volume = {5},
  pages = {670-698},
  number = {4},
  doi = {10.1137/050629367},
  eprint = {http://epubs.siam.org/doi/pdf/10.1137/050629367},
  url = {http://epubs.siam.org/doi/abs/10.1137/050629367}
}

@ARTICLE{Attay_2005,
  author = {Atay, F. and Hutt, A.},
  title = {Stability and Bifurcations in Neural Fields with Finite Propagation
	Speed and General Connectivity},
  journal = {SIAP},
  year = {2005},
  volume = {65},
  pages = {644-666},
  abstract = {Linear bifurcation analysis for IDEs for general connectivities involving
	large but finite propagation speeds, comparison of analytical results
	to numerical results, graphical criterion for phase transitions by
	Fourier components of connectivity function},
  comment = {SIAM Journal on Applied Mathematics (SIAP)},
  owner = {paupau},
  timestamp = {2013.05.01}
}

@ARTICLE{Axer_2011a,
  author = {Markus Axer and Katrin Amunts and David Grässel and Christoph Palm
	and Jürgen Dammers and Hubertus Axer and Uwe Pietrzyk and Karl Zilles},
  title = {A novel approach to the human connectome: ultra-high resolution mapping
	of fiber tracts in the brain.},
  journal = {Neuroimage},
  year = {2011},
  volume = {54},
  pages = {1091--1101},
  number = {2},
  month = {Jan},
  abstract = {Signal transmission between different brain regions requires connecting
	fiber tracts, the structural basis of the human connectome. In contrast
	to animal brains, where a multitude of tract tracing methods can
	be used, magnetic resonance (MR)-based diffusion imaging is presently
	the only promising approach to study fiber tracts between specific
	human brain regions. However, this procedure has various inherent
	restrictions caused by its relatively low spatial resolution. Here,
	we introduce 3D-polarized light imaging (3D-PLI) to map the three-dimensional
	course of fiber tracts in the human brain with a resolution at a
	submillimeter scale based on a voxel size of 100 μm isotropic or
	less. 3D-PLI demonstrates nerve fibers by utilizing their intrinsic
	birefringence of myelin sheaths surrounding axons. This optical method
	enables the demonstration of 3D fiber orientations in serial microtome
	sections of entire human brains. Examples for the feasibility of
	this novel approach are given here. 3D-PLI enables the study of brain
	regions of intense fiber crossing in unprecedented detail, and provides
	an independent evaluation of fiber tracts derived from diffusion
	imaging data.},
  doi = {10.1016/j.neuroimage.2010.08.075},
  institution = {Institute of Neuroscience and Medicine (INM-1, INM-2, INM-4), Research
	Centre Jülich, Jülich, Germany. m.axer@fz-juelich.de},
  keywords = {Birefringence; Brain Mapping, methods; Brain, ultrastructure; Humans;
	Image Processing, Computer-Assisted, methods; Imaging, Three-Dimensional,
	methods; Nerve Fibers, ultrastructure; Neural Pathways, anatomy /&/
	histology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S1053-8119(10)01178-X},
  pmid = {20832489},
  timestamp = {2013.07.04},
  url = {http://dx.doi.org/10.1016/j.neuroimage.2010.08.075}
}

@ARTICLE{Axer_2011,
  author = {Markus Axer and David Grässel and Melanie Kleiner and Jürgen Dammers
	and Timo Dickscheid and Julia Reckfort and Tim Hütz and Björn Eiben
	and Uwe Pietrzyk and Karl Zilles and Katrin Amunts},
  title = {High-resolution fiber tract reconstruction in the human brain by
	means of three-dimensional polarized light imaging.},
  journal = {Front Neuroinform},
  year = {2011},
  volume = {5},
  pages = {34},
  abstract = {Functional interactions between different brain regions require connecting
	fiber tracts, the structural basis of the human connectome. To assemble
	a comprehensive structural understanding of neural network elements
	from the microscopic to the macroscopic dimensions, a multimodal
	and multiscale approach has to be envisaged. However, the integration
	of results from complementary neuroimaging techniques poses a particular
	challenge. In this paper, we describe a steadily evolving neuroimaging
	technique referred to as three-dimensional polarized light imaging
	(3D-PLI). It is based on the birefringence of the myelin sheaths
	surrounding axons, and enables the high-resolution analysis of myelinated
	axons constituting the fiber tracts. 3D-PLI provides the mapping
	of spatial fiber architecture in the postmortem human brain at a
	sub-millimeter resolution, i.e., at the mesoscale. The fundamental
	data structure gained by 3D-PLI is a comprehensive 3D vector field
	description of fibers and fiber tract orientations - the basis for
	subsequent tractography. To demonstrate how 3D-PLI can contribute
	to unravel and assemble the human connectome, a multiscale approach
	with the same technology was pursued. Two complementary state-of-the-art
	polarimeters providing different sampling grids (pixel sizes of 100
	and 1.6 μm) were used. To exemplarily highlight the potential of
	this approach, fiber orientation maps and 3D fiber models were reconstructed
	in selected regions of the brain (e.g., Corpus callosum, Internal
	capsule, Pons). The results demonstrate that 3D-PLI is an ideal tool
	to serve as an interface between the microscopic and macroscopic
	levels of organization of the human connectome.},
  doi = {10.3389/fninf.2011.00034},
  institution = {Institute of Neuroscience and Medicine (INM-1, INM-2, INM-4), Research
	Centre Jülich and Jülich Aachen Research Alliance Jülich, Germany.},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {22232597},
  timestamp = {2013.07.04},
  url = {http://dx.doi.org/10.3389/fninf.2011.00034}
}

@ARTICLE{Baars_2012,
  author = {Bernard J Baars and David B Edelman},
  title = {Consciousness, biology and quantum hypotheses.},
  journal = {Phys. Life. Rev.},
  year = {2012},
  volume = {9},
  pages = {285--294},
  number = {3},
  month = {Sep},
  abstract = {Natural phenomena are reducible to quantum events in principle, but
	quantum mechanics does not always provide the best level of analysis.
	The many-body problem, chaotic avalanches, materials properties,
	biological organisms, and weather systems are better addressed at
	higher levels. Animals are highly organized, goal-directed, adaptive,
	selectionist, information-preserving, functionally redundant, multicellular,
	quasi-autonomous, highly mobile, reproducing, dissipative systems
	that conserve many fundamental features over remarkably long periods
	of time at the species level. Animal brains consist of massive, layered
	networks of specialized signaling cells with 10,000 communication
	points per cell, and interacting up to 1000 Hz. Neurons begin to
	divide and differentiate very early in gestation, and continue to
	develop until middle age. Waking brains operate far from thermodynamic
	equilibrium under delicate homeostatic control, making them extremely
	sensitive to a range of physical and chemical stimuli, highly adaptive,
	and able to produce a remarkable range of goal-relevant actions.
	Consciousness is "a difference that makes a difference" at the level
	of massive neuronal interactions in the most parallel-interactive
	anatomical structure of the mammalian brain, the cortico-thalamic
	(C-T) system. Other brain structures are not established to result
	in direct conscious experiences, at least in humans. However, indirect
	extra-cortical influences on the C-T system are pervasive. Learning,
	brain plasticity and major life adaptations may require conscious
	cognition. While brains evolved over hundreds of millions of years,
	and individual brains grow over months, years and decades, conscious
	events appear to have a duty cycle of ∼100 ms, fading after a few
	seconds. They can of course be refreshed by inner rehearsal, re-visualization,
	or attending to recurrent stimulus sources. These very distinctive
	brain events are needed when animals seek out and cope with new,
	unpredictable and highly valued life events, such as evading predators,
	gathering critical information, seeking mates and hunting prey. Attentional
	selection of conscious events can be observed behaviorally in animals
	showing coordinated receptor orienting, flexible responding, alertness,
	emotional reactions, seeking, motivation and curiosity, as well as
	behavioral surprise and cortical and autonomic arousal. Brain events
	corresponding to attentional selection are prominent and widespread.
	Attention generally results in conscious experiences, which may be
	needed to recruit widespread processing resources in the brain. Many
	neuronal processes never become conscious, such as the balance system
	of the inner ear. An air traveler may "see" the passenger cabin tilt
	downward as the plane tilts to descend for a landing. That visual
	experience occurs even at night, when the traveler has no external
	frame of spatial reference. The passenger's body tilt with respect
	to gravity is detected unconsciously via the hair cells of the vestibular
	canals, which act as liquid accelerometers. However, that sensory
	activity is not experienced directly. It only becomes conscious via
	vision and the body senses. The vestibular sense is therefore quite
	different from visual perception, which "reports" accurately to a
	conscious field of experience, so that we can point accurately to
	a bright star on a dark night. Vestibular input is also precise but
	unconscious. Conscious cognition is therefore a distinct kind of
	brain event. Many of its features are well established, and must
	be accounted for by any adequate theory. No non-biological examples
	are known. Penrose and Hameroff have proposed that consciousness
	may be viewed as a fundamental problem in quantum physics. Specifically,
	their 'orchestrated objective reduction' (Orch-OR) hypothesis posits
	that conscious states arise from quantum computations in the microtubules
	of neurons. However, a number of microtubule-associated proteins
	are found in both plant and animal cells (like neurons) and plants
	are not generally considered to be conscious. Current quantum-level
	proposals do not explain the prominent empirical features of consciousness.
	Notably, they do not distinguish between closely matched conscious
	and unconscious brain events, as cognitive-biological theories must.
	About half of the human brain does not support conscious contents
	directly, yet neurons in these "unconscious" brain regions contain
	large numbers of microtubules. QM phenomena are famously observer-dependent,
	but to the best of our knowledge it has not been shown that they
	require a conscious observer, as opposed to a particle detector.
	Conscious humans cannot detect quantum events "as such" without the
	aid of special instrumentation. Instead, we categorize the wavelengths
	of light into conscious sensory events that neglect their quantum
	mechanical properties. In science the burden of proof is on the proposer,
	and this burden has not yet been met by quantum-level proposals.
	While in the future we may discover quantum effects that bear distinctively
	on conscious cognition 'as such,' we do not have such evidence today.},
  doi = {10.1016/j.plrev.2012.07.001},
  institution = {The Neurosciences Institute, San Diego, CA 92121, United States.
	baars@nsi.edu},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S1571-0645(12)00084-X},
  pmid = {22925839},
  timestamp = {2013.03.05},
  url = {http://dx.doi.org/10.1016/j.plrev.2012.07.001}
}

@ARTICLE{Babajani_2005,
  author = {Babajani, Abbas and Nekooei, Mohammad-Hossein and Soltanian-Zadeh,
	Hamid},
  title = {Integrated MEG and fMRI model: synthesis and analysis.},
  journal = {Brain Topogr.},
  year = {2005},
  volume = {18},
  pages = {101--113},
  number = {2},
  abstract = {An integrated model for magnetoencephalography (MEG) and functional
	Magnetic Resonance Imaging (fMRI) is proposed. In the model, the
	neural activity is related to the Post Synaptic Potentials (PSPs)
	which is common link between MEG and fMRI. Each PSP is modeled by
	the direction and strength of its current flow which are treated
	as random variables. The overall neural activity in each voxel is
	used for equivalent current dipole in MEG and as input of extended
	Balloon model in fMRI. The proposed model shows the possibility of
	detecting activation by fMRI in a voxel while the voxel is silent
	for MEG and vice versa. Parameters of the model can illustrate situations
	like closed field due to non-pyramidal cells, canceling effect of
	inhibitory PSP on excitatory PSP, and effect of synchronicity. In
	addition, the model shows that the crosstalk from neural activities
	of the adjacent voxels in fMRI may result in the detection of activations
	in these voxels that contain no neural activities. The proposed model
	is instrumental in evaluating and comparing different analysis methods
	of MEG and fMRI. It is also useful in characterizing the upcoming
	combined methods for simultaneous analysis of MEG and fMRI.},
  doi = {10.1007/s10548-005-0279-5},
  institution = {Control and Intelligent Processing Center of Excellence, Electrical
	and Computer Engineering Department, University of Tehran, Tehran,
	Iran.},
  keywords = {Algorithms; Excitatory Postsynaptic Potentials, physiology; Humans;
	Image Processing, Computer-Assisted, statistics /&/ numerical data;
	Linear Models; Magnetic Resonance Imaging, statistics /&/ numerical
	data; Magnetoencephalography, statistics /&/ numerical data; Models,
	Statistical; Oxygen, blood},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paupau},
  pmid = {16341578},
  timestamp = {2013.04.09},
  url = {http://dx.doi.org/10.1007/s10548-005-0279-5}
}

@ARTICLE{Babajani_2006,
  author = {Babajani, Abbas and Soltanian-Zadeh, Hamid},
  title = {Integrated MEG/EEG and fMRI model based on neural masses.},
  journal = {IEEE Trans. Biomed. Eng.},
  year = {2006},
  volume = {53},
  pages = {1794--1801},
  number = {9},
  month = {Sep},
  abstract = {We introduce a bottom-up model for integrating electroencephalography
	(EEG) or magnetoencephalography (MEG) with functional magnetic resonance
	imaging (fMRI). An extended neural mass model is proposed based on
	the physiological principles of cortical minicolumns and their connections.
	The fMRI signal is extracted from the proposed neural mass model
	by introducing a relationship between the stimulus and the neural
	activity and using the resultant neural activity as input of the
	extended Balloon model. The proposed model, validated using simulations,
	is instrumental in evaluating the upcoming combined methods for simultaneous
	analysis of MEG/EEG and fMRI.},
  doi = {10.1109/TBME.2006.873748},
  institution = {Control and Intelligent Processing Center of Excellence, Electrical
	and Computer Engineering Department, University of Tehran, Iran.
	a.babajani@ece.ut.ac.ir},
  keywords = {Algorithms; Brain Mapping, methods; Brain, physiology; Computer Simulation;
	Diagnosis, Computer-Assisted, methods; Electroencephalography, methods;
	Evoked Potentials, physiology; Humans; Magnetic Resonance Imaging,
	methods; Magnetoencephalography, methods; Models, Neurological; Nerve
	Net, physiology; Systems Integration},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paupau},
  pmid = {16941835},
  timestamp = {2013.04.09},
  url = {http://dx.doi.org/10.1109/TBME.2006.873748}
}

@ARTICLE{Babajani_2012,
  author = {Babajani, Gholamreza and Tropak, Michael B. and Mahuran, Don J. and
	Kermode, Allison R.},
  title = {Pharmacological chaperones facilitate the post-ER transport of recombinant
	N370S mutant β-glucocerebrosidase in plant cells: evidence that N370S
	is a folding mutant.},
  journal = {Mol. Genet. Metab.},
  year = {2012},
  volume = {106},
  pages = {323--329},
  number = {3},
  month = {Jul},
  abstract = {Gaucher disease is a prevalent lysosomal storage disease in which
	affected individuals inherit mutations in the gene (GBA1) encoding
	lysosomal acid β-glucosidase (glucocerebrosidase, GCase, EC 3.2.1.45).
	One of the most prevalent disease-causing mutations in humans is
	a N370S missense mutation in the GCase protein. As part of a larger
	endeavor to study the fate of mutant human proteins expressed in
	plant cells, the N370S mutant protein along with the wild-type- (WT)-GCase,
	both equipped with a signal peptide, were synthesized in transgenic
	tobacco BY2 cells, which do not possess lysosomes. The enzymatic
	activity of plant-recombinant N370S GCase lines was significantly
	lower (by 81-95\%) than that of the WT-GCase lines. In contrast to
	the WT-GCase protein, which was efficiently secreted from tobacco
	BY2 cells, and detected in large amounts in the culture medium, only
	a small proportion of the N370S GCase was secreted. Pharmacological
	chaperones such as N-(n-nonyl) deoxynojirimycin and ambroxol increased
	the steady-state mutant protein levels both inside the plant cells
	and in the culture medium. These findings contradict the assertion
	that small molecule chaperones increase N370S GCase activity (as
	assayed in treated patient cell lysates) by stabilizing the enzyme
	in the lysosome, and suggest that the mutant protein is impaired
	in its ability to obtain its functional folded conformation, which
	is a requirement for exiting the lumen of the ER.},
  doi = {10.1016/j.ymgme.2012.04.018},
  institution = {Department of Biological Sciences, Simon Fraser University, 8888
	University Dr., Burnaby, BC, Canada V5A 1S6.},
  keywords = {Biological Transport; Catalytic Domain; Cells, Cultured; Endoplasmic
	Reticulum, metabolism; Gaucher Disease, enzymology/genetics; Glucosylceramidase,
	genetics/metabolism; Humans; Molecular Chaperones, genetics/metabolism;
	Mutation; Plant Cells, metabolism; Plants, Genetically Modified;
	Protein Folding; Recombinant Proteins, genetics/metabolism},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paupau},
  pii = {S1096-7192(12)00161-8},
  pmid = {22592100},
  timestamp = {2013.04.09},
  url = {http://dx.doi.org/10.1016/j.ymgme.2012.04.018}
}

@ARTICLE{Babajani_2010,
  author = {Babajani-Feremi, Abbas and Soltanian-Zadeh, Hamid},
  title = {Multi-area neural mass modeling of EEG and MEG signals.},
  journal = {Neuroimage},
  year = {2010},
  volume = {52},
  pages = {793--811},
  number = {3},
  month = {Sep},
  abstract = {We previously proposed an integrated electroencephalography (EEG),
	magnetoencephalography (MEG), and functional Magnetic Resonance Imaging
	(fMRI) model based on an extended neural mass model (ENMM) within
	a single cortical area. In the ENMM, a cortical area contains several
	minicolumns where strengths of their connections diminish exponentially
	with their distances. The ENMM was derived based on the physiological
	principles of the cortical minicolumns and their connections within
	a single cortical area to generate EEG, MEG, and fMRI signals. The
	purpose of this paper is to further extend the ENMM model from a
	single-area to a multi-area model to develop a neural mass model
	of the entire brain that generates EEG and MEG signals. For multi-area
	modeling, two connection types are considered: short-range connections
	(SRCs) and long-range connections (LRCs). The intra-area SRCs among
	the minicolumns within the areas were previously modeled in the ENMM.
	To define inter-area LRCs among the cortical areas, we consider that
	the cell populations of all minicolumns in the destination area are
	affected by the excitatory afferent of the pyramidal cells of all
	minicolumns in the source area. The state-space representation of
	the multi-area model is derived considering the intra-minicolumn,
	SRCs', and LRCs' parameters. Using simulations, we evaluate effects
	of parameters of the model on its dynamics and, based on stability
	analysis, find valid ranges for parameters of the model. In addition,
	we evaluate reducing redundancy of the model parameters using simulation
	results and conclude that the parameters of the model can be limited
	to the LRCs and SRCs while the intra-minicolumn parameters stay at
	their physiological mean values. The proposed multi-area integrated
	E/MEG model provides an efficient neuroimaging technique for effective
	connectivity analysis in healthy subjects as well as neurological
	and psychiatric patients.},
  doi = {10.1016/j.neuroimage.2010.01.034},
  institution = {Image Analysis Lab., Radiology Department, Henry Ford Hospital, One
	Ford Place, 2F, Detroit, MI 48202, USA. abbasb@rad.hfh.edu},
  keywords = {Brain Mapping, methods; Brain, physiology; Electroencephalography;
	Humans; Magnetic Resonance Imaging; Magnetoencephalography; Models,
	Neurological; Nerve Net},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paupau},
  pii = {S1053-8119(10)00054-6},
  pmid = {20080193},
  timestamp = {2013.04.14},
  url = {http://dx.doi.org/10.1016/j.neuroimage.2010.01.034}
}

@ARTICLE{Bakker_2012,
  author = {Rembrandt Bakker and Thomas Wachtler and Markus Diesmann},
  title = {CoCoMac 2.0 and the future of tract-tracing databases.},
  journal = {Front. Neuroinform.},
  year = {2012},
  volume = {6},
  pages = {30},
  abstract = {The CoCoMac database contains the results of several hundred published
	axonal tract-tracing studies in the macaque monkey brain. The combined
	results are used for constructing the macaque macro-connectome. Here
	we discuss the redevelopment of CoCoMac and compare it to six connectome-related
	projects: two online resources that provide full access to raw tracing
	data in rodents, a connectome viewer for advanced 3D graphics, a
	partial but highly detailed rat connectome, a brain data management
	system that generates custom connectivity matrices, and a software
	package that covers the complete pipeline from connectivity data
	to large-scale brain simulations. The second edition of CoCoMac features
	many enhancements over the original. For example, a search wizard
	is provided for full access to all tables and their nested dependencies.
	Connectivity matrices can be computed on demand in a user-selected
	nomenclature. A new data entry system is available as a preview,
	and is to become a generic solution for community-driven data entry
	in manually collated databases. We conclude with the question whether
	neuronal tracing will remain the gold standard to uncover the wiring
	of brains, thereby highlighting developments in human connectome
	construction, tracer substances, polarized light imaging, and serial
	block-face scanning electron microscopy.},
  doi = {10.3389/fninf.2012.00030},
  institution = {Donders Institute for Brain, Cognition and Behaviour, Radboud University
	Nijmegen Nijmegen, Netherlands ; Institute of Neuroscience and Medicine
	6, Research Center Jülich Jülich, Germany ; Department Biology II,
	Ludwig-Maximilians-Universität München Munich, Germany.},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {23293600},
  timestamp = {2013.02.18},
  url = {http://dx.doi.org/10.3389/fninf.2012.00030}
}

@ARTICLE{Bangera_2010,
  author = {Nitin B Bangera and Donald L Schomer and Nima Dehghani and Istvan
	Ulbert and Sydney Cash and Steve Papavasiliou and Solomon R Eisenberg
	and Anders M Dale and Eric Halgren},
  title = {Experimental validation of the influence of white matter anisotropy
	on the intracranial EEG forward solution.},
  journal = {J. Comput. Neurosci.},
  year = {2010},
  volume = {29},
  pages = {371--387},
  number = {3},
  month = {Dec},
  abstract = {Forward solutions with different levels of complexity are employed
	for localization of current generators, which are responsible for
	the electric and magnetic fields measured from the human brain. The
	influence of brain anisotropy on the forward solution is poorly understood.
	The goal of this study is to validate an anisotropic model for the
	intracranial electric forward solution by comparing with the directly
	measured 'gold standard'. Dipolar sources are created at known locations
	in the brain and intracranial electroencephalogram (EEG) is recorded
	simultaneously. Isotropic models with increasing level of complexity
	are generated along with anisotropic models based on Diffusion tensor
	imaging (DTI). A Finite Element Method based forward solution is
	calculated and validated using the measured data. Major findings
	are (1) An anisotropic model with a linear scaling between the eigenvalues
	of the electrical conductivity tensor and water self-diffusion tensor
	in brain tissue is validated. The greatest improvement was obtained
	when the stimulation site is close to a region of high anisotropy.
	The model with a global anisotropic ratio of 10:1 between the eigenvalues
	(parallel: tangential to the fiber direction) has the worst performance
	of all the anisotropic models. (2) Inclusion of cerebrospinal fluid
	as well as brain anisotropy in the forward model is necessary for
	an accurate description of the electric field inside the skull. The
	results indicate that an anisotropic model based on the DTI can be
	constructed non-invasively and shows an improved performance when
	compared to the isotropic models for the calculation of the intracranial
	EEG forward solution.},
  doi = {10.1007/s10827-009-0205-z},
  institution = {Department of Biomedical Engineering, Boston University, Boston,
	MA, USA. nitinb@bu.edu},
  keywords = {Algorithms; Anisotropy; Brain, physiology; Cerebrospinal Fluid, physiology;
	Data Interpretation, Statistical; Diffusion Magnetic Resonance Imaging;
	Electric Conductivity; Electrodes; Electroencephalography, statistics
	/&/ numerical data; Finite Element Analysis; Head; Humans; Image
	Processing, Computer-Assisted; Linear Models; Models, Neurological;
	Reproducibility of Results; Skull, anatomy /&/ histology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {20063051},
  timestamp = {2013.04.17},
  url = {http://dx.doi.org/10.1007/s10827-009-0205-z}
}

@ARTICLE{Barnard_1967,
  author = {Barnard, ACL and Duck, IM and Lynn, MS and Timlake, WP},
  title = {The Application of Electromagnetic Theory to Electrocardiology::
	II. Numerical Solution of the Integral Equations},
  journal = {Biophys. J.},
  year = {1967},
  volume = {7},
  pages = {463--491},
  number = {5},
  doi = {10.1016/S0006-3495(67)86599-8},
  issn = {0006-3495},
  publisher = {Elsevier}
}

@ARTICLE{Bastiani_2012,
  author = {Matteo Bastiani and Nadim Jon Shah and Rainer Goebel and Alard Roebroeck},
  title = {Human cortical connectome reconstruction from diffusion weighted
	MRI: the effect of tractography algorithm.},
  journal = {Neuroimage},
  year = {2012},
  volume = {62},
  pages = {1732--1749},
  number = {3},
  month = {Sep},
  abstract = {Reconstructing the macroscopic human cortical connectome by Diffusion
	Weighted Imaging (DWI) is a challenging research topic that has recently
	gained a lot of attention. In the present work, we investigate the
	effects of intra-voxel fiber direction modeling and tractography
	algorithm on derived structural network indices (e.g. density, small-worldness
	and global efficiency). The investigation is centered on three semi-independent
	distinctions within the large set of available diffusion models and
	tractography methods: i) single fiber direction versus multiple directions
	in the intra-voxel diffusion model, ii) deterministic versus probabilistic
	tractography and iii) local versus global measure-of-fit of the reconstructed
	fiber trajectories. The effect of algorithm and parameter choice
	has two components. First, there is the large effect of tractography
	algorithm and parameters on global network density, which is known
	to strongly affect graph indices. Second, and more importantly, there
	are remaining effects on graph indices which range in the tens of
	percent even when global density is controlled for. This is crucial
	for the sensitivity of any human structural network study and for
	the validity of study comparisons. We then investigate the effect
	of the choice of tractography algorithm on sensitivity and specificity
	of the resulting connections with a connectome dissection quality
	control (QC) approach. In this approach, evaluation of Tract Specific
	Density Coefficients (TSDCs) measures sensitivity while careful inspection
	of tractography path results assesses specificity. We use this to
	discuss interactions in the combined effects of these methods and
	implications for future studies.},
  doi = {10.1016/j.neuroimage.2012.06.002},
  institution = {Department of Cognitive Neuroscience, Faculty of Psychology and Neuroscience,
	Maastricht University, Maastricht, The Netherlands. matteo.bastiani@maastrichtuniversity.nl},
  keywords = {Adult; Algorithms; Cerebral Cortex, physiology; Connectome, methods;
	Diffusion Tensor Imaging, methods; Humans; Image Interpretation,
	Computer-Assisted; Male; Neural Pathways, physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S1053-8119(12)00579-4},
  pmid = {22699045},
  timestamp = {2013.02.14},
  url = {http://dx.doi.org/10.1016/j.neuroimage.2012.06.002}
}

@ARTICLE{Bastien_2012,
  author = {Fr{\'e}d{\'e}ric Bastien and Pascal Lamblin and Razvan Pascanu and
	James Bergstra and Ian J. Goodfellow and Arnaud Bergeron and Nicolas
	Bouchard and David Warde-Farley and Yoshua Bengio},
  title = {Theano: new features and speed improvements},
  journal = {CoRR.},
  year = {2012},
  volume = {abs/1211.5590},
  pages = {--},
  bibsource = {DBLP, http://dblp.uni-trier.de},
  ee = {http://arxiv.org/abs/1211.5590},
  owner = {paupau},
  timestamp = {2013.04.18}
}

@ARTICLE{Beggs_2004,
  author = {John M Beggs and Dietmar Plenz},
  title = {Neuronal avalanches are diverse and precise activity patterns that
	are stable for many hours in cortical slice cultures.},
  journal = {J. Neurosci.},
  year = {2004},
  volume = {24},
  pages = {5216--5229},
  number = {22},
  month = {Jun},
  abstract = {A major goal of neuroscience is to elucidate mechanisms of cortical
	information processing and storage. Previous work from our laboratory
	(Beggs and Plenz, 2003) revealed that propagation of local field
	potentials (LFPs) in cortical circuits could be described by the
	same equations that govern avalanches. Whereas modeling studies suggested
	that these "neuronal avalanches" were optimal for information transmission,
	it was not clear what role they could play in information storage.
	Work from numerous other laboratories has shown that cortical structures
	can generate reproducible spatiotemporal patterns of activity that
	could be used as a substrate for memory. Here, we show that although
	neuronal avalanches lasted only a few milliseconds, their spatiotemporal
	patterns were also stable and significantly repeatable even many
	hours later. To investigate these issues, we cultured coronal slices
	of rat cortex for 4 weeks on 60-channel microelectrode arrays and
	recorded spontaneous extracellular LFPs continuously for 10 hr. Using
	correlation-based clustering and a global contrast function, we found
	that each cortical culture spontaneously produced 4736 +/- 2769 (mean
	+/- SD) neuronal avalanches per hour that clustered into 30 +/- 14
	statistically significant families of spatiotemporal patterns. In
	10 hr of recording, over 98\% of the mutual information shared by
	these avalanche patterns were retained. Additionally, jittering analysis
	revealed that the correlations between avalanches were temporally
	precise to within +/-4 msec. The long-term stability, diversity,
	and temporal precision of these avalanches indicate that they fulfill
	many of the requirements expected of a substrate for memory and suggest
	that they play a central role in both information transmission and
	storage within cortical networks.},
  doi = {10.1523/JNEUROSCI.0540-04.2004},
  institution = {Unit of Neural Network Physiology, Laboratory of Systems Neuroscience,
	National Institute of Mental Health, Bethesda, Maryland 20892, USA.},
  keywords = {Action Potentials, physiology; Algorithms; Animals; Cerebral Cortex,
	cytology/physiology; Cluster Analysis; Memory, physiology; Microelectrodes;
	Models, Neurological; Neostriatum, physiology; Nerve Net, physiology;
	Neural Networks (Computer); Neurons, physiology; Rats; Rats, Sprague-Dawley;
	Reproducibility of Results; Signal Processing, Computer-Assisted;
	Substantia Nigra, physiology; Synaptic Transmission, physiology;
	Time Factors},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {24/22/5216},
  pmid = {15175392},
  timestamp = {2013.03.05},
  url = {http://dx.doi.org/10.1523/JNEUROSCI.0540-04.2004}
}

@ARTICLE{Beggs_2003,
  author = {John M Beggs and Dietmar Plenz},
  title = {Neuronal avalanches in neocortical circuits.},
  journal = {J. Neurosci.},
  year = {2003},
  volume = {23},
  pages = {11167--11177},
  number = {35},
  month = {Dec},
  abstract = {Networks of living neurons exhibit diverse patterns of activity, including
	oscillations, synchrony, and waves. Recent work in physics has shown
	yet another mode of activity in systems composed of many nonlinear
	units interacting locally. For example, avalanches, earthquakes,
	and forest fires all propagate in systems organized into a critical
	state in which event sizes show no characteristic scale and are described
	by power laws. We hypothesized that a similar mode of activity with
	complex emergent properties could exist in networks of cortical neurons.
	We investigated this issue in mature organotypic cultures and acute
	slices of rat cortex by recording spontaneous local field potentials
	continuously using a 60 channel multielectrode array. Here, we show
	that propagation of spontaneous activity in cortical networks is
	described by equations that govern avalanches. As predicted by theory
	for a critical branching process, the propagation obeys a power law
	with an exponent of -3/2 for event sizes, with a branching parameter
	close to the critical value of 1. Simulations show that a branching
	parameter at this value optimizes information transmission in feedforward
	networks, while preventing runaway network excitation. Our findings
	suggest that "neuronal avalanches" may be a generic property of cortical
	networks, and represent a mode of activity that differs profoundly
	from oscillatory, synchronized, or wave-like network states. In the
	critical state, the network may satisfy the competing demands of
	information transmission and network stability.},
  institution = {Unit of Neural Network Physiology, Laboratory of Systems Neuroscience,
	National Institute of Mental Health, Bethesda, Maryland 20892-4075,
	USA.},
  keywords = {Animals; Computer Simulation; Electrodes; Models, Neurological; Neocortex,
	cytology/physiology; Nerve Net, physiology; Neural Networks (Computer);
	Neurons, physiology; Rats; Synaptic Transmission, physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {23/35/11167},
  pmid = {14657176},
  timestamp = {2013.03.05}
}

@ARTICLE{Behrens_2003,
  author = {T. E J Behrens and H. Johansen-Berg and M. W. Woolrich and S. M.
	Smith and C. A M Wheeler-Kingshott and P. A. Boulby and G. J. Barker
	and E. L. Sillery and K. Sheehan and O. Ciccarelli and A. J. Thompson
	and J. M. Brady and P. M. Matthews},
  title = {Non-invasive mapping of connections between human thalamus and cortex
	using diffusion imaging.},
  journal = {Nat Neurosci},
  year = {2003},
  volume = {6},
  pages = {750--757},
  number = {7},
  month = {Jul},
  abstract = {Evidence concerning anatomical connectivities in the human brain is
	sparse and based largely on limited post-mortem observations. Diffusion
	tensor imaging has previously been used to define large white-matter
	tracts in the living human brain, but this technique has had limited
	success in tracing pathways into gray matter. Here we identified
	specific connections between human thalamus and cortex using a novel
	probabilistic tractography algorithm with diffusion imaging data.
	Classification of thalamic gray matter based on cortical connectivity
	patterns revealed distinct subregions whose locations correspond
	to nuclei described previously in histological studies. The connections
	that we found between thalamus and cortex were similar to those reported
	for non-human primates and were reproducible between individuals.
	Our results provide the first quantitative demonstration of reliable
	inference of anatomical connectivity between human gray matter structures
	using diffusion data and the first connectivity-based segmentation
	of gray matter.},
  doi = {10.1038/nn1075},
  institution = {Centre for Functional Magnetic Resonance Imaging of the Brain, University
	of Oxford, John Radcliffe Hospital, Oxford OX3 9DU, UK.},
  keywords = {Adult; Brain Mapping; Cerebral Cortex, anatomy /&/ histology/physiology;
	Diffusion Magnetic Resonance Imaging, methods; Female; Humans; Male;
	Neural Pathways, anatomy /&/ histology/metabolism; Probability; Reproducibility
	of Results; Thalamus, anatomy /&/ histology/physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {nn1075},
  pmid = {12808459},
  timestamp = {2013.08.30},
  url = {http://dx.doi.org/10.1038/nn1075}
}

@INPROCEEDINGS{Belkin_2008,
  author = {Belkin, Mikhail and Sun, Jian and Wang, Yusu},
  title = {Discrete laplace operator on meshed surfaces},
  booktitle = {Proceedings of the twenty-fourth annual symposium on Computational
	geometry},
  year = {2008},
  series = {SCG '08},
  pages = {278--287},
  address = {New York, NY, USA},
  publisher = {ACM},
  acmid = {1377725},
  doi = {10.1145/1377676.1377725},
  isbn = {978-1-60558-071-5},
  keywords = {approximation algorithm, laplace-beltrami operator, surfacemesh},
  location = {College Park, MD, USA},
  numpages = {10}
}

@ARTICLE{Benayoun_2010,
  author = {Marc Benayoun and Michael Kohrman and Jack Cowan and Wim van Drongelen},
  title = {EEG, temporal correlations, and avalanches.},
  journal = {J. Clin. Neurophysiol.},
  year = {2010},
  volume = {27},
  pages = {458--464},
  number = {6},
  month = {Dec},
  abstract = {Epileptiform activity in the EEG is frequently characterized by rhythmic,
	correlated patterns or synchronized bursts. Long-range temporal correlations
	(LRTC) are described by power law scaling of the autocorrelation
	function and have been observed in scalp and intracranial EEG recordings.
	Synchronous large-amplitude bursts (also called neuronal avalanches)
	have been observed in local field potentials both in vitro and in
	vivo. This article explores the presence of neuronal avalanches in
	scalp and intracranial EEG in the context of LRTC. Results indicate
	that both scalp and intracranial EEG show LRTC, with larger scaling
	exponents in scalp recordings than intracranial. A subset of analyzed
	recordings also show avalanche behavior, indicating that avalanches
	may be associated with LRTC. Artificial test signals reveal a linear
	relationship between the scaling exponent measured by detrended fluctuation
	analysis and the exponent of the avalanche size distribution. Analysis
	and evaluation of simulated data reveal that preprocessing of EEG
	(squaring the signal or applying a filter) affect the ability of
	detrended fluctuation analysis to reliably measure LRTC.},
  doi = {10.1097/WNP.0b013e3181fdf8e5},
  institution = {Department of Pediatrics, The University of Chicago, Chicago, Illinois
	60637-1470, USA.},
  keywords = {Adolescent; Brain, physiology; Child; Child, Preschool; Electroencephalography;
	Female; Fourier Analysis; Humans; Infant; Male; Neurons, physiology;
	Scalp, physiology; Signal Processing, Computer-Assisted; Young Adult},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {21076326},
  timestamp = {2013.03.05},
  url = {http://dx.doi.org/10.1097/WNP.0b013e3181fdf8e5}
}

@ARTICLE{Berg_1994,
  author = {Berg, P and Scherg, M},
  title = {A fast method for forward computation of multiple-shell spherical
	head models.},
  journal = {Electroencephalogr. Clin. Neurophysiol.},
  year = {1994},
  volume = {90},
  pages = {58–64},
  number = {1},
  month = {January},
  owner = {paula},
  timestamp = {2012.10.26}
}

@INPROCEEDINGS{bergstra+al:2010-scipy,
  author = {Bergstra, James and Breuleux, Olivier and Bastien, Fr{\'{e}}d{\'{e}}ric
	and Lamblin, Pascal and Pascanu, Razvan and Desjardins, Guillaume
	and Turian, Joseph and Warde-Farley, David and Bengio, Yoshua},
  title = {Theano: a {CPU} and {GPU} Math Expression Compiler},
  booktitle = {Proceedings of the Python for Scientific Computing Conference ({SciPy})},
  year = {2010},
  month = jun,
  note = {Oral Presentation},
  location = {Austin, TX},
  url = {http://www.iro.umontreal.ca/~lisa/pointeurs/theano_scipy2010.pdf}
}

@ARTICLE{Beurle_1959,
  author = {Beurle, R. L.},
  title = {Storage and manipulation of information in the brain},
  journal = {JIEE.},
  year = {1959},
  volume = {5},
  pages = {75--82},
  number = {50},
  owner = {paula},
  timestamp = {2013.04.17}
}

@ARTICLE{Beurle_1956,
  author = {Beurle, R. L.},
  title = {Properties of a Mass of Cells Capable of Regenerating Pulses},
  journal = {Philos. Trans. R. Soc. Lond. B. Biol. Sci.},
  year = {1956},
  volume = {240},
  pages = {55-94},
  number = {669},
  abstract = {Cells having some properties similar to those of neurons are considered.
	A mass of such cells, randomly placed together with a uniform volume
	density, appears capable of supporting various simple forms of activity,
	including plane waves, spherical and circular waves and vortex effects.
	The propagation of a plane wave of activity has been considered in
	some detail. It is shown that a wave may be initiated in a mass of
	such cells by a number of individual stimuli. The mass has a very
	sensitive threshold to such stimulation. This threshold depends on
	cell properties, and by altering the threshold a mass of cells may
	be made to act as an on/off switch. The switching of waves may be
	compared with the shifting of attention in a living organism. Particularly
	interesting phenomena emerge if some property of the individual cells,
	e.g. size, extent of axon or dendrite structure, or threshold, changes
	with repeated use. The mass of cells may then exhibit an ability
	to modify its response according to past experience in a manner similar
	to that of living organisms. Trial and error learning, conditioned
	responses, and the ability to regenerate internally a sequence of
	past events may be demonstrated with very little complication of
	the form of the mass of cells.},
  doi = {10.1098/rstb.1956.0012},
  eprint = {http://rstb.royalsocietypublishing.org/content/240/669/55.full.pdf+html},
  url = {http://rstb.royalsocietypublishing.org/content/240/669/55.abstract}
}

@ARTICLE{Bezgin_2012,
  author = {Gleb Bezgin and Vasily A Vakorin and A. John van Opstal and Anthony
	R McIntosh and Rembrandt Bakker},
  title = {Hundreds of brain maps in one atlas: registering coordinate-independent
	primate neuro-anatomical data to a standard brain.},
  journal = {Neuroimage},
  year = {2012},
  volume = {62},
  pages = {67--76},
  number = {1},
  month = {Aug},
  abstract = {Non-invasive measuring methods such as EEG/MEG, fMRI and DTI are increasingly
	utilised to extract quantitative information on functional and anatomical
	connectivity in the human brain. These methods typically register
	their data in Euclidean space, so that one can refer to a particular
	activity pattern by specifying its spatial coordinates. Since each
	of these methods has limited resolution in either the time or spatial
	domain, incorporating additional data, such as those obtained from
	invasive animal studies, would be highly beneficial to link structure
	and function. Here we describe an approach to spatially register
	all cortical brain regions from the macaque structural connectivity
	database CoCoMac, which contains the combined tracing study results
	from 459 publications (http://cocomac.g-node.org). Brain regions
	from 9 different brain maps were directly mapped to a standard macaque
	cortex using the tool Caret (Van Essen and Dierker, 2007). The remaining
	regions in the CoCoMac database were semantically linked to these
	9 maps using previously developed algebraic and machine-learning
	techniques (Bezgin et al., 2008; Stephan et al., 2000). We analysed
	neural connectivity using several graph-theoretical measures to capture
	global properties of the derived network, and found that Markov Centrality
	provides the most direct link between structure and function. With
	this registration approach, users can query the CoCoMac database
	by specifying spatial coordinates. Availability of deformation tools
	and homology evidence then allow one to directly attribute detailed
	anatomical animal data to human experimental results.},
  doi = {10.1016/j.neuroimage.2012.04.013},
  institution = {Rotman Research Institute of Baycrest Centre, University of Toronto,
	Toronto, Ontario, Canada. gbezgin@rotman-baycrest.on.ca},
  keywords = {Animals; Brain, anatomy /&/ histology; Computer Simulation; Databases,
	Factual, standards; Image Interpretation, Computer-Assisted, methods;
	Macaca, anatomy /&/ histology; Models, Anatomic; Models, Neurological;
	Nerve Net, anatomy /&/ histology; Reference Values; Software; Subtraction
	Technique},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S1053-8119(12)00394-1},
  pmid = {22521477},
  timestamp = {2013.08.29},
  url = {http://dx.doi.org/10.1016/j.neuroimage.2012.04.013}
}

@INPROCEEDINGS{Bezgin_2011,
  author = {G. Y. Bezgin and E. Gibson and R Bakker and AR McIntosh},
  title = {What structure underlies the human brain function? Combining human
	DTI data with axonal tract tracing animalstudies.},
  booktitle = {Annual Meeting of the Society for Neuroscience, Washington DC.},
  year = {2011},
  owner = {paula},
  timestamp = {2013.08.29}
}

@ARTICLE{Biessmann_2012,
  author = {Felix Biessmann and Yusuke Murayama and Nikos K Logothetis and Klaus-Robert
	Müller and Frank C Meinecke},
  title = {Improved decoding of neural activity from fMRI signals using non-separable
	spatiotemporal deconvolutions.},
  journal = {Neuroimage},
  year = {2012},
  volume = {61},
  pages = {1031--1042},
  number = {4},
  month = {Jul},
  abstract = {The goal of most functional Magnetic Resonance Imaging (fMRI) analyses
	is to investigate neural activity. Many fMRI analysis methods assume
	that the temporal dynamics of the hemodynamic response function (HRF)
	to neural activation is separable from its spatial dynamics. Although
	there is empirical evidence that the HRF is more complex than suggested
	by space-time separable canonical HRF models, it is difficult to
	assess how much information about neural activity is lost when assuming
	space-time separability. In this study we directly test whether spatiotemporal
	variability in the HRF that is not captured by separable models contains
	information about neural signals. We predict intracranially measured
	neural activity from simultaneously recorded fMRI data using separable
	and non-separable spatiotemporal deconvolutions of voxel time series
	around the recording electrode. Our results show that abandoning
	the spatiotemporal separability assumption consistently improves
	the decoding accuracy of neural signals from fMRI data. We compare
	our findings with results from optical imaging and fMRI studies and
	discuss potential implications for classical fMRI analyses without
	invasive electrophysiological recordings.},
  doi = {10.1016/j.neuroimage.2012.04.015},
  institution = {Berlin Institute of Technology, Machine Learning Group, Franklinstr
	28/29, 10587 Berlin, Germany. felix.biessmann@tu-berlin.de},
  keywords = {Algorithms; Animals; Brain, physiology; Image Processing, Computer-Assisted,
	methods; Macaca mulatta; Magnetic Resonance Imaging, methods; Models,
	Neurological},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S1053-8119(12)00396-5},
  pmid = {22537598},
  timestamp = {2013.08.19},
  url = {http://dx.doi.org/10.1016/j.neuroimage.2012.04.015}
}

@ARTICLE{Biswal_1995c,
  author = {B. Biswal and F. Z. Yetkin and V. M. Haughton and J. S. Hyde},
  title = {Functional connectivity in the motor cortex of resting human brain
	using echo-planar MRI.},
  journal = {Magn. Reson. Med.},
  year = {1995},
  volume = {34},
  pages = {537--541},
  number = {4},
  month = {Oct},
  abstract = {An MRI time course of 512 echo-planar images (EPI) in resting human
	brain obtained every 250 ms reveals fluctuations in signal intensity
	in each pixel that have a physiologic origin. Regions of the sensorimotor
	cortex that were activated secondary to hand movement were identified
	using functional MRI methodology (FMRI). Time courses of low frequency
	(< 0.1 Hz) fluctuations in resting brain were observed to have a
	high degree of temporal correlation (P < 10(-3)) within these regions
	and also with time courses in several other regions that can be associated
	with motor function. It is concluded that correlation of low frequency
	fluctuations, which may arise from fluctuations in blood oxygenation
	or flow, is a manifestation of functional connectivity of the brain.},
  institution = {Biophysics Research Institute, Medical College of Wisconsin, Milwaukee
	53226-0509, USA.},
  keywords = {Acoustic Stimulation; Adult; Brain, metabolism/physiology; Cerebrovascular
	Circulation; Echo-Planar Imaging; Electroencephalography; Female;
	Fingers, physiology; Hand, physiology; Humans; Magnetic Resonance
	Imaging, methods; Male; Motor Cortex, metabolism/physiology; Motor
	Skills; Movement; Neurons, physiology; Oxygen, blood; Photic Stimulation;
	Psychomotor Performance; Rest; Somatosensory Cortex, metabolism/physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {8524021},
  timestamp = {2012.11.14}
}

@ARTICLE{Bojak_2010,
  author = {Ingo Bojak and David T J Liley},
  title = {Axonal velocity distributions in neural field equations.},
  journal = {PLoS Comput. Biol.},
  year = {2010},
  volume = {6},
  pages = {e1000653},
  number = {1},
  month = {Jan},
  abstract = {By modelling the average activity of large neuronal populations, continuum
	mean field models (MFMs) have become an increasingly important theoretical
	tool for understanding the emergent activity of cortical tissue.
	In order to be computationally tractable, long-range propagation
	of activity in MFMs is often approximated with partial differential
	equations (PDEs). However, PDE approximations in current use correspond
	to underlying axonal velocity distributions incompatible with experimental
	measurements. In order to rectify this deficiency, we here introduce
	novel propagation PDEs that give rise to smooth unimodal distributions
	of axonal conduction velocities. We also argue that velocities estimated
	from fibre diameters in slice and from latency measurements, respectively,
	relate quite differently to such distributions, a significant point
	for any phenomenological description. Our PDEs are then successfully
	fit to fibre diameter data from human corpus callosum and rat subcortical
	white matter. This allows for the first time to simulate long-range
	conduction in the mammalian brain with realistic, convenient PDEs.
	Furthermore, the obtained results suggest that the propagation of
	activity in rat and human differs significantly beyond mere scaling.
	The dynamical consequences of our new formulation are investigated
	in the context of a well known neural field model. On the basis of
	Turing instability analyses, we conclude that pattern formation is
	more easily initiated using our more realistic propagator. By increasing
	characteristic conduction velocities, a smooth transition can occur
	from self-sustaining bulk oscillations to travelling waves of various
	wavelengths, which may influence axonal growth during development.
	Our analytic results are also corroborated numerically using simulations
	on a large spatial grid. Thus we provide here a comprehensive analysis
	of empirically constrained activity propagation in the context of
	MFMs, which will allow more realistic studies of mammalian brain
	activity in the future.},
  doi = {10.1371/journal.pcbi.1000653},
  institution = {Donders Institute for Brain, Cognition and Behaviour, Centre for
	Neuroscience, Radboud University Nijmegen, Nijmegen, The Netherlands.
	i.bojak@donders.ru.nl},
  keywords = {Algorithms; Animals; Axons, physiology; Cerebral Cortex, cytology/physiology;
	Chi-Square Distribution; Computer Simulation; Corpus Callosum, cytology/physiology;
	Humans; Models, Neurological; Nerve Fibers, Myelinated, physiology;
	Rats; Synapses, physiology},
  language = {eng},
  medline-pst = {epublish},
  owner = {paula},
  pmid = {20126532},
  timestamp = {2013.02.18},
  url = {http://dx.doi.org/10.1371/journal.pcbi.1000653}
}

@ARTICLE{Bojak_2005,
  author = {I. Bojak and D. T J Liley},
  title = {Modeling the effects of anesthesia on the electroencephalogram.},
  journal = {Phys. Rev. E: Stat., Nonlinear, Soft Matter Phys.},
  year = {2005},
  volume = {71},
  pages = {041902},
  number = {4 Pt 1},
  month = {Apr},
  abstract = {Changes to the electroencephalogram (EEG) observed during general
	anesthesia are modeled with a physiological mean field theory of
	electrocortical activity. To this end a parametrization of the postsynaptic
	impulse response is introduced which takes into account pharmacological
	effects of anesthetic agents on neuronal ligand-gated ionic channels.
	Parameter sets for this improved theory are then identified which
	respect known anatomical constraints and predict mean firing rates
	and power spectra typically encountered in human subjects. Through
	parallelized simulations of the eight nonlinear, two-dimensional
	partial differential equations on a grid representing an entire human
	cortex, it is demonstrated that linear approximations are sufficient
	for the prediction of a range of quantitative EEG variables. More
	than 70,000 plausible parameter sets are finally selected and subjected
	to a simulated induction with the stereotypical inhaled general anesthetic
	isoflurane. Thereby 86 parameter sets are identified that exhibit
	a strong "biphasic" rise in total power, a feature often observed
	in experiments. A sensitivity study suggests that this "biphasic"
	behavior is distinguishable even at low agent concentrations. Finally,
	our results are briefly compared with previous work by other groups
	and an outlook on future fits to experimental data is provided.},
  institution = {Centre for Intelligent Systems and Complex Processes, LSS, Swinburne
	University of Technology, P. O. Box 218, Hawthorn, Victoria 3122,
	Australia. ibojak@swin.edu.au},
  keywords = {Action Potentials, drug effects/physiology; Anesthesia, methods; Anesthetics,
	General, administration /&/ dosage; Anesthetics, administration /&/
	dosage; Animals; Cerebral Cortex, drug effects/physiology; Computer
	Simulation; Electroencephalography, drug effects/methods; Humans;
	Isoflurane, administration /&/ dosage; Models, Neurological; Nerve
	Net, drug effects/physiology; Synaptic Transmission, physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {15903696},
  timestamp = {2013.02.18}
}

@ARTICLE{Bojak_2011,
  author = {Bojak, I and Oostendorp, TF and Reid, AT and Kötter, R},
  title = {Towards a model-based integration of co-registered electroencephalography/functional
	magnetic resonance imaging data with realistic neural population
	meshes},
  journal = {Philos. Trans. R Soc. Lond. A.},
  year = {2011},
  volume = {369},
  pages = {3785-3801},
  number = {1952},
  owner = {paula},
  timestamp = {2012.10.18}
}

@ARTICLE{Bojak_2010a,
  author = {Bojak, I and Oostendorp, TF and Reid, AT and Kötter R},
  title = {Connecting mean field models of neural activity to EEG and fMRI data.},
  journal = {Brain Topogr.},
  year = {2010},
  volume = {23},
  pages = {139-149},
  number = {2},
  keywords = {EEG, fMRI},
  owner = {paula},
  timestamp = {2012.10.18}
}

@ARTICLE{Bostock_2011,
  author = {Michael Bostock and Vadim Ogievetsky and Jeffrey Heer},
  title = {D3 Data-Driven Documents},
  journal = {IEEE Trans. Visual. Comput. Graphics},
  year = {2011},
  volume = {17},
  pages = {2301-2309},
  number = {2},
  doi = {10.1109/TVCG.2011.185},
  owner = {paula},
  timestamp = {2013.01.31}
}

@ARTICLE{Boynton_2011,
  author = {Geoffrey M Boynton},
  title = {Spikes, BOLD, attention, and awareness: a comparison of electrophysiological
	and fMRI signals in V1.},
  journal = {J Vis},
  year = {2011},
  volume = {11},
  pages = {12},
  number = {5},
  abstract = {Early fMRI studies comparing results from fMRI and electrophysiological
	experiments support the notion that the blood oxygen level-dependent
	(BOLD) signal reliably follows the spiking activity of an underlying
	neuronal population averaged across a small region in space and a
	brief period in time. However, more recent studies focusing on higher
	level cognitive factors such as attention and visual awareness report
	striking discrepancies between the fMRI response in humans and electrophysiological
	signals in macaque early visual areas. Four hypotheses are discussed
	that can explain the discrepancies between the two methods: (1) the
	BOLD signal follows local field potential (LFP) signals closer than
	spikes, and only the LFP is modulated by top-down factors, (2) the
	BOLD signal is reflecting electrophysiological signals that are occurring
	later in time due to feedback delay, (3) the BOLD signal is more
	sensitive than traditional electrophysiological methods due to massive
	pooling by the hemodynamic coupling process, and finally (4) there
	is no real discrepancy, and instead, weak but reliable effects on
	firing rates may be obscured by differences in experimental design
	and interpretation of results across methods.},
  doi = {10.1167/11.5.12},
  institution = {Department of Psychology, University of Washington, Seattle, WA,
	USA. gboynton@uw.edu},
  keywords = {Attention, physiology; Awareness, physiology; Electrophysiological
	Phenomena; Humans; Magnetic Resonance Imaging, methods; Photic Stimulation,
	methods; Visual Cortex, physiology},
  language = {eng},
  medline-pst = {epublish},
  owner = {paula},
  pii = {11.5.12},
  pmid = {22199162},
  timestamp = {2013.08.19},
  url = {http://dx.doi.org/10.1167/11.5.12}
}

@ARTICLE{Boynton_1996,
  author = {G. M. Boynton and S. A. Engel and G. H. Glover and D. J. Heeger},
  title = {Linear Systems Analysis of Functional Magnetic Resonance Imaging
	in Human V1},
  journal = {Journal of Neuroscience},
  year = {1996},
  volume = {16},
  pages = {4207– 4221},
  number = {13},
  month = {July},
  owner = {paula},
  timestamp = {2013.08.19}
}

@ARTICLE{Boynton_2012,
  author = {Geoffrey M Boynton and Stephen A Engel and David J Heeger},
  title = {Linear systems analysis of the fMRI signal.},
  journal = {Neuroimage},
  year = {2012},
  volume = {62},
  pages = {975--984},
  number = {2},
  month = {Aug},
  abstract = {In 1995 when we began our investigations of the human visual system
	using fMRI, little was known about the temporal properties of the
	fMRI signal. Before we felt comfortable making quantitative estimates
	of neuronal responses with this new technique, we decided to first
	conduct a basic study of how the time-course of the fMRI response
	varied with stimulus timing and strength. The results ended up showing
	strong evidence that to a first approximation the hemodynamic transformation
	was linear in time. This was both important and remarkable: important
	because nearly all fMRI data analysis techniques assume or require
	linearity, and remarkable because the physiological basis of the
	hemodynamic transformation is so complex that we still have a far
	from complete understanding of it. In this paper, we provide highlights
	of the results of our original paper supporting the linear transform
	hypothesis. A reanalysis of the original data provides some interesting
	new insights into the published results. We also provide a detailed
	appendix describing of the properties and predictions of a linear
	system in time in the context of the transformation between neuronal
	responses and the BOLD signal.},
  doi = {10.1016/j.neuroimage.2012.01.082},
  institution = {Department of Psychology, University of Washington, PO Box 351525,
	Seattle, WA 98195-1525, USA. gboynton@uw.edu},
  keywords = {Brain Mapping, history/methods; Cerebrovascular Circulation, physiology;
	Hemodynamics, physiology; History, 20th Century; History, 21st Century;
	Humans; Image Processing, Computer-Assisted, history/methods; Linear
	Models; Magnetic Resonance Imaging, history/methods; Visual Cortex,
	blood supply/physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S1053-8119(12)00099-7},
  pmid = {22289807},
  timestamp = {2013.08.19},
  url = {http://dx.doi.org/10.1016/j.neuroimage.2012.01.082}
}

@ARTICLE{Breakspear_2012,
  author = {Michael Breakspear},
  title = {Dynamic and stochastic models of neuroimaging data: A comment on
	Lohmann et al.},
  journal = {Neuroimage},
  year = {2012},
  volume = {xx},
  pages = {In press},
  month = {Feb},
  abstract = {DCM is a platform for inferring the architecture of dynamical systems,
	combining a user-dependent model specification step with a Bayesian
	model selection scheme. In their critique of the model selection
	procedure, Lohmann et al confine themselves to models generated from
	the classic bilinear deterministic DCM. Although brief reference
	is made to recent modeling advances, such as stochastic DCM and nonlinear
	DCM, these are negatively cast as guilty of further exploding the
	combinatorial problem that is proposed to plague model selection.
	Yet this is only a problem if a naïve approach is adopted towards
	the model generation process. Where the user draws on prior knowledge
	of the system being modeled and the statistical properties of the
	particular data set, these advances can be employed precisely to
	address the type of concerns Lohmann et al raise in their exemplar
	analysis (Fig. 6). This note provides a putative generative model
	for their data by adding stochastic effects, using independent evidence
	to increase its biological plausibility and challenging the notion
	that model fit should be assessed using simple linear correlations.
	Rather than encouraging reliance on future developments in imaging
	hardware and data-driven multivariate algorithms, informed engagement
	with causal models of neuronal dynamics allows imaging researchers
	develop detailed theories of brain function across a broad range
	of data sets and cognitive phenomena.},
  doi = {10.1016/j.neuroimage.2012.02.047},
  language = {eng},
  medline-pst = {aheadofprint},
  owner = {paula},
  pii = {S1053-8119(12)00225-X},
  pmid = {22387473},
  timestamp = {2013.02.18},
  url = {http://dx.doi.org/10.1016/j.neuroimage.2012.02.047}
}

@ARTICLE{Breakspear_2006a,
  author = {Michael Breakspear and Ed T Bullmore and Kevin Aquino and Pritha
	Das and Leanne M Williams},
  title = {The multiscale character of evoked cortical activity.},
  journal = {Neuroimage},
  year = {2006},
  volume = {30},
  pages = {1230--1242},
  number = {4},
  month = {May},
  abstract = {Both the architecture and the dynamics of the brain have characteristic
	features at different spatial scales. However, the existence, nature
	and function of dynamical interdependencies between such scales have
	not been investigated. We studied the multiscale properties of functional
	magnetic resonance imaging (fMRI) data acquired while human subjects
	viewed a visual image. Traditional "region of interest" analysis
	of this data set revealed evoked activity in primary and extrastriate
	visual cortex. Wavelet transform in the spatial domain provides a
	multiscale representation of this evoked brain activity. Studying
	the correlation structure of this representation revealed strong
	and novel interdependencies in these data within and between different
	spatial scales. We found that such correlations are stronger than
	those evident in the original data and comparable in magnitude to
	those obtained after Gaussian smoothing. However, analysis of the
	data in the wavelet domain revealed additional structure such as
	positive correlations, strong anti-correlations and phase-lagged
	interdependencies. Statistical significance of these effects was
	inferred through nonparametric bootstrap techniques. We conclude
	that the spatial analysis of functional neuroimaging data in the
	wavelet domain provides novel information which may reflect complex
	spatiotemporal neuronal activity and information encoding. It also
	affords a quantitative means of testing hierarchical and multiscale
	models of cortical activity.},
  doi = {10.1016/j.neuroimage.2005.10.041},
  institution = {The Black Dog Institute, Hospital Rd, Prince of Wales Hospital and
	The School of Psychiatry, University of New South Wales, Randwick,
	NSW 2031, Australia. mbreak@unsw.edu.au},
  keywords = {Adult; Color Perception, physiology; Computer Simulation; Dominance,
	Cerebral, physiology; Evoked Potentials, Visual, physiology; Humans;
	Image Processing, Computer-Assisted, methods; Magnetic Resonance
	Imaging, methods; Male; Mathematical Computing; Neurons, physiology;
	Normal Distribution; Pattern Recognition, Visual, physiology; Statistics
	as Topic; Statistics, Nonparametric; Visual Cortex, physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S1053-8119(05)02443-2},
  pmid = {16403656},
  timestamp = {2013.02.18},
  url = {http://dx.doi.org/10.1016/j.neuroimage.2005.10.041}
}

@BOOK{Breakspear_2007,
  title = {Handbook of Brain Connectivity (Understanding Complex Systems) -
	Neuronal Dynamics and Brain Connectivity},
  publisher = {Springer Berlin / Heidelberg},
  year = {2007},
  author = {Breakspear, M and Jirsa, VK},
  pages = {3-64},
  owner = {paula},
  timestamp = {2012.10.18}
}

@ARTICLE{Breakspear_2006,
  author = {M. Breakspear and J. A. Roberts and J. R. Terry and S. Rodrigues
	and N. Mahant and P. A. Robinson},
  title = {A unifying explanation of primary generalized seizures through nonlinear
	brain modeling and bifurcation analysis.},
  journal = {Cereb. Cortex},
  year = {2006},
  volume = {16},
  pages = {1296--1313},
  number = {9},
  month = {Sep},
  abstract = {The aim of this paper is to explain critical features of the human
	primary generalized epilepsies by investigating the dynamical bifurcations
	of a nonlinear model of the brain's mean field dynamics. The model
	treats the cortex as a medium for the propagation of waves of electrical
	activity, incorporating key physiological processes such as propagation
	delays, membrane physiology, and corticothalamic feedback. Previous
	analyses have demonstrated its descriptive validity in a wide range
	of healthy states and yielded specific predictions with regards to
	seizure phenomena. We show that mapping the structure of the nonlinear
	bifurcation set predicts a number of crucial dynamic processes, including
	the onset of periodic and chaotic dynamics as well as multistability.
	Quantitative study of electrophysiological data supports the validity
	of these predictions. Hence, we argue that the core electrophysiological
	and cognitive differences between tonic-clonic and absence seizures
	are predicted and interrelated by the global bifurcation diagram
	of the model's dynamics. The present study is the first to present
	a unifying explanation of these generalized seizures using the bifurcation
	analysis of a dynamical model of the brain.},
  doi = {10.1093/cercor/bhj072},
  institution = {School of Physics, University of Sydney, NSW 2006, Australia. mbreak@unsw.edu},
  keywords = {Action Potentials; Adolescent; Adult; Animals; Biological Clocks;
	Cerebral Cortex, physiopathology; Computer Simulation; Electroencephalography;
	Feedback; Female; Humans; Male; Middle Aged; Models, Neurological;
	Nerve Net, physiopathology; Neurons; Nonlinear Dynamics; Seizures,
	physiopathology; Synaptic Transmission; Thalamus, physiopathology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {bhj072},
  pmid = {16280462},
  timestamp = {2013.02.18},
  url = {http://dx.doi.org/10.1093/cercor/bhj072}
}

@ARTICLE{Breakspear_2003,
  author = {Michael Breakspear and John R Terry and Karl J Friston},
  title = {Modulation of excitatory synaptic coupling facilitates synchronization
	and complex dynamics in a biophysical model of neuronal dynamics.},
  journal = {Network},
  year = {2003},
  volume = {14},
  pages = {703--732},
  number = {4},
  month = {Nov},
  abstract = {In this paper, complex dynamical synchronization in a non-linear model
	of a neural system is studied, and the computational significance
	of the behaviours is explored. The local neural dynamics is determined
	by voltage- and ligand-gated ion channels and feedback between densely
	interconnected excitatory and inhibitory neurons. A mesoscopic array
	of local networks is modelled by introducing coupling between the
	local networks via weak excitatory-to-excitatory connectivity. It
	is shown that with modulation of this long-range synaptic coupling,
	the system undergoes a transition from independent oscillations to
	stable chaotic synchronization. Between these states exists a 'weakly'
	stable state associated with complex, intermittent behaviour in the
	temporal domain and clusters of synchronous regions in the spatial
	domain. The paper concludes with a discussion of the putative relevance
	of such processes in the brain, including the role of neuromodulatory
	systems and the mechanisms underlying sensory perception, adaptation,
	computation and complexity.},
  institution = {Brain Dynamics Centre, Westmead Hospital, Westmead, NSW 2145, Australia.
	mbreak@physics.usyd.edu.au},
  keywords = {Action Potentials; Animals; Computer Simulation; Cortical Synchronization;
	Excitatory Postsynaptic Potentials; Feedback; Humans; Ion Channel
	Gating, physiology; Membrane Potentials; Models, Neurological; Neural
	Inhibition; Neural Networks (Computer); Neurons, physiology; Nonlinear
	Dynamics; Synapses, physiology; Time Factors},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {14653499},
  timestamp = {2013.02.18}
}

@ARTICLE{Bressloff1994,
  author = {Bressloff},
  title = {Dynamics of compartmental model recurrent neural networks.},
  journal = {Phys. Rev. E: Stat. Phys. Plasmas Fluids Relat. Interdisciplin. Top.},
  year = {1994},
  volume = {50},
  pages = {2308--2319},
  number = {3},
  month = {Sep},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paupau},
  pmid = {9962239},
  timestamp = {2013.04.09}
}

@ARTICLE{Bressloff_2012,
  author = {Paul C Bressloff},
  title = {From invasion to extinction in heterogeneous neural fields.},
  journal = {JMN.},
  year = {2012},
  volume = {2},
  pages = {6},
  number = {1},
  abstract = {In this paper, we analyze the invasion and extinction of activity
	in heterogeneous neural fields. We first consider the effects of
	spatial heterogeneities on the propagation of an invasive activity
	front. In contrast to previous studies of front propagation in neural
	media, we assume that the front propagates into an unstable rather
	than a metastable zero-activity state. For sufficiently localized
	initial conditions, the asymptotic velocity of the resulting pulled
	front is given by the linear spreading velocity, which is determined
	by linearizing about the unstable state within the leading edge of
	the front. One of the characteristic features of these so-called
	pulled fronts is their sensitivity to perturbations inside the leading
	edge. This means that standard perturbation methods for studying
	the effects of spatial heterogeneities or external noise fluctuations
	break down. We show how to extend a partial differential equation
	method for analyzing pulled fronts in slowly modulated environments
	to the case of neural fields with slowly modulated synaptic weights.
	The basic idea is to rescale space and time so that the front becomes
	a sharp interface whose location can be determined by solving a corresponding
	local Hamilton-Jacobi equation. We use steepest descents to derive
	the Hamilton-Jacobi equation from the original nonlocal neural field
	equation. In the case of weak synaptic heterogenities, we then use
	perturbation theory to solve the corresponding Hamilton equations
	and thus determine the time-dependent wave speed. In the second part
	of the paper, we investigate how time-dependent heterogenities in
	the form of extrinsic multiplicative noise can induce rare noise-driven
	transitions to the zero-activity state, which now acts as an absorbing
	state signaling the extinction of all activity. In this case, the
	most probable path to extinction can be obtained by solving the classical
	equations of motion that dominate a path integral representation
	of the stochastic neural field in the weak noise limit. These equations
	take the form of nonlocal Hamilton equations in an infinite-dimensional
	phase space.},
  doi = {10.1186/2190-8567-2-6},
  institution = {Department of Mathematics, University of Utah, Salt Lake City, UT,
	84112, USA. bressloff@math.utah.edu.},
  language = {eng},
  medline-pst = {epublish},
  owner = {paula},
  pii = {2190-8567-2-6},
  pmid = {22655682},
  timestamp = {2013.04.17},
  url = {http://dx.doi.org/10.1186/2190-8567-2-6}
}

@ARTICLE{Bressolf_2005,
  author = {Paul C Bressloff},
  title = {Spontaneous symmetry breaking in self-organizing neural fields.},
  journal = {Biol. Cybern.},
  year = {2005},
  volume = {93},
  pages = {256--274},
  number = {4},
  month = {Oct},
  abstract = {We extend the theory of self-organizing neural fields in order to
	analyze the joint emergence of topography and feature selectivity
	in primary visual cortex through spontaneous symmetry breaking. We
	first show how a binocular one-dimensional topographic map can undergo
	a pattern forming instability that breaks the underlying symmetry
	between left and right eyes. This leads to the spatial segregation
	of eye specific activity bumps consistent with the emergence of ocular
	dominance columns. We then show how a 2-dimensional isotropic topographic
	map can undergo a pattern forming instability that breaks the underlying
	rotation symmetry. This leads to the formation of elongated activity
	bumps consistent with the emergence of orientation preference columns.
	A particularly interesting property of the latter symmetry breaking
	mechanism is that the linear equations describing the growth of the
	orientation columns exhibits a rotational shift-twist symmetry, in
	which there is a coupling between orientation and topography. Such
	coupling has been found in experimentally generated orientation preference
	maps.},
  doi = {10.1007/s00422-005-0002-3},
  institution = {Department of Mathematics, University of Utah, Salt Lake City, Utah,
	USA.},
  keywords = {Algorithms; Models, Neurological; Models, Theoretical; Neurons; Vision,
	Binocular, physiology; Visual Cortex, physiology; Visual Perception,
	physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {16193306},
  timestamp = {2013.04.17},
  url = {http://dx.doi.org/10.1007/s00422-005-0002-3}
}

@ARTICLE{Bressloff1999,
  author = {Bressloff, P. C.},
  title = {Mean-field theory of globally coupled integrate-and-fire neural oscillators
	with dynamic synapses.},
  journal = {Phys. Rev. E: Stat. Phys. Plasmas Fluids Relat. Interdisciplin. Top.},
  year = {1999},
  volume = {60},
  pages = {2160--2170},
  number = {2 Pt B},
  month = {Aug},
  abstract = {We analyze the effects of synaptic depression or facilitation on the
	existence and stability of the splay or asynchronous state in a population
	of all-to-all, pulse-coupled neural oscillators. We use mean-field
	techniques to derive conditions for the local stability of the splay
	state and determine how stability depends on the degree of synaptic
	depression or facilitation. We also consider the effects of noise.
	Extensions of the mean-field results to finite networks are developed
	in terms of the nonlinear firing time map.},
  institution = {Nonlinear and Complex Systems Group, Department of Mathematical Sciences,
	Loughborough University, Loughborough, Leicestershire LE11 3TU, United
	Kingdom.},
  keywords = {Models, Neurological; Nerve Net, physiology; Neurons, physiology;
	Nonlinear Dynamics; Oscillometry; Synapses, physiology; Synaptic
	Transmission, physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paupau},
  pmid = {11970009},
  timestamp = {2013.04.09}
}

@ARTICLE{Bressloff1995,
  author = {Bressloff, P. C.},
  title = {Integro-differential equations and the stability of neural networks
	with dendritic structure.},
  journal = {Biol. Cybern.},
  year = {1995},
  volume = {73},
  pages = {281--290},
  number = {3},
  month = {Aug},
  abstract = {We analyse the effects of dendritic structure on the stability of
	a recurrent neural network in terms of a set of coupled, non-linear
	Volterra integro-differential equations. These, which describe the
	dynamics of the somatic membrane potentials, are obtained by eliminating
	the dendritic potentials from the underlying compartmental model
	or cable equations. We then derive conditions for Turing-like instability
	as a precursor for pattern formation in a spatially organized network.
	These conditions depend on the spatial distribution of axo-dendritic
	connections across the network.},
  institution = {Department of Mathematical Sciences, Loughborough University of Technology,
	Leics, UK.},
  keywords = {Animals; Dendrites, physiology; Humans; Models, Theoretical; Neural
	Networks (Computer); Neurons, physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paupau},
  pmid = {7548316},
  timestamp = {2013.04.09}
}

@ARTICLE{Bressloff2000,
  author = {Bressloff, P. C. and Coombes, S.},
  title = {Dynamics of strongly-coupled spiking neurons.},
  journal = {Neural Comput.},
  year = {2000},
  volume = {12},
  pages = {91--129},
  number = {1},
  month = {Jan},
  abstract = {We present a dynamical theory of integrate-and-fire neurons with strong
	synaptic coupling. We show how phase-locked states that are stable
	in the weak coupling regime can destabilize as the coupling is increased,
	leading to states characterized by spatiotemporal variations in the
	interspike intervals (ISIs). The dynamics is compared with that of
	a corresponding network of analog neurons in which the outputs of
	the neurons are taken to be mean firing rates. A fundamental result
	is that for slow interactions, there is good agreement between the
	two models (on an appropriately defined timescale). Various examples
	of desynchronization in the strong coupling regime are presented.
	First, a globally coupled network of identical neurons with strong
	inhibitory coupling is shown to exhibit oscillator death in which
	some of the neurons suppress the activity of others. However, the
	stability of the synchronous state persists for very large networks
	and fast synapses. Second, an asymmetric network with a mixture of
	excitation and inhibition is shown to exhibit periodic bursting patterns.
	Finally, a one-dimensional network of neurons with long-range interactions
	is shown to desynchronize to a state with a spatially periodic pattern
	of mean firing rates across the network. This is modulated by deterministic
	fluctuations of the instantaneous firing rate whose size is an increasing
	function of the speed of synaptic response.},
  institution = {Nonlinear and Complex Systems Group, Department of Mathematical Sciences,
	Loughborough University, Loughborough, Leicestershire LE11 3TU, U.K.},
  keywords = {Animals; Models, Neurological; Models, Theoretical; Neural Networks
	(Computer); Neurons, physiology; Synapses, physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paupau},
  pmid = {10636934},
  timestamp = {2013.04.09}
}

@ARTICLE{Bressloff2002,
  author = {Bressloff, Paul C. and Cowan, Jack D.},
  title = {An amplitude equation approach to contextual effects in visual cortex.},
  journal = {Neural Comput.},
  year = {2002},
  volume = {14},
  pages = {493--525},
  number = {3},
  month = {Mar},
  abstract = {A mathematical theory of interacting hypercolumns in primary visual
	cortex (V1) is presented that incorporates details concerning the
	anisotropic nature of long-range lateral connections. Each hypercolumn
	is modeled as a ring of interacting excitatory and inhibitory neural
	populations with orientation preferences over the range 0 to 180
	degrees. Analytical methods from bifurcation theory are used to derive
	nonlinear equations for the amplitude and phase of the population
	tuning curves in which the effective lateral interactions are linear
	in the amplitudes. These amplitude equations describe how mutual
	interactions between hypercolumns via lateral connections modify
	the response of each hypercolumn to modulated inputs from the lateral
	geniculate nucleus; such interactions form the basis of contextual
	effects. The coupled ring model is shown to reproduce a number of
	orientation-dependent and contrast-dependent features observed in
	center-surround experiments. A major prediction of the model is that
	the anisotropy in lateral connections results in a nonuniform modulatory
	effect of the surround that is correlated with the orientation of
	the center.},
  doi = {10.1162/089976602317250870},
  keywords = {Animals; Anisotropy; Humans; Models, Neurological; Nonlinear Dynamics;
	Visual Cortex, physiology; Visual Pathways, physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paupau},
  pmid = {11860680},
  timestamp = {2013.04.09},
  url = {http://dx.doi.org/10.1162/089976602317250870}
}

@ARTICLE{Bressloff2001,
  author = {Bressloff, P. C. and Cowan, J. D. and Golubitsky, M. and Thomas,
	P. J. and Wiener, M. C.},
  title = {Geometric visual hallucinations, Euclidean symmetry and the functional
	architecture of striate cortex.},
  journal = {Philos. Trans. R. Soc. Lond. B. Biol. Sci.},
  year = {2001},
  volume = {356},
  pages = {299--330},
  number = {1407},
  month = {Mar},
  abstract = {This paper is concerned with a striking visual experience: that of
	seeing geometric visual hallucinations. Hallucinatory images were
	classified by Klüver into four groups called form constants comprising
	(i) gratings, lattices, fretworks, filigrees, honeycombs and chequer-boards,
	(ii) cobwebs, (iii) tunnels, funnels, alleys, cones and vessels,
	and (iv) spirals. This paper describes a mathematical investigation
	of their origin based on the assumption that the patterns of connection
	between retina and striate cortex (henceforth referred to as V1)-the
	retinocortical map-and of neuronal circuits in V1, both local and
	lateral, determine their geometry. In the first part of the paper
	we show that form constants, when viewed in V1 coordinates, essentially
	correspond to combinations of plane waves, the wavelengths of which
	are integral multiples of the width of a human Hubel-Wiesel hypercolumn,
	ca. 1.33-2 mm. We next introduce a mathematical description of the
	large-scale dynamics of V1 in terms of the continuum limit of a lattice
	of interconnected hypercolumns, each of which itself comprises a
	number of interconnected iso-orientation columns. We then show that
	the patterns of interconnection in V1 exhibit a very interesting
	symmetry, i.e. they are invariant under the action of the planar
	Euclidean group E(2)-the group of rigid motions in the plane-rotations,
	reflections and translations. What is novel is that the lateral connectivity
	of V1 is such that a new group action is needed to represent its
	properties: by virtue of its anisotropy it is invariant with respect
	to certain shifts and twists of the plane. It is this shift-twist
	invariance that generates new representations of E(2). Assuming that
	the strength of lateral connections is weak compared with that of
	local connections, we next calculate the eigenvalues and eigenfunctions
	of the cortical dynamics, using Rayleigh-Schrödinger perturbation
	theory. The result is that in the absence of lateral connections,
	the eigenfunctions are degenerate, comprising both even and odd combinations
	of sinusoids in straight phi, the cortical label for orientation
	preference, and plane waves in r, the cortical position coordinate.
	'Switching-on' the lateral interactions breaks the degeneracy and
	either even or else odd eigenfunctions are selected. These results
	can be shown to follow directly from the Euclidean symmetry we have
	imposed. In the second part of the paper we study the nature of various
	even and odd combinations of eigenfunctions or planforms, the symmetries
	of which are such that they remain invariant under the particular
	action of E(2) we have imposed. These symmetries correspond to certain
	subgroups of E(2), the so-called axial subgroups. Axial subgroups
	are important in that the equivariant branching lemma indicates that
	when a symmetrical dynamical system becomes unstable, new solutions
	emerge which have symmetries corresponding to the axial subgroups
	of the underlying symmetry group. This is precisely the case studied
	in this paper. Thus we study the various planforms that emerge when
	our model V1 dynamics become unstable under the presumed action of
	hallucinogens or flickering lights. We show that the planforms correspond
	to the axial subgroups of E(2), under the shift-twist action. We
	then compute what such planforms would look like in the visual field,
	given an extension of the retinocortical map to include its action
	on local edges and contours. What is most interesting is that, given
	our interpretation of the correspondence between V1 planforms and
	perceived patterns, the set of planforms generates representatives
	of all the form constants. It is also noteworthy that the planforms
	derived from our continuum model naturally divide V1 into what are
	called linear regions, in which the pattern has a near constant orientation,
	reminiscent of the iso-orientation patches constructed via optical
	imaging. The boundaries of such regions form fractures whose points
	of intersection correspond to the well-known 'pinwheels'. To complete
	the study we then investigate the stability of the planforms, using
	methods of nonlinear stability analysis, including Liapunov-Schmidt
	reduction and Poincaré-Lindstedt perturbation theory. We find a close
	correspondence between stable planforms and form constants. The results
	are sensitive to the detailed specification of the lateral connectivity
	and suggest an interesting possibility, that the cortical mechanisms
	by which geometric visual hallucinations are generated, if sited
	mainly in V1, are closely related to those involved in the processing
	of edges and contours.},
  doi = {10.1098/rstb.2000.0769},
  institution = {Department of Mathematics, University of Utah, Salt Lake City, UT
	84112, USA.},
  keywords = {Animals; Hallucinations; Humans; Linear Models; Models, Biological;
	Visual Cortex, physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paupau},
  pmid = {11316482},
  timestamp = {2013.04.09},
  url = {http://dx.doi.org/10.1098/rstb.2000.0769}
}

@ARTICLE{Brette_2011,
  author = {Romain Brette and Dan F M Goodman},
  title = {Vectorized algorithms for spiking neural network simulation.},
  journal = {Neural Comput.},
  year = {2011},
  volume = {23},
  pages = {1503--1535},
  number = {6},
  month = {Jun},
  abstract = {High-level languages (Matlab, Python) are popular in neuroscience
	because they are flexible and accelerate development. However, for
	simulating spiking neural networks, the cost of interpretation is
	a bottleneck. We describe a set of algorithms to simulate large spiking
	neural networks efficiently with high-level languages using vector-based
	operations. These algorithms constitute the core of Brian, a spiking
	neural network simulator written in the Python language. Vectorized
	simulation makes it possible to combine the flexibility of high-level
	languages with the computational efficiency usually associated with
	compiled languages.},
  doi = {10.1162/NECO_a_00123},
  institution = {Laboratoire Psychologie de la Perception, CNRS and Université Paris
	Descartes, Paris 75006, France, and Département d'Etudes Cognitives,
	Ecole Normale Supérieure, Paris Cedex 05, 75230 France. romain.brette@ens.fr},
  keywords = {Action Potentials, physiology; Algorithms; Computer Simulation; Models,
	Neurological; Nerve Net, physiology; Neural Networks (Computer);
	Neurons, physiology; Synapses, physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {21395437},
  timestamp = {2013.02.01},
  url = {http://dx.doi.org/10.1162/NECO_a_00123}
}

@ARTICLE{Brunel_2003,
  author = {Brunel, N and Wang, X-J},
  title = {What determines the frequency of fast network oscillations with irregular
	neural discharges? I. Synaptic dynamics and excitation-inhibition
	balance},
  journal = {J. Neurophysiol.},
  year = {2003},
  volume = {90},
  pages = {415-430},
  keywords = {model},
  owner = {paula},
  timestamp = {2012.10.18}
}

@ARTICLE{Brunel_2001,
  author = {Brunel, N and Wang, X-J},
  title = {Effects of neuromodulation in a cortical network model of object
	working memory dominated by recurrent inhibition},
  journal = {J. Comput. Neurosci.},
  year = {2001},
  volume = {11},
  pages = {63-85},
  owner = {paula},
  timestamp = {2012.11.07}
}

@ARTICLE{Bullmore_2012,
  author = {Ed Bullmore and Olaf Sporns},
  title = {The economy of brain network organization.},
  journal = {Nat. Rev. Neurosci.},
  year = {2012},
  volume = {13},
  pages = {336--349},
  number = {5},
  month = {May},
  abstract = {The brain is expensive, incurring high material and metabolic costs
	for its size--relative to the size of the body--and many aspects
	of brain network organization can be mostly explained by a parsimonious
	drive to minimize these costs. However, brain networks or connectomes
	also have high topological efficiency, robustness, modularity and
	a 'rich club' of connector hubs. Many of these and other advantageous
	topological properties will probably entail a wiring-cost premium.
	We propose that brain organization is shaped by an economic trade-off
	between minimizing costs and allowing the emergence of adaptively
	valuable topological patterns of anatomical or functional connectivity
	between multiple neuronal populations. This process of negotiating,
	and re-negotiating, trade-offs between wiring cost and topological
	value continues over long (decades) and short (millisecond) timescales
	as brain networks evolve, grow and adapt to changing cognitive demands.
	An economical analysis of neuropsychiatric disorders highlights the
	vulnerability of the more costly elements of brain networks to pathological
	attack or abnormal development.},
  doi = {10.1038/nrn3214},
  institution = { Clinical Neuroscience Institute, University of Cambridge, Department
	of Psychiatry, Cambridge Biomedical Campus, Cambridge CB2 0SZ, UK.
	etb23@cam.ac.uk},
  keywords = {Adaptation, Physiological, physiology; Animals; Brain, cytology/physiology;
	Humans; Mental Disorders, metabolism/pathology/physiopathology; Nerve
	Net, cytology/physiology; Nervous System Diseases, metabolism/pathology/physiopathology;
	Neural Pathways, cytology/physiology},
  language = {eng},
  medline-pst = {epublish},
  owner = {paula},
  pii = {nrn3214},
  pmid = {22498897},
  timestamp = {2012.11.14},
  url = {http://dx.doi.org/10.1038/nrn3214}
}

@ARTICLE{Bullmore_2009,
  author = {Ed Bullmore and Olaf Sporns},
  title = {Complex brain networks: graph theoretical analysis of structural
	and functional systems.},
  journal = {Nat. Rev. Neurosci.},
  year = {2009},
  volume = {10},
  pages = {186--198},
  number = {3},
  month = {Mar},
  abstract = {Recent developments in the quantitative analysis of complex networks,
	based largely on graph theory, have been rapidly translated to studies
	of brain network organization. The brain's structural and functional
	systems have features of complex networks--such as small-world topology,
	highly connected hubs and modularity--both at the whole-brain scale
	of human neuroimaging and at a cellular scale in non-human animals.
	In this article, we review studies investigating complex brain networks
	in diverse experimental modalities (including structural and functional
	MRI, diffusion tensor imaging, magnetoencephalography and electroencephalography
	in humans) and provide an accessible introduction to the basic principles
	of graph theory. We also highlight some of the technical challenges
	and key questions to be addressed by future developments in this
	rapidly moving field.},
  doi = {10.1038/nrn2575},
  institution = { Clinical Neurosciences Institute, Department of Psychiatry, Addenbrooke's
	Hospital, Cambridge, CB2 2QQ, UK. etb23@cam.ac.uk},
  keywords = {Animals; Brain Mapping, methods; Brain, anatomy /&/ histology/physiology;
	Computer Graphics, trends; Electroencephalography, methods; Humans;
	Image Processing, Computer-Assisted, methods; Magnetic Resonance
	Imaging, methods; Magnetoencephalography, methods; Nerve Net, anatomy
	/&/ histology/physiology; Neural Networks (Computer)},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {nrn2575},
  pmid = {19190637},
  timestamp = {2012.11.14},
  url = {http://dx.doi.org/10.1038/nrn2575}
}

@ARTICLE{Bullmore_2011,
  author = {Edward T Bullmore and Danielle S Bassett},
  title = {Brain graphs: graphical models of the human brain connectome.},
  journal = {Annual Review of Clinical Psychology},
  year = {2011},
  volume = {7},
  pages = {113--140},
  abstract = {Brain graphs provide a relatively simple and increasingly popular
	way of modeling the human brain connectome, using graph theory to
	abstractly define a nervous system as a set of nodes (denoting anatomical
	regions or recording electrodes) and interconnecting edges (denoting
	structural or functional connections). Topological and geometrical
	properties of these graphs can be measured and compared to random
	graphs and to graphs derived from other neuroscience data or other
	(nonneural) complex systems. Both structural and functional human
	brain graphs have consistently demonstrated key topological properties
	such as small-worldness, modularity, and heterogeneous degree distributions.
	Brain graphs are also physically embedded so as to nearly minimize
	wiring cost, a key geometric property. Here we offer a conceptual
	review and methodological guide to graphical analysis of human neuroimaging
	data, with an emphasis on some of the key assumptions, issues, and
	trade-offs facing the investigator.},
  doi = {10.1146/annurev-clinpsy-040510-143934},
  institution = { Clinical Neuroscience Institute, Department of Psychiatry, University
	of Cambridge, Cambridge Biomedical Campus, Cambridge CB2 0SZ, United
	Kingdom. etb23@cam.ac.uk},
  keywords = {Animals; Brain, anatomy /&/ histology/physiology; Humans; Magnetic
	Resonance Imaging; Models, Neurological; Nerve Net, anatomy /&/ histology/physiology;
	Neural Networks (Computer)},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {21128784},
  timestamp = {2013.02.18},
  url = {http://dx.doi.org/10.1146/annurev-clinpsy-040510-143934}
}

@ARTICLE{Burrage_2004,
  author = {Burrage, K. and Burrage, P. M. and Tian, T.},
  title = {Numerical methods for strong solutions of stochastic differential
	equations: an overview},
  journal = {Proc. R. Soc. London, Ser. A},
  year = {2004},
  volume = {460},
  pages = {373-402},
  number = {2041},
  abstract = {This paper gives a review of recent progress in the design of numerical
	methods for computing the trajectories (sample paths) of solutions
	to stochastic differential equations. We give a brief survey of the
	area focusing on a number of application areas where approximations
	to strong solutions are important, with a particular focus on computational
	biology applications, and give the necessary analytical tools for
	understanding some of the important concepts associated with stochastic
	processes. We present the stochastic Taylor series expansion as the
	fundamental mechanism for constructing effective numerical methods,
	give general results that relate local and global order of convergence
	and mention the Magnus expansion as a mechanism for designing methods
	that preserve the underlying structure of the problem. We also present
	various classes of explicit and implicit methods for strong solutions,
	based on the underlying structure of the problem. Finally, we discuss
	implementation issues relating to maintaining the Brownian path,
	efficient simulation of stochastic integrals and variable–step–size
	implementations based on various types of control.},
  doi = {10.1098/rspa.2003.1247},
  eprint = {http://rspa.royalsocietypublishing.org/content/460/2041/373.full.pdf+html},
  url = {http://rspa.royalsocietypublishing.org/content/460/2041/373.abstract}
}

@ARTICLE{Buxton_1997,
  author = {Buxton, R and Frank, L},
  title = {A Model for the Coupling between Cerebral Blood Flow and Oxygen Metabolism
	During Neural Stimulation},
  journal = {J. Cereb. Blood Flow Metab.},
  year = {1997},
  volume = {17},
  pages = {64-72},
  owner = {paula},
  timestamp = {2012.10.29}
}

@ARTICLE{Buxton_2004,
  author = {Richard B Buxton and Kâmil Uludağ and David J Dubowitz and Thomas
	T Liu},
  title = {Modeling the hemodynamic response to brain activation.},
  journal = {Neuroimage},
  year = {2004},
  volume = {23 Suppl 1},
  pages = {S220--S233},
  abstract = {Neural activity in the brain is accompanied by changes in cerebral
	blood flow (CBF) and blood oxygenation that are detectable with functional
	magnetic resonance imaging (fMRI) techniques. In this paper, recent
	mathematical models of this hemodynamic response are reviewed and
	integrated. Models are described for: (1) the blood oxygenation level
	dependent (BOLD) signal as a function of changes in cerebral oxygen
	extraction fraction (E) and cerebral blood volume (CBV); (2) the
	balloon model, proposed to describe the transient dynamics of CBV
	and deoxy-hemoglobin (Hb) and how they affect the BOLD signal; (3)
	neurovascular coupling, relating the responses in CBF and cerebral
	metabolic rate of oxygen (CMRO(2)) to the neural activity response;
	and (4) a simple model for the temporal nonlinearity of the neural
	response itself. These models are integrated into a mathematical
	framework describing the steps linking a stimulus to the measured
	BOLD and CBF responses. Experimental results examining transient
	features of the BOLD response (post-stimulus undershoot and initial
	dip), nonlinearities of the hemodynamic response, and the role of
	the physiologic baseline state in altering the BOLD signal are discussed
	in the context of the proposed models. Quantitative modeling of the
	hemodynamic response, when combined with experimental data measuring
	both the BOLD and CBF responses, makes possible a more specific and
	quantitative assessment of brain physiology than is possible with
	standard BOLD imaging alone. This approach has the potential to enhance
	numerous studies of brain function in development, health, and disease.},
  doi = {10.1016/j.neuroimage.2004.07.013},
  institution = {of California-San Diego, La Jolla, CA 92093-0677, USA. rbuxton@ecsd.edu},
  keywords = {Algorithms; Blood Vessels, innervation/physiology; Brain, physiology;
	Cerebrovascular Circulation, physiology; Hemodynamics, physiology;
	Humans; Magnetic Resonance Imaging; Models, Neurological; Neurons,
	physiology; Nonlinear Dynamics; Oxygen, blood; Terminology as Topic},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S1053-8119(04)00378-7},
  pmid = {15501093},
  timestamp = {2013.08.19},
  url = {http://dx.doi.org/10.1016/j.neuroimage.2004.07.013}
}

@BOOK{Buzsaky_2006,
  title = {Rhythms of the Brain},
  publisher = {Oxford University Press},
  year = {2006},
  author = {Gyorgy Buzsaki},
  owner = {paula},
  timestamp = {2012.10.18}
}

@ARTICLE{Cabral_2011,
  author = {Cabral, Joana and Hugues, Etienne and Sporns, Olaf and Deco, Gustavo},
  title = {Role of local network oscillations in resting-state functional connectivity.},
  journal = {Neuroimage},
  year = {2011},
  volume = {57},
  pages = {130--139},
  number = {1},
  month = {Jul},
  __markedentry = {[paupau:6]},
  abstract = {Spatio-temporally organized low-frequency fluctuations (<0.1 Hz),
	observed in BOLD fMRI signal during rest, suggest the existence of
	underlying network dynamics that emerge spontaneously from intrinsic
	brain processes. Furthermore, significant correlations between distinct
	anatomical regions-or functional connectivity (FC)-have led to the
	identification of several widely distributed resting-state networks
	(RSNs). This slow dynamics seems to be highly structured by anatomical
	connectivity but the mechanism behind it and its relationship with
	neural activity, particularly in the gamma frequency range, remains
	largely unknown. Indeed, direct measurements of neuronal activity
	have revealed similar large-scale correlations, particularly in slow
	power fluctuations of local field potential gamma frequency range
	oscillations. To address these questions, we investigated neural
	dynamics in a large-scale model of the human brain's neural activity.
	A key ingredient of the model was a structural brain network defined
	by empirically derived long-range brain connectivity together with
	the corresponding conduction delays. A neural population, assumed
	to spontaneously oscillate in the gamma frequency range, was placed
	at each network node. When these oscillatory units are integrated
	in the network, they behave as weakly coupled oscillators. The time-delayed
	interaction between nodes is described by the Kuramoto model of phase
	oscillators, a biologically-based model of coupled oscillatory systems.
	For a realistic setting of axonal conduction speed, we show that
	time-delayed network interaction leads to the emergence of slow neural
	activity fluctuations, whose patterns correlate significantly with
	the empirically measured FC. The best agreement of the simulated
	FC with the empirically measured FC is found for a set of parameters
	where subsets of nodes tend to synchronize although the network is
	not globally synchronized. Inside such clusters, the simulated BOLD
	signal between nodes is found to be correlated, instantiating the
	empirically observed RSNs. Between clusters, patterns of positive
	and negative correlations are observed, as described in experimental
	studies. These results are found to be robust with respect to a biologically
	plausible range of model parameters. In conclusion, our model suggests
	how resting-state neural activity can originate from the interplay
	between the local neural dynamics and the large-scale structure of
	the brain.},
  doi = {10.1016/j.neuroimage.2011.04.010},
  institution = {Theoretical and Computational Neuroscience Group, Center for Brain
	and Cognition, Universitat Pompeu Fabra, Barcelona, Spain. joana.cabral@upf.edu},
  keywords = {Brain Mapping, methods; Brain, physiology; Humans; Magnetic Resonance
	Imaging; Models, Neurological; Neural Pathways, physiology; Rest,
	physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paupau},
  pii = {S1053-8119(11)00388-0},
  pmid = {21511044},
  timestamp = {2013.10.27},
  url = {http://dx.doi.org/10.1016/j.neuroimage.2011.04.010}
}

@ARTICLE{Callaway_2000,
  author = {Callaway, D. S. and Newman, M. E. and Strogatz, S. H. and Watts,
	D. J.},
  title = {Network robustness and fragility: percolation on random graphs.},
  journal = {Phys Rev Lett},
  year = {2000},
  volume = {85},
  pages = {5468--5471},
  number = {25},
  month = {Dec},
  __markedentry = {[paupau:]},
  abstract = {Recent work on the Internet, social networks, and the power grid has
	addressed the resilience of these networks to either random or targeted
	deletion of network nodes or links. Such deletions include, for example,
	the failure of Internet routers or power transmission lines. Percolation
	models on random graphs provide a simple representation of this process
	but have typically been limited to graphs with Poisson degree distribution
	at their vertices. Such graphs are quite unlike real-world networks,
	which often possess power-law or other highly skewed degree distributions.
	In this paper we study percolation on graphs with completely general
	degree distribution, giving exact solutions for a variety of cases,
	including site percolation, bond percolation, and models in which
	occupation probabilities depend on vertex degree. We discuss the
	application of our theory to the understanding of network resilience.},
  institution = {Department of Theoretical and Applied Mechanics, Cornell University,
	Ithaca, New York 14853-1503, USA.},
  keywords = {Algorithms; Animals; Cell Physiological Phenomena; Computer Simulation;
	Humans; Internet; Models, Statistical; Signal Transduction, physiology;
	Social Support},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paupau},
  pmid = {11136023},
  timestamp = {2013.10.27}
}

@ARTICLE{Cammoun_2012,
  author = {Leila Cammoun and Xavier Gigandet and Djalel Meskaldji and Jean Philippe
	Thiran and Olaf Sporns and Kim Q Do and Philippe Maeder and Reto
	Meuli and Patric Hagmann},
  title = {Mapping the human connectome at multiple scales with diffusion spectrum
	MRI.},
  journal = {J. Neurosci. Methods},
  year = {2012},
  volume = {203},
  pages = {386--397},
  number = {2},
  month = {Jan},
  abstract = {The global structural connectivity of the brain, the human connectome,
	is now accessible at millimeter scale with the use of MRI. In this
	paper, we describe an approach to map the connectome by constructing
	normalized whole-brain structural connection matrices derived from
	diffusion MRI tractography at 5 different scales. Using a template-based
	approach to match cortical landmarks of different subjects, we propose
	a robust method that allows (a) the selection of identical cortical
	regions of interest of desired size and location in different subjects
	with identification of the associated fiber tracts (b) straightforward
	construction and interpretation of anatomically organized whole-brain
	connection matrices and (c) statistical inter-subject comparison
	of brain connectivity at various scales. The fully automated post-processing
	steps necessary to build such matrices are detailed in this paper.
	Extensive validation tests are performed to assess the reproducibility
	of the method in a group of 5 healthy subjects and its reliability
	is as well considerably discussed in a group of 20 healthy subjects.},
  doi = {10.1016/j.jneumeth.2011.09.031},
  institution = {Signal Processing Laboratory (LTS5), Ecole Polytechnique Fédérale
	de Lausanne, Switzerland. leila.cammoun@epfl.ch},
  keywords = {Adult; Brain Mapping, methods; Brain, cytology/physiology; Diffusion
	Tensor Imaging, methods; Humans; Image Processing, Computer-Assisted,
	methods; Male; Neural Pathways, cytology/physiology; Young Adult},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S0165-0270(11)00599-1},
  pmid = {22001222},
  timestamp = {2013.02.18},
  url = {http://dx.doi.org/10.1016/j.jneumeth.2011.09.031}
}

@ARTICLE{Canales-Rodriguez2010,
  author = {Erick Jorge Canales-Rodríguez and Yasser Iturria-Medina and Yasser
	Alemán-Gómez and Lester Melie-García},
  title = {Deconvolution in diffusion spectrum imaging.},
  journal = {Neuroimage},
  year = {2010},
  volume = {50},
  pages = {136--149},
  number = {1},
  month = {Mar},
  abstract = {Diffusion spectrum magnetic resonance imaging (DSI) allows the estimation
	of the displacement probability density function (pdf) of water molecules,
	which contain valuable information about the microgeometry of the
	medium where the diffusion process occurs. It provides a more general
	approach to disentangle complex fiber structures in biological tissues
	because it does not assume any particular model of diffusion; even
	so, it has a number of limitations that remain unstudied. For instance,
	the theoretical model used to compute the displacement pdf is based
	on a Fourier transformation defined in the whole measurement space;
	however, in practice, it is computed using discrete signals with
	a finite support. As a consequence, the displacement pdf obtained
	from the experiments is the convolution between the true pdf and
	a point spread function (PSF) that completely depends on the experimental
	sampling scheme. In this work, a general framework to rectify and
	decontaminate the displacement pdf reconstructed from DSI is introduced.
	This framework is based on model-free deconvolution techniques that
	allow obtaining clearer and sharper DSI estimates. The method was
	tested in synthetic data as well as in real data measured from a
	healthy human volunteer. The results demonstrated that the angular
	resolution of DSI can be increased, potentially revealing new real
	fiber components and reducing both the artefactual peaks and the
	uncertainty of the local diffusion orientational distribution. Furthermore,
	the deconvolution process provides scalar maps of quantities derived
	from the propagator, such as the zero displacement probability, with
	higher tissue contrast.},
  doi = {10.1016/j.neuroimage.2009.11.066},
  institution = {Benito Menni Complex Assistencial en Salut Mental, Barcelona, Spain.
	ejcanalesr@gmail.com},
  keywords = {Algorithms; Anisotropy; Artifacts; Brain, anatomy /&/ histology/physiology;
	Computer Simulation; Diffusion; Diffusion Magnetic Resonance Imaging,
	methods; Humans; Male; Models, Neurological; Probability; Signal
	Processing, Computer-Assisted; Young Adult},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S1053-8119(09)01252-X},
  pmid = {19962440},
  timestamp = {2013.07.04},
  url = {http://dx.doi.org/10.1016/j.neuroimage.2009.11.066}
}

@ARTICLE{Canales-Rodriguez2010a,
  author = {Erick Jorge Canales-Rodríguez and Ching-Po Lin and Yasser Iturria-Medina
	and Chun-Hung Yeh and Kuan-Hung Cho and Lester Melie-García},
  title = {Diffusion orientation transform revisited.},
  journal = {Neuroimage},
  year = {2010},
  volume = {49},
  pages = {1326--1339},
  number = {2},
  month = {Jan},
  abstract = {Diffusion orientation transform (DOT) is a powerful imaging technique
	that allows the reconstruction of the microgeometry of fibrous tissues
	based on diffusion MRI data. The three main error sources involving
	this methodology are the finite sampling of the q-space, the practical
	truncation of the series of spherical harmonics and the use of a
	mono-exponential model for the attenuation of the measured signal.
	In this work, a detailed mathematical description that provides an
	extension to the DOT methodology is presented. In particular, the
	limitations implied by the use of measurements with a finite support
	in q-space are investigated and clarified as well as the impact of
	the harmonic series truncation. Near- and far-field analytical patterns
	for the diffusion propagator are examined. The near-field pattern
	makes available the direct computation of the probability of return
	to the origin. The far-field pattern allows probing the limitations
	of the mono-exponential model, which suggests the existence of a
	limit of validity for DOT. In the regimen from moderate to large
	displacement lengths the isosurfaces of the diffusion propagator
	reveal aberrations in form of artifactual peaks. Finally, the major
	contribution of this work is the derivation of analytical equations
	that facilitate the accurate reconstruction of some orientational
	distribution functions (ODFs) and skewness ODFs that are relatively
	immune to these artifacts. The new formalism was tested using synthetic
	and real data from a phantom of intersecting capillaries. The results
	support the hypothesis that the revisited DOT methodology could enhance
	the estimation of the microgeometry of fiber tissues.},
  doi = {10.1016/j.neuroimage.2009.09.067},
  institution = {Benito Menni Complex Assistencial en Salut Mental, Barcelona, Spain.},
  keywords = {Algorithms; Artifacts; Computer Simulation; Diffusion Magnetic Resonance
	Imaging, methods; Fourier Analysis; Models, Theoretical; Phantoms,
	Imaging},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S1053-8119(09)01066-0},
  pmid = {19815083},
  timestamp = {2013.07.04},
  url = {http://dx.doi.org/10.1016/j.neuroimage.2009.09.067}
}

@ARTICLE{Canales-Rodriguez2009,
  author = {Erick Jorge Canales-Rodríguez and Lester Melie-García and Yasser
	Iturria-Medina},
  title = {Mathematical description of q-space in spherical coordinates: exact
	q-ball imaging.},
  journal = {Magn Reson Med},
  year = {2009},
  volume = {61},
  pages = {1350--1367},
  number = {6},
  month = {Jun},
  abstract = {Novel methodologies have been recently developed to characterize the
	microgeometry of neural tissues and porous structures via diffusion
	MRI data. In line with these previous works, this article provides
	a detailed mathematical description of q-space in spherical coordinates
	that helps to highlight the differences and similarities between
	various related q-space methodologies proposed to date such as q-ball
	imaging (QBI), diffusion spectrum imaging (DSI), and diffusion orientation
	transform imaging (DOT). This formulation provides a direct relationship
	between the orientation distribution function (ODF) and the diffusion
	data without using any approximation. Under this relationship, the
	exact ODF can be computed by means of the Radon transform of the
	radial projection (in q-space) of the diffusion MRI signal. This
	new methodology, termed exact q-ball imaging (EQBI), was put into
	practice using an analytical ODF estimation in terms of spherical
	harmonics that allows obtaining model-free and model-based reconstructions.
	This work provides a new framework for combining information coming
	from diffusion data recorded on multiple spherical shells in q-space
	(hybrid diffusion imaging encoding scheme), which is capable of mapping
	ODF to a high accuracy. This represents a step toward a more efficient
	development of diffusion MRI experiments for obtaining better ODF
	estimates.},
  doi = {10.1002/mrm.21917},
  institution = {Neuroimaging Department, Cuban Neuroscience Center, Havana, Cuba.},
  keywords = {Algorithms; Computer Simulation; Diffusion Magnetic Resonance Imaging,
	methods; Image Enhancement, methods; Image Interpretation, Computer-Assisted,
	methods; Imaging, Three-Dimensional, methods; Models, Biological;
	Reproducibility of Results; Sensitivity and Specificity},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {19319889},
  timestamp = {2013.07.04},
  url = {http://dx.doi.org/10.1002/mrm.21917}
}

@ARTICLE{Canales-Rodriguez2008,
  author = {Erick Jorge Canales-Rodríguez and Lester Melie-García and Yasser
	Iturria-Medina and Eduardo Martínez-Montes and Yasser Alemán-Gómez
	and Ching-Po Lin},
  title = {Inferring multiple maxima in intravoxel white matter fiber distribution.},
  journal = {Magn Reson Med},
  year = {2008},
  volume = {60},
  pages = {616--630},
  number = {3},
  month = {Sep},
  abstract = {A new methodology is introduced that characterizes the intravoxel
	orientation distribution function (ODF) based on a single-fiber model
	of the diffusion MRI signal. Using a Bayesian framework the probability
	of finding a fiber in a specific orientation is obtained. The proposed
	ODF estimation relies on a cigar-like diffusion tensor model, the
	methodology is thus denominated Bayesian cigar-like diffusion tensor
	(BCDT). This work makes two major contributions: 1) the study of
	single-fiber models in detecting fibers with different volume fractions
	in a voxel, and 2) the introduction of the Nth-root correction to
	improve the detection of fibers with smaller volume fractions, where
	N is the number of diffusion MRI measurements. It is demonstrated
	that the incomplete signal modeling fails to reconstruct the relative
	fiber volume fractions, especially when the intravoxel diffusion
	profiles have dissimilar contributions to the diffusion MRI signal.
	In this situation the fibers with smaller contributions are hardly
	detectable. The BCDT method proposed here reduces this effect by
	introducing the Nth-root correction, making multiple fibers estimable.
	The performance of the new methodology is illustrated using synthetic
	and real data, as well as the data from a phantom of intersecting
	capillaries.},
  doi = {10.1002/mrm.21673},
  institution = {Neuroimaging Department, Cuban Neuroscience Center, Playa, Havana,
	Cuba.},
  keywords = {Algorithms; Brain Mapping, methods; Brain, anatomy /&/ histology;
	Diffusion Magnetic Resonance Imaging, methods; Humans; Nerve Fibers;
	Phantoms, Imaging},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {18727080},
  timestamp = {2013.07.04},
  url = {http://dx.doi.org/10.1002/mrm.21673}
}

@ARTICLE{Canales-Rodriguez2013,
  author = {Erick Jorge Canales-Rodríguez and Joaquim Radua and Edith Pomarol-Clotet
	and Salvador Sarró and Yasser Alemán-Gómez and Yasser Iturria-Medina
	and Raymond Salvador},
  title = {Statistical analysis of brain tissue images in the wavelet domain:
	wavelet-based morphometry.},
  journal = {Neuroimage},
  year = {2013},
  volume = {72},
  pages = {214--226},
  month = {May},
  abstract = {Wavelet-based methods have been developed for statistical analysis
	of functional MRI and PET data, where the wavelet transformation
	is employed as a tool for efficient signal representation. A number
	of studies using these approaches have reported better estimation
	capabilities, in terms of increased sensitivity and specificity,
	than the standard statistical analyses in the spatial domain. In
	line with these previous studies, the present report proposes a statistical
	analysis in the wavelet domain for the estimation of inter-group
	differences from structural MRI data. The procedure, called wavelet-based
	morphometry (WBM), was implemented under a voxel-based morphometry
	(VBM) style analysis. It was evaluated by comparing the gray-matter
	images of a group of 32 healthy subjects whose images were artificially
	altered to induce thinning of the cortex, with a different group
	of 32 healthy subjects whose images were unaltered. In order to quantify
	the performance of the reconstruction from a practical perspective,
	the same comparison was also conducted with standard VBM using SPM's
	Gaussian random fields and FSL's cluster-based statistics, family-wise
	error corrected, for datasets spatially-normalized via two different
	registration methods (i.e., SyN and FNIRT). The effect of using different
	amounts of smoothing, Battle-Lemarié filters and resolution levels
	in the wavelet transform was also investigated. Results support the
	proposed approach as a different and promising methodology to assess
	the structural morphometric differences between different populations
	of subjects.},
  doi = {10.1016/j.neuroimage.2013.01.058},
  institution = {FIDMAG Germanes Hospitalàries, C/ Dr. Antoni Pujadas, 38, 08830,
	Sant Boi de Llobregat, Barcelona, Spain. ejcanalesr@gmail.com},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S1053-8119(13)00105-5},
  pmid = {23384522},
  timestamp = {2013.07.04},
  url = {http://dx.doi.org/10.1016/j.neuroimage.2013.01.058}
}

@ARTICLE{Cardoso_2012,
  author = {M. Jorge Cardoso and Gavin Winston and Marc Modat and Shiva Keihaninejad
	and John Duncan and Sebastien Ourselin},
  title = {Geodesic shape-based averaging.},
  journal = {MICCAI.},
  year = {2012},
  volume = {15},
  pages = {26--33},
  number = {Pt 3},
  abstract = {A new method for the geometrical averaging of labels or landmarks
	is presented. This method expands the shape-based averaging framework
	from an Euclidean to a geodesic based distance, incorporating a spatially
	varying similarity term as time cost. This framework has unique geometrical
	properties, making it ideal for propagating very small structures
	following rigorous labelling protocols. The method is used to automate
	the seeding and way-pointing of optic radiation tractography in DTI
	imaging. The propagated seeds and waypoints follow a strict clinical
	protocol by being geometrically constrained to one single slice and
	by guaranteeing spatial contiguity. The proposed method not only
	reduces the fragmentation of the propagated areas but also significantly
	increases the seed positioning accuracy and subsequent tractography
	results when compared to state-of-the-art label fusion techniques.},
  institution = {Centre for Medical Image Computing, UCL, UK.},
  keywords = {Algorithms; Brain, anatomy /&/ histology; Connectome, methods; Data
	Compression, methods; Diffusion Tensor Imaging, methods; Humans;
	Image Enhancement, methods; Image Interpretation, Computer-Assisted,
	methods; Imaging, Three-Dimensional, methods; Nerve Fibers, Myelinated,
	ultrastructure; Reproducibility of Results; Sensitivity and Specificity},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {23286110},
  timestamp = {2013.02.18}
}

@ARTICLE{Castellanos_2013,
  author = {F. Xavier Castellanos and Adriana Di Martino and R. Cameron Craddock
	and Ashesh D Mehta and Michael P Milham},
  title = {Clinical applications of the functional connectome.},
  journal = {Neuroimage},
  year = {2013},
  volume = {80},
  pages = {527--540},
  month = {Oct},
  abstract = {Central to the development of clinical applications of functional
	connectomics for neurology and psychiatry is the discovery and validation
	of biomarkers. Resting state fMRI (R-fMRI) is emerging as a mainstream
	approach for imaging-based biomarker identification, detecting variations
	in the functional connectome that can be attributed to clinical variables
	(e.g., diagnostic status). Despite growing enthusiasm, many challenges
	remain. Here, we assess evidence of the readiness of R-fMRI based
	functional connectomics to lead to clinically meaningful biomarker
	identification through the lens of the criteria used to evaluate
	clinical tests (i.e., validity, reliability, sensitivity, specificity,
	and applicability). We focus on current R-fMRI-based prediction efforts,
	and survey R-fMRI used for neurosurgical planning. We identify gaps
	and needs for R-fMRI-based biomarker identification, highlighting
	the potential of emerging conceptual, analytical and cultural innovations
	(e.g., the Research Domain Criteria Project (RDoC), open science
	initiatives, and Big Data) to address them. Additionally, we note
	the need to expand future efforts beyond identification of biomarkers
	for disease status alone to include clinical variables related to
	risk, expected treatment response and prognosis.},
  doi = {10.1016/j.neuroimage.2013.04.083},
  institution = {Phyllis Green and Randolph Cowen Institute for Pediatric Neuroscience,
	New York University Child Study Center, New York, NY 10016, USA;
	Nathan Kline Institute for Psychiatric Research, Orangeburg, NY 10962,
	USA. Electronic address: Francisco.Castellanos@nyumc.org.},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S1053-8119(13)00430-8},
  pmid = {23631991},
  timestamp = {2013.08.20},
  url = {http://dx.doi.org/10.1016/j.neuroimage.2013.04.083}
}

@ARTICLE{Castro_2005,
  author = {Igor de Castro and Daniel de Holanda Christoph and Daniel Paes dos
	Santos and José Alberto Landeiro},
  title = {Internal structure of the cerebral hemispheres: an introduction of
	fiber dissection technique.},
  journal = {Arq Neuropsiquiatr},
  year = {2005},
  volume = {63},
  pages = {252--258},
  number = {2A},
  month = {Jun},
  abstract = {The aim of this study is to introduce the fiber dissection technique
	and its importance in the comprehension of the three-dimensional
	intrinsic anatomy of the brain. A total of twenty brain hemispheres
	were dissected. Using Kingler's technique we demonstrated the intrinsic
	structures of the brain. The supra lateral aspect of the brain as
	well as the medial aspect were presented. The most important fiber
	systems were demonstrated. The use and comprehension of new neuroimaging
	techniques demand a better understanding of this fascinating anatomy.
	The knowledge acquired with this technique will improve our understanding
	of critical pathways of the central nervous system.},
  institution = {Serviço de Neurocirurgia do Hospital da Força Aérea do Galeão, Rio
	de Janeiro RJ, Brasil.},
  keywords = {Brain, anatomy /&/ histology; Cadaver; Dissection, methods; Humans},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S0004-282X2005000200011},
  pmid = {16100971},
  timestamp = {2013.07.04}
}

@BOOK{Chacon_2009,
  title = {Pro Git},
  publisher = {Apress},
  year = {2009},
  author = {Chacon, S.},
  owner = {paula},
  timestamp = {2012.12.26},
  url = {http://progit.org/book}
}

@ARTICLE{Clearwater_2008,
  author = {J. M. Clearwater and C. J. Rennie and P. A. Robinson},
  title = {Mean field model of acetylcholine mediated dynamics in the thalamocortical
	system.},
  journal = {J Theor Biol},
  year = {2008},
  volume = {255},
  pages = {287--298},
  number = {3},
  month = {Dec},
  abstract = {A recent continuum model of the large scale electrical activity of
	the thalamocortical system is generalized to include cholinergic
	modulation. The model is examined analytically and numerically to
	determine the effect of acetylcholine (ACh) on its steady states,
	linear stability, spectrum, and temporal responses. Changing the
	ACh concentration moves the system between zones of one, three, and
	five steady states, showing that neuromodulation of synaptic strength
	is a possible mechanism by which multiple steady states emerge in
	the brain. The lowest firing rate steady state is always stable,
	and subsequent fixed points alternate between stable and unstable.
	Increasing ACh concentration changes the form of the spectrum. Increasing
	the tonic level of ACh concentration increases the magnitudes of
	the N100 and P200 in the evoked response potential (ERP), without
	changing the timing of these peaks. Driving the system with a pulse
	of cholinergic activity results in a transient increase in the firing
	rate of cortical neurons that lasts over 10s. Step-like increases
	in cortical ACh concentration cause increases in the firing rate
	of cortical neurons, with rapid responses due to fast acting nicotinic
	receptors and slower responses due to muscarinic receptor suppression
	of intracortical connections.},
  doi = {10.1016/j.jtbi.2008.08.010},
  institution = {School of Physics, University of Sydney, New South Wales 2006, Australia.
	j.clearwater@physics.usyd.edu.au},
  keywords = {Acetylcholine, physiology; Animals; Cerebral Cortex, metabolism; Computer
	Simulation; Electroencephalography; Evoked Potentials, physiology;
	Humans; Models, Neurological; Neurons, physiology; Receptors, Muscarinic,
	metabolism; Receptors, Nicotinic, metabolism; Synaptic Transmission,
	physiology; Thalamus, metabolism},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S0022-5193(08)00423-2},
  pmid = {18775441},
  timestamp = {2013.08.19},
  url = {http://dx.doi.org/10.1016/j.jtbi.2008.08.010}
}

@ARTICLE{Clearwater_2007,
  author = {J. M. Clearwater and C. J. Rennie and P. A. Robinson},
  title = {Mean field model of acetylcholine mediated dynamics in the cerebral
	cortex.},
  journal = {Biol Cybern},
  year = {2007},
  volume = {97},
  pages = {449--460},
  number = {5-6},
  month = {Dec},
  abstract = {A recent continuum model of the large scale electrical activity of
	the cerebral cortex is generalized to include cholinergic modulation.
	In this model, dynamic modulation of synaptic strength acts over
	the time scales of nicotinic and muscarinic receptor action. The
	cortical model is analyzed to determine the effect of acetylcholine
	(ACh) on its steady states, linear stability, spectrum, and temporal
	responses to changes in subcortical input. ACh increases the firing
	rate in steady states of the system. Changing ACh concentration does
	not introduce oscillatory behavior into the system, but increases
	the overall spectral power. Model responses to pulses in subcortical
	input are affected by the tonic level of ACh concentration, with
	higher levels of ACh increasing the magnitude firing rate response
	of excitatory cortical neurons to pulses of subcortical input. Numerical
	simulations are used to explore the temporal dynamics of the model
	in response to changes in ACh concentration. Evidence is seen of
	a transition from a state in which intracortical inputs are emphasized
	to a state where thalamic afferents have enhanced influence. Perturbations
	in ACh concentration cause changes in the firing rate of cortical
	neurons, with rapid responses due to fast acting facilitatory effects
	of nicotinic receptors on subcortical afferents, and slower responses
	due to muscarinic suppression of intracortical connections. Together,
	these numerical simulations demonstrate that the actions of ACh could
	be a significant factor modulating early components of evoked response
	potentials.},
  doi = {10.1007/s00422-007-0186-9},
  institution = {School of Physics, University of Sydney, Sydney, NSW 2006, Australia.
	j.clearwater@physics.usyd.edu.au},
  keywords = {Acetylcholine, metabolism/pharmacology; Animals; Cerebral Cortex,
	drug effects/physiology/radiation effects; Dose-Response Relationship,
	Drug; Electric Stimulation, methods; Electroencephalography; Evoked
	Potentials, drug effects; Mathematics; Models, Neurological; Nonlinear
	Dynamics; Spectrum Analysis; Time Factors},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {17965874},
  timestamp = {2013.08.19},
  url = {http://dx.doi.org/10.1007/s00422-007-0186-9}
}

@ARTICLE{Coombes_2010,
  author = {S. Coombes},
  title = {Large-scale neural dynamics: simple and complex.},
  journal = {Neuroimage},
  year = {2010},
  volume = {52},
  pages = {731--739},
  number = {3},
  month = {Sep},
  abstract = {We review the use of neural field models for modelling the brain at
	the large scales necessary for interpreting EEG, fMRI, MEG and optical
	imaging data. Albeit a framework that is limited to coarse-grained
	or mean-field activity, neural field models provide a framework for
	unifying data from different imaging modalities. Starting with a
	description of neural mass models, we build to spatially extend cortical
	models of layered two-dimensional sheets with long range axonal connections
	mediating synaptic interactions. Reformulations of the fundamental
	non-local mathematical model in terms of more familiar local differential
	(brain wave) equations are described. Techniques for the analysis
	of such models, including how to determine the onset of spatio-temporal
	pattern forming instabilities, are reviewed. Extensions of the basic
	formalism to treat refractoriness, adaptive feedback and inhomogeneous
	connectivity are described along with open challenges for the development
	of multi-scale models that can integrate macroscopic models at large
	spatial scales with models at the microscopic scale.},
  doi = {10.1016/j.neuroimage.2010.01.045},
  institution = {School of Mathematical Sciences, University of Nottingham, Nottingham,
	NG7 2RD, UK. stephen.coombes@nottingham.ac.uk},
  keywords = {Animals; Brain Mapping, methods; Brain, physiology; Electroencephalography;
	Humans; Image Interpretation, Computer-Assisted, methods; Magnetic
	Resonance Imaging; Magnetoencephalography; Models, Neurological;
	Models, Theoretical; Signal Processing, Computer-Assisted},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S1053-8119(10)00067-4},
  pmid = {20096791},
  timestamp = {2013.04.17},
  url = {http://dx.doi.org/10.1016/j.neuroimage.2010.01.045}
}

@ELECTRONIC{Coombes_2006,
  author = {Coombes, S.},
  month = {July},
  year = {2008},
  title = {Neural Fields},
  organization = {Scholarpedia},
  url = {http://www.scholarpedia.org/article/Neural_fields},
  owner = {paula},
  timestamp = {2013.02.18}
}

@ARTICLE{Coombes_2008scholarpedia,
  author = {Coombes, S.},
  title = {Neural fields},
  journal = {Scholarpedia},
  year = {2008},
  volume = {xx},
  pages = {-:-},
  month = {July},
  owner = {paula},
  timestamp = {2013.02.18},
  url = {http://www.scholarpedia.org/article/Neural_fields}
}

@ARTICLE{Coombes_2007,
  author = {S. Coombes and N. A. Venkov and L. Shiau and I. Bojak and D. T J
	Liley and C. R. Laing},
  title = {Modeling electrocortical activity through improved local approximations
	of integral neural field equations.},
  journal = {Phys. Rev. E: Stat., Nonlinear, Soft Matter Phys.},
  year = {2007},
  volume = {76},
  pages = {051901},
  number = {5 Pt 1},
  month = {Nov},
  abstract = {Neural field models of firing rate activity typically take the form
	of integral equations with space-dependent axonal delays. Under natural
	assumptions on the synaptic connectivity we show how one can derive
	an equivalent partial differential equation (PDE) model that properly
	treats the axonal delay terms of the integral formulation. Our analysis
	avoids the so-called long-wavelength approximation that has previously
	been used to formulate PDE models for neural activity in two spatial
	dimensions. Direct numerical simulations of this PDE model show instabilities
	of the homogeneous steady state that are in full agreement with a
	Turing instability analysis of the original integral model. We discuss
	the benefits of such a local model and its usefulness in modeling
	electrocortical activity. In particular, we are able to treat "patchy"
	connections, whereby a homogeneous and isotropic system is modulated
	in a spatially periodic fashion. In this case the emergence of a
	"lattice-directed" traveling wave predicted by a linear instability
	analysis is confirmed by the numerical simulation of an appropriate
	set of coupled PDEs.},
  institution = {School of Mathematical Sciences, University of Nottingham, NG7 2RD,
	United Kingdom.},
  keywords = {Action Potentials, physiology; Animals; Biological Clocks, physiology;
	Computer Simulation; Electroencephalography, methods; Electromagnetic
	Fields; Humans; Models, Neurological; Neocortex, physiology; Nerve
	Net, physiology; Neurons, physiology; Synaptic Transmission, physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {18233681},
  timestamp = {2013.02.18}
}

@ARTICLE{Cornelis_2012,
  author = {Hugo Cornelis and Armando L Rodriguez and Allan D Coop and James
	M Bower},
  title = {Python as a federation tool for GENESIS 3.0.},
  journal = {PLoS One},
  year = {2012},
  volume = {7},
  pages = {e29018},
  number = {1},
  abstract = {The GENESIS simulation platform was one of the first broad-scale modeling
	systems in computational biology to encourage modelers to develop
	and share model features and components. Supported by a large developer
	community, it participated in innovative simulator technologies such
	as benchmarking, parallelization, and declarative model specification
	and was the first neural simulator to define bindings for the Python
	scripting language. An important feature of the latest version of
	GENESIS is that it decomposes into self-contained software components
	complying with the Computational Biology Initiative federated software
	architecture. This architecture allows separate scripting bindings
	to be defined for different necessary components of the simulator,
	e.g., the mathematical solvers and graphical user interface. Python
	is a scripting language that provides rich sets of freely available
	open source libraries. With clean dynamic object-oriented designs,
	they produce highly readable code and are widely employed in specialized
	areas of software component integration. We employ a simplified wrapper
	and interface generator to examine an application programming interface
	and make it available to a given scripting language. This allows
	independent software components to be 'glued' together and connected
	to external libraries and applications from user-defined Python or
	Perl scripts. We illustrate our approach with three examples of Python
	scripting. (1) Generate and run a simple single-compartment model
	neuron connected to a stand-alone mathematical solver. (2) Interface
	a mathematical solver with GENESIS 3.0 to explore a neuron morphology
	from either an interactive command-line or graphical user interface.
	(3) Apply scripting bindings to connect the GENESIS 3.0 simulator
	to external graphical libraries and an open source three dimensional
	content creation suite that supports visualization of models based
	on electron microscopy and their conversion to computational models.
	Employed in this way, the stand-alone software components of the
	GENESIS 3.0 simulator provide a framework for progressive federated
	software development in computational neuroscience.},
  doi = {10.1371/journal.pone.0029018},
  institution = {Cornelis H. Research Imaging Institute, University of Texas Health
	Science Center at San Antonio, San Antonio, Texas, United States
	of America. Hugo.Cornelis@gmail.com},
  keywords = {Computational Biology, methods; Programming Languages; Software},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {PONE-D-11-06506},
  pmid = {22276101},
  timestamp = {2013.02.01},
  url = {http://dx.doi.org/10.1371/journal.pone.0029018}
}

@ARTICLE{Costa_2005,
  author = {Madalena Costa and Ary L Goldberger and C-K. Peng},
  title = {Multiscale entropy analysis of biological signals.},
  journal = {Phys. Rev. E: Stat., Nonlinear, Soft Matter Phys.},
  year = {2005},
  volume = {71},
  pages = {021906},
  number = {2 Pt 1},
  month = {Feb},
  abstract = {Traditional approaches to measuring the complexity of biological signals
	fail to account for the multiple time scales inherent in such time
	series. These algorithms have yielded contradictory findings when
	applied to real-world datasets obtained in health and disease states.
	We describe in detail the basis and implementation of the multiscale
	entropy (MSE) method. We extend and elaborate previous findings showing
	its applicability to the fluctuations of the human heartbeat under
	physiologic and pathologic conditions. The method consistently indicates
	a loss of complexity with aging, with an erratic cardiac arrhythmia
	(atrial fibrillation), and with a life-threatening syndrome (congestive
	heart failure). Further, these different conditions have distinct
	MSE curve profiles, suggesting diagnostic uses. The results support
	a general "complexity-loss" theory of aging and disease. We also
	apply the method to the analysis of coding and noncoding DNA sequences
	and find that the latter have higher multiscale entropy, consistent
	with the emerging view that so-called "junk DNA" sequences contain
	important biological information.},
  institution = {Margret and H. A. Rey Institute for Nonlinear Dynamics in Medicine,
	Beth Israel Deaconess Medical Center, Harvard Medical School, Boston,
	Massachusetts 02215, USA.},
  keywords = {Adult; Aged; Algorithms; Atrial Fibrillation, diagnosis; Computer
	Simulation; Diagnosis, Computer-Assisted, methods; Electrocardiography,
	Ambulatory, methods; Entropy; Female; Heart Failure, diagnosis; Humans;
	Male; Middle Aged; Models, Biological; Models, Chemical; Reproducibility
	of Results; Sensitivity and Specificity; Sequence Analysis, DNA,
	methods},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {15783351},
  timestamp = {2013.02.11}
}

@ARTICLE{Costa_2002a,
  author = {Madalena Costa and Ary L Goldberger and C-K. Peng},
  title = {Multiscale entropy analysis of complex physiologic time series.},
  journal = {Phys. Rev. Lett.},
  year = {2002},
  volume = {89},
  pages = {068102},
  number = {6},
  month = {Aug},
  abstract = {There has been considerable interest in quantifying the complexity
	of physiologic time series, such as heart rate. However, traditional
	algorithms indicate higher complexity for certain pathologic processes
	associated with random outputs than for healthy dynamics exhibiting
	long-range correlations. This paradox may be due to the fact that
	conventional algorithms fail to account for the multiple time scales
	inherent in healthy physiologic dynamics. We introduce a method to
	calculate multiscale entropy (MSE) for complex time series. We find
	that MSE robustly separates healthy and pathologic groups and consistently
	yields higher values for simulated long-range correlated noise compared
	to uncorrelated noise.},
  institution = {, Boston, Massachusetts 02215, USA.},
  keywords = {Algorithms; Disease; Entropy; Heart Failure, physiopathology; Heart
	Rate, physiology; Humans; Models, Biological; Pathology, methods;
	Physiology, methods; Time Factors},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {12190613},
  timestamp = {2013.02.11}
}

@ARTICLE{Craddock_2013,
  author = {R. Cameron Craddock and Saad Jbabdi and Chao-Gan Yan and Joshua T
	Vogelstein and F. Xavier Castellanos and Adriana Di Martino and Clare
	Kelly and Keith Heberlein and Stan Colcombe and Michael P Milham},
  title = {Imaging human connectomes at the macroscale.},
  journal = {Nat Methods},
  year = {2013},
  volume = {10},
  pages = {524--539},
  number = {6},
  month = {Jun},
  abstract = {At macroscopic scales, the human connectome comprises anatomically
	distinct brain areas, the structural pathways connecting them and
	their functional interactions. Annotation of phenotypic associations
	with variation in the connectome and cataloging of neurophenotypes
	promise to transform our understanding of the human brain. In this
	Review, we provide a survey of magnetic resonance imaging–based measurements
	of functional and structural connectivity. We highlight emerging
	areas of development and inquiry and emphasize the importance of
	integrating structural and functional perspectives on brain architecture.},
  doi = {10.1038/nmeth.2482},
  institution = {Center for the Developing Brain, Child Mind Institute, New York,
	New York, USA.},
  keywords = {Brain, cytology/physiology; Connectome; Humans; Magnetic Resonance
	Imaging, methods; Phenotype},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {nmeth.2482},
  pmid = {23722212},
  timestamp = {2013.08.20},
  url = {http://dx.doi.org/10.1038/nmeth.2482}
}

@ARTICLE{Craddock_2013a,
  author = {R. Cameron Craddock and Michael P Milham and Stephen M Laconte},
  title = {Predicting intrinsic brain activity.},
  journal = {Neuroimage},
  year = {2013},
  volume = {82C},
  pages = {127--136},
  month = {May},
  abstract = {Multivariate supervised learning methods exhibit a remarkable ability
	to decode externally driven sensory, behavioral, and cognitive states
	from functional neuroimaging data. Although they are typically applied
	to task-based analyses, supervised learning methods are equally applicable
	to intrinsic effective and functional connectivity analyses. The
	obtained models of connectivity incorporate the multivariate interactions
	between all brain regions simultaneously, which will result in a
	more accurate representation of the connectome than the ones available
	with standard bivariate methods. Additionally the models can be applied
	to decode or predict the time series of intrinsic brain activity
	of a region from an independent dataset. The obtained prediction
	accuracy provides a measure of the integration between a brain region
	and other regions in its network, as well as a method for evaluating
	acquisition and preprocessing pipelines for resting state fMRI data.
	This article describes a method for learning multivariate models
	of connectivity. The method is applied in the non-parametric prediction
	accuracy, influence, and reproducibility-resampling (NPAIRS) framework,
	to study the regional variation of prediction accuracy and reproducibility
	(Strother et al., 2002). The resulting spatial distribution of these
	metrics is consistent with the functional hierarchy proposed by Mesulam
	(1998). Additionally we illustrate the utility of the multivariate
	regression connectivity modeling method for optimizing experimental
	parameters and assessing the quality of functional neuroimaging data.},
  doi = {10.1016/j.neuroimage.2013.05.072},
  institution = {Virginia Tech Carilion Research Institute, Roanoke, VA, USA; Center
	for the Developing Brain, Child Mind Institute, New York, NY, USA;
	Nathan S. Kline Institute for Psychiatric Research, Orangeburg, NY,
	USA.},
  language = {eng},
  medline-pst = {aheadofprint},
  owner = {paula},
  pii = {S1053-8119(13)00572-7},
  pmid = {23707580},
  timestamp = {2013.08.20},
  url = {http://dx.doi.org/10.1016/j.neuroimage.2013.05.072}
}

@ARTICLE{Crook_1998,
  author = {S. M. Crook and G. B. Ermentrout and J. M. Bower},
  title = {Dendritic and synaptic effects in systems of coupled cortical oscillators.},
  journal = {J Comput Neurosci},
  year = {1998},
  volume = {5},
  pages = {315--329},
  number = {3},
  month = {Jul},
  abstract = {We explore the influence of synaptic location and form on the behavior
	of networks of coupled cortical oscillators. First, we develop a
	model of two coupled somatic oscillators that includes passive dendritic
	cables. Using a phase model approach, we show that the synchronous
	solution can change from a stable solution to an unstable one as
	the cable lengthens and the synaptic position moves further from
	the soma. We confirm this prediction using a system of coupled compartmental
	models. We also demonstrate that when the synchronous solution becomes
	unstable, a bifurcation occurs and a pair of asynchronous stable
	solutions appear, causing a phase lag between the cells in the system.
	Then using a variety of coupling functions and different synaptic
	positions, we show that distal connections and broad synaptic time
	courses encourage phase lags that can be reduced, eliminated, or
	enhanced by the presence of active currents in the dendrite. This
	mechanism may appear in neural systems where proximal connections
	could be used to encourage synchrony, and distal connections and
	broad synaptic time courses could be used to produce phase lags that
	can be modulated by active currents.},
  institution = {Center for Computational Biology, Montana State University, Bozeman
	59717, USA. crook@nervana.montana.edu},
  keywords = {Dendrites, physiology; Models, Neurological; Periodicity; Pyramidal
	Cells, physiology/ultrastructure; Synapses, physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {9663554},
  timestamp = {2013.09.04}
}

@ARTICLE{Crook_1997,
  author = {S. M. Crook and G. B. Ermentrout and M. C. Vanier and J. M. Bower},
  title = {The role of axonal delay in the synchronization of networks of coupled
	cortical oscillators.},
  journal = {J Comput Neurosci},
  year = {1997},
  volume = {4},
  pages = {161--172},
  number = {2},
  month = {Apr},
  abstract = {Coupled oscillator models use a single phase variable to approximate
	the voltage oscillation of each neuron during repetitive firing where
	the behavior of the model depends on the connectivity and the interaction
	function chosen to describe the coupling. We introduce a network
	model consisting of a continuum of these oscillators that includes
	the effects of spatially decaying coupling and axonal delay. We derive
	equations for determining the stability of solutions and analyze
	the network behavior for two different interaction functions. The
	first is a sine function, and the second is derived from a compartmental
	model of a pyramidal cell. In both cases, the system of coupled neural
	oscillators can undergo a bifurcation from synchronous oscillations
	to waves. The change in qualitative behavior is due to the axonal
	delay, which causes distant connections to encourage a phase shift
	between cells. We suggest that this mechanism could contribute to
	the behavior observed in several neurobiological systems.},
  institution = {Department of Mathematics, University of Maryland, College Park 20742,
	USA. crook@bart.niddk.nih.gov},
  keywords = {Axons, physiology; Cortical Synchronization; Neural Networks (Computer);
	Time Factors},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {9154522},
  timestamp = {2013.09.04}
}

@ARTICLE{Culic2009,
  author = {Milka Culic and Biljana Gjoneska and Hiie Hinrikus and Magnus Jändel
	and Wlodzimierz Klonowski and Hans Liljenström and Nada Pop-Jordanova
	and Dan Psatta and Dietrich von Rosen and Björn Wahlund},
  title = {Signatures of depression in non-stationary biometric time series.},
  journal = {Comput. Intell. Neurosci.},
  year = {2009},
  volume = {--},
  pages = {989824},
  abstract = {This paper is based on a discussion that was held during a special
	session on models of mental disorders, at the NeuroMath meeting in
	Stockholm, Sweden, in September 2008. At this occasion, scientists
	from different countries and different fields of research presented
	their research and discussed open questions with regard to analyses
	and models of mental disorders, in particular depression. The content
	of this paper emerged from these discussions and in the presentation
	we briefly link biomarkers (hormones), bio-signals (EEG) and biomaps
	(brain-maps via EEG) to depression and its treatments, via linear
	statistical models as well as nonlinear dynamic models. Some examples
	involving EEG-data are presented.},
  comment = {ToRead},
  doi = {10.1155/2009/989824},
  institution = {Department of Neurobiology Institute for Biological Research, University
	of Belgrade, 11000 Belgrade, Serbia.},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {19584928},
  timestamp = {2013.04.09},
  url = {http://dx.doi.org/10.1155/2009/989824}
}

@ARTICLE{Dafilis_2013,
  author = {Dafilis, Mathew P. and Frascoli, Federico and Cadusch, Peter J. and
	Liley, David T J.},
  title = {Four dimensional chaos and intermittency in a mesoscopic model of
	the electroencephalogram.},
  journal = {Chaos},
  year = {2013},
  volume = {23},
  pages = {023111},
  number = {2},
  month = {Jun},
  abstract = {The occurrence of so-called four dimensional chaos in dynamical systems
	represented by coupled, nonlinear, ordinary differential equations
	is rarely reported in the literature. In this paper, we present evidence
	that Liley's mesoscopic theory of the electroencephalogram (EEG),
	which has been used to describe brain activity in a variety of clinically
	relevant contexts, possesses a chaotic attractor with a Kaplan-Yorke
	dimension significantly larger than three. This accounts for simple,
	high order chaos for a physiologically admissible parameter set.
	Whilst the Lyapunov spectrum of the attractor has only one positive
	exponent, the contracting dimensions are such that the integer part
	of the Kaplan-Yorke dimension is three, thus giving rise to four
	dimensional chaos. A one-parameter bifurcation analysis with respect
	to the parameter corresponding to extracortical input is conducted,
	with results indicating that the origin of chaos is due to an inverse
	period doubling cascade. Hence, in the vicinity of the high order,
	strange attractor, the model is shown to display intermittent behavior,
	with random alternations between oscillatory and chaotic regimes.
	This phenomenon represents a possible dynamical justification of
	some of the typical features of clinically established EEG traces,
	which can arise in the case of burst suppression in anesthesia and
	epileptic encephalopathies in early infancy.},
  doi = {10.1063/1.4804176},
  institution = {Vaccine and Immunisation Research Group, Murdoch Childrens' Research
	Institute and Melbourne School of Population Health, The University
	of Melbourne, Carlton VIC 3010, Australia.},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paupau},
  pmid = {23822476},
  timestamp = {2013.08.24},
  url = {http://dx.doi.org/10.1063/1.4804176}
}

@ARTICLE{Dale_1999,
  author = {Dale, A.M. and Fischl, B. and Sereno, M.I.},
  title = {Cortical Surface-Based Analysis. I. Segmentation and Surface Reconstruction},
  journal = {Neuroimage},
  year = {1999},
  volume = {9},
  pages = {179--194},
  number = {2},
  issn = {1053-8119},
  publisher = {Elsevier}
}

@ARTICLE{Dammers_2012,
  author = {Jürgen Dammers and Lukas Breuer and Markus Axer and Melanie Kleiner
	and Björn Eiben and David Grässel and Timo Dickscheid and Karl Zilles
	and Katrin Amunts and N. Joni Shah and Uwe Pietrzyk},
  title = {Automatic identification of gray and white matter components in polarized
	light imaging.},
  journal = {Neuroimage},
  year = {2012},
  volume = {59},
  pages = {1338--1347},
  number = {2},
  month = {Jan},
  abstract = {Polarized light imaging (PLI) enables the visualization of fiber tracts
	with high spatial resolution in microtome sections of postmortem
	brains. Vectors of the fiber orientation defined by inclination and
	direction angles can directly be derived from the optical signals
	employed by PLI analysis. The polarization state of light propagating
	through a rotating polarimeter is varied in such a way that the detected
	signal of each spatial unit describes a sinusoidal signal. Noise,
	light scatter and filter inhomogeneities, however, interfere with
	the original sinusoidal PLI signals, which in turn have direct impact
	on the accuracy of subsequent fiber tracking. Recently we showed
	that the primary sinusoidal signals can effectively be restored after
	noise and artifact rejection utilizing independent component analysis
	(ICA). In particular, regions with weak intensities are greatly enhanced
	after ICA based artifact rejection and signal restoration. Here,
	we propose a user independent way of identifying the components of
	interest after decomposition; i.e., components that are related to
	gray and white matter. Depending on the size of the postmortem brain
	and the section thickness, the number of independent component maps
	can easily be in the range of a few ten thousand components for one
	brain. Therefore, we developed an automatic and, more importantly,
	user independent way of extracting the signal of interest. The automatic
	identification of gray and white matter components is based on the
	evaluation of the statistical properties of the so-called feature
	vectors of each individual component map, which, in the ideal case,
	shows a sinusoidal waveform. Our method enables large-scale analysis
	(i.e., the analysis of thousands of whole brain sections) of nerve
	fiber orientations in the human brain using polarized light imaging.},
  doi = {10.1016/j.neuroimage.2011.08.030},
  institution = {Institute of Neuroscience and Medicine (INM-1, INM-2, INM-4), Research
	Centre Jülich, Germany. J.Dammers@fz-juelich.de},
  keywords = {Algorithms; Artificial Intelligence; Brain, cytology; Humans; Image
	Enhancement, methods; Image Interpretation, Computer-Assisted, methods;
	Lighting, methods; Microscopy, Polarization, methods; Nerve Fibers,
	Myelinated, ultrastructure; Neurons, cytology; Pattern Recognition,
	Automated, methods; Reproducibility of Results; Sensitivity and Specificity},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S1053-8119(11)00923-2},
  pmid = {21875673},
  timestamp = {2013.07.04},
  url = {http://dx.doi.org/10.1016/j.neuroimage.2011.08.030}
}

@ARTICLE{Damoiseaux_2006,
  author = {J. S. Damoiseaux and S. A R B Rombouts and F. Barkhof and P. Scheltens
	and C. J. Stam and S. M. Smith and C. F. Beckmann},
  title = {Consistent resting-state networks across healthy subjects.},
  journal = {Proc. Natl. Acad. Sci. U.S.A.},
  year = {2006},
  volume = {103},
  pages = {13848--13853},
  number = {37},
  month = {Sep},
  abstract = {Functional MRI (fMRI) can be applied to study the functional connectivity
	of the human brain. It has been suggested that fluctuations in the
	blood oxygenation level-dependent (BOLD) signal during rest reflect
	the neuronal baseline activity of the brain, representing the state
	of the human brain in the absence of goal-directed neuronal action
	and external input, and that these slow fluctuations correspond to
	functionally relevant resting-state networks. Several studies on
	resting fMRI have been conducted, reporting an apparent similarity
	between the identified patterns. The spatial consistency of these
	resting patterns, however, has not yet been evaluated and quantified.
	In this study, we apply a data analysis approach called tensor probabilistic
	independent component analysis to resting-state fMRI data to find
	coherencies that are consistent across subjects and sessions. We
	characterize and quantify the consistency of these effects by using
	a bootstrapping approach, and we estimate the BOLD amplitude modulation
	as well as the voxel-wise cross-subject variation. The analysis found
	10 patterns with potential functional relevance, consisting of regions
	known to be involved in motor function, visual processing, executive
	functioning, auditory processing, memory, and the so-called default-mode
	network, each with BOLD signal changes up to 3\%. In general, areas
	with a high mean percentage BOLD signal are consistent and show the
	least variation around the mean. These findings show that the baseline
	activity of the brain is consistent across subjects exhibiting significant
	temporal dynamics, with percentage BOLD signal change comparable
	with the signal changes found in task-related experiments.},
  doi = {10.1073/pnas.0601417103},
  institution = {Department of Neurology, VU University Medical Center, De Boelelaan
	1117, 1081 HV Amsterdam, The Netherlands. j.damoiseaux@vumc.nl},
  keywords = {Brain Mapping; Brain, physiology; Health; Humans; Magnetic Resonance
	Imaging; Rest, physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {0601417103},
  pmid = {16945915},
  timestamp = {2012.11.14},
  url = {http://dx.doi.org/10.1073/pnas.0601417103}
}

@ARTICLE{David_2004,
  author = {Olivier David and Diego Cosmelli and Karl J Friston},
  title = {Evaluation of different measures of functional connectivity using
	a neural mass model.},
  journal = {Neuroimage},
  year = {2004},
  volume = {21},
  pages = {659--673},
  number = {2},
  month = {Feb},
  abstract = {We use a neural mass model to address some important issues in characterising
	functional integration among remote cortical areas using magnetoencephalography
	or electroencephalography (MEG or EEG). In a previous paper [NeuroImage
	(in press)], we showed how the coupling among cortical areas can
	modulate the MEG or EEG spectrum and synchronise oscillatory dynamics.
	In this work, we exploit the model further by evaluating different
	measures of statistical dependencies (i.e., functional connectivity)
	among MEG or EEG signals that are mediated by neuronal coupling.
	We have examined linear and nonlinear methods, including phase synchronisation.
	Our results show that each method can detect coupling but with different
	sensitivity profiles that depended on (i) the frequency specificity
	of the interaction (broad vs. narrow band) and (ii) the nature of
	the coupling (linear vs. nonlinear). Our analyses suggest that methods
	based on the concept of generalised synchronisation are the most
	sensitive when interactions encompass different frequencies (broadband
	analyses). In the context of narrow-band analyses, mutual information
	was found to be the most sensitive way to disclose frequency-specific
	couplings. Measures based on generalised synchronisation and phase
	synchronisation are the most sensitive to nonlinear coupling. These
	different sensitivity profiles mean that the choice of coupling measures
	can have dramatic effects on the cortical networks identified. We
	illustrate this using a single-subject MEG study of binocular rivalry
	and highlight the greater recovery of statistical dependencies among
	cortical areas in the beta band when mutual information is used.},
  doi = {10.1016/j.neuroimage.2003.10.006},
  institution = {Functional Imaging Laboratory, Wellcome Department of Imaging Neuroscience,
	London WC1N 3BG, UK. odavid@fil.ion.ucl.ac.uk},
  keywords = {Beta Rhythm; Brain Mapping; Cerebral Cortex, physiology; Cortical
	Synchronization; Dendrites, physiology; Dominance, Cerebral, physiology;
	Electroencephalography; Evoked Potentials, physiology; Fourier Analysis;
	Humans; Linear Models; Magnetoencephalography; Mathematical Computing;
	Models, Neurological; Nerve Net, physiology; Neurons, physiology;
	Nonlinear Dynamics; Pattern Recognition, Visual, physiology; Psychomotor
	Performance, physiology; Signal Processing, Computer-Assisted; Statistics
	as Topic; Synaptic Transmission, physiology; Vision Disparity, physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S1053811903006566},
  pmid = {14980568},
  timestamp = {2013.02.21},
  url = {http://dx.doi.org/10.1016/j.neuroimage.2003.10.006}
}

@ARTICLE{David_2003,
  author = {Olivier David and Karl J Friston},
  title = {A neural mass model for MEG/EEG: coupling and neuronal dynamics.},
  journal = {Neuroimage},
  year = {2003},
  volume = {20},
  pages = {1743--1755},
  number = {3},
  month = {Nov},
  abstract = {Although MEG/EEG signals are highly variable, systematic changes in
	distinct frequency bands are commonly encountered. These frequency-specific
	changes represent robust neural correlates of cognitive or perceptual
	processes (for example, alpha rhythms emerge on closing the eyes).
	However, their functional significance remains a matter of debate.
	Some of the mechanisms that generate these signals are known at the
	cellular level and rest on a balance of excitatory and inhibitory
	interactions within and between populations of neurons. The kinetics
	of the ensuing population dynamics determine the frequency of oscillations.
	In this work we extended the classical nonlinear lumped-parameter
	model of alpha rhythms, initially developed by Lopes da Silva and
	colleagues [Kybernetik 15 (1974) 27], to generate more complex dynamics.
	We show that the whole spectrum of MEG/EEG signals can be reproduced
	within the oscillatory regime of this model by simply changing the
	population kinetics. We used the model to examine the influence of
	coupling strength and propagation delay on the rhythms generated
	by coupled cortical areas. The main findings were that (1) coupling
	induces phase-locked activity, with a phase shift of 0 or pi when
	the coupling is bidirectional, and (2) both coupling and propagation
	delay are critical determinants of the MEG/EEG spectrum. In forthcoming
	articles, we will use this model to (1) estimate how neuronal interactions
	are expressed in MEG/EEG oscillations and establish the construct
	validity of various indices of nonlinear coupling, and (2) generate
	event-related transients to derive physiologically informed basis
	functions for statistical modelling of average evoked responses.},
  institution = {Wellcome Department of Imaging Neuroscience, Functional Imaging Laboratory,
	12 Queen Square, London WC1N 3BG, UK. odavid@fil.ion.ucl.ac.uk},
  keywords = {Algorithms; Computer Simulation; Electroencephalography; Evoked Potentials;
	Humans; Kinetics; Linear Models; Magnetoencephalography; Models,
	Neurological; Neurons, physiology; Nonlinear Dynamics; Pyramidal
	Cells, physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S1053811903004579},
  pmid = {14642484},
  timestamp = {2013.02.21}
}

@ARTICLE{David_2005,
  author = {Olivier David and Lee Harrison and Karl J Friston},
  title = {Modelling event-related responses in the brain.},
  journal = {Neuroimage},
  year = {2005},
  volume = {25},
  pages = {756--770},
  number = {3},
  month = {Apr},
  abstract = {The aim of this work was to investigate the mechanisms that shape
	evoked electroencephalographic (EEG) and magneto-encephalographic
	(MEG) responses. We used a neuronally plausible model to characterise
	the dependency of response components on the models parameters. This
	generative model was a neural mass model of hierarchically arranged
	areas using three kinds of inter-area connections (forward, backward
	and lateral). We investigated how responses, at each level of a cortical
	hierarchy, depended on the strength of connections or coupling. Our
	strategy was to systematically add connections and examine the responses
	of each successive architecture. We did this in the context of deterministic
	responses and then with stochastic spontaneous activity. Our aim
	was to show, in a simple way, how event-related dynamics depend on
	extrinsic connectivity. To emphasise the importance of nonlinear
	interactions, we tried to disambiguate the components of event-related
	potentials (ERPs) or event-related fields (ERFs) that can be explained
	by a linear superposition of trial-specific responses and those engendered
	nonlinearly (e.g., by phase-resetting). Our key conclusions were;
	(i) when forward connections, mediating bottom-up or extrinsic inputs,
	are sufficiently strong, nonlinear mechanisms cause a saturation
	of excitatory interneuron responses. This endows the system with
	an inherent stability that precludes nondissipative population dynamics.
	(ii) The duration of evoked transients increases with the hierarchical
	depth or level of processing. (iii) When backward connections are
	added, evoked transients become more protracted, exhibiting damped
	oscillations. These are formally identical to late or endogenous
	components seen empirically. This suggests that late components are
	mediated by reentrant dynamics within cortical hierarchies. (iv)
	Bilateral connections produce similar effects to backward connections
	but can also mediate zero-lag phase-locking among areas. (v) Finally,
	with spontaneous activity, ERPs/ERFs can arise from two distinct
	mechanisms: For low levels of (stimulus related and ongoing) activity,
	the systems response conforms to a quasi-linear superposition of
	separable responses to the fixed and stochastic inputs. This is consistent
	with classical assumptions that motivate trial averaging to suppress
	spontaneous activity and disclose the ERP/ERF. However, when activity
	is sufficiently high, there are nonlinear interactions between the
	fixed and stochastic inputs. This interaction is expressed as a phase-resetting
	and represents a qualitatively different explanation for the ERP/ERF.},
  doi = {10.1016/j.neuroimage.2004.12.030},
  institution = {Wellcome Department of Imaging Neuroscience, Functional Imaging Laboratory,
	12 Queen Square, London WC1N 3BG, UK. Olivier.David@ujf-grenoble.fr},
  keywords = {Animals; Arousal, physiology; Attention, physiology; Dominance, Cerebral,
	physiology; Electroencephalography, statistics /&/ numerical data;
	Electromyography, instrumentation; Evoked Potentials, physiology;
	Humans; Interneurons, physiology; Magnetic Resonance Imaging, statistics
	/&/ numerical data; Neocortex, physiology; Neural Networks (Computer);
	Neuronal Plasticity; Neurons, physiology; Nonlinear Dynamics; Oscillometry;
	Pyramidal Cells, physiology; Signal Processing, Computer-Assisted;
	Stochastic Processes; Synaptic Transmission, physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S1053-8119(04)00788-8},
  pmid = {15808977},
  timestamp = {2013.02.21},
  url = {http://dx.doi.org/10.1016/j.neuroimage.2004.12.030}
}

@ARTICLE{David_2006a,
  author = {Olivier David and Stefan J Kiebel and Lee M Harrison and Jérémie
	Mattout and James M Kilner and Karl J Friston},
  title = {Dynamic causal modeling of evoked responses in EEG and MEG.},
  journal = {Neuroimage},
  year = {2006},
  volume = {30},
  pages = {1255--1272},
  number = {4},
  month = {May},
  abstract = {Neuronally plausible, generative or forward models are essential for
	understanding how event-related fields (ERFs) and potentials (ERPs)
	are generated. In this paper, we present a new approach to modeling
	event-related responses measured with EEG or MEG. This approach uses
	a biologically informed model to make inferences about the underlying
	neuronal networks generating responses. The approach can be regarded
	as a neurobiologically constrained source reconstruction scheme,
	in which the parameters of the reconstruction have an explicit neuronal
	interpretation. Specifically, these parameters encode, among other
	things, the coupling among sources and how that coupling depends
	upon stimulus attributes or experimental context. The basic idea
	is to supplement conventional electromagnetic forward models, of
	how sources are expressed in measurement space, with a model of how
	source activity is generated by neuronal dynamics. A single inversion
	of this extended forward model enables inference about both the spatial
	deployment of sources and the underlying neuronal architecture generating
	them. Critically, this inference covers long-range connections among
	well-defined neuronal subpopulations. In a previous paper, we simulated
	ERPs using a hierarchical neural-mass model that embodied bottom-up,
	top-down and lateral connections among remote regions. In this paper,
	we describe a Bayesian procedure to estimate the parameters of this
	model using empirical data. We demonstrate this procedure by characterizing
	the role of changes in cortico-cortical coupling, in the genesis
	of ERPs. In the first experiment, ERPs recorded during the perception
	of faces and houses were modeled as distinct cortical sources in
	the ventral visual pathway. Category-selectivity, as indexed by the
	face-selective N170, could be explained by category-specific differences
	in forward connections from sensory to higher areas in the ventral
	stream. We were able to quantify and make inferences about these
	effects using conditional estimates of connectivity. This allowed
	us to identify where, in the processing stream, category-selectivity
	emerged. In the second experiment, we used an auditory oddball paradigm
	to show that the mismatch negativity can be explained by changes
	in connectivity. Specifically, using Bayesian model selection, we
	assessed changes in backward connections, above and beyond changes
	in forward connections. In accord with theoretical predictions, there
	was strong evidence for learning-related changes in both forward
	and backward coupling. These examples show that category- or context-specific
	coupling among cortical regions can be assessed explicitly, within
	a mechanistic, biologically motivated inference framework.},
  doi = {10.1016/j.neuroimage.2005.10.045},
  institution = {Wellcome Department of Imaging Neuroscience, Functional Imaging Laboratory,
	Institute of Neurology, UCL, 12 Queen Square, London WC1N 3BG, UK.},
  keywords = {Auditory Pathways, physiology; Bayes Theorem; Brain Mapping; Cerebral
	Cortex, physiology; Electroencephalography; Evoked Potentials, physiology;
	Humans; Magnetoencephalography; Nerve Net, physiology; Neural Networks
	(Computer); Neurons, physiology; Nonlinear Dynamics; Pattern Recognition,
	Visual, physiology; Pitch Perception, physiology; Synaptic Transmission,
	physiology; Visual Pathways, physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S1053-8119(05)00801-3},
  pmid = {16473023},
  timestamp = {2013.02.21},
  url = {http://dx.doi.org/10.1016/j.neuroimage.2005.10.045}
}

@ARTICLE{David_2006,
  author = {Olivier David and James M Kilner and Karl J Friston},
  title = {Mechanisms of evoked and induced responses in MEG/EEG.},
  journal = {Neuroimage},
  year = {2006},
  volume = {31},
  pages = {1580--1591},
  number = {4},
  month = {Jul},
  abstract = {Cortical responses, recorded by electroencephalography and magnetoencephalography,
	can be characterized in the time domain, to study event-related potentials/fields,
	or in the time-frequency domain, to study oscillatory activity. In
	the literature, there is a common conception that evoked, induced,
	and on-going oscillations reflect different neuronal processes and
	mechanisms. In this work, we consider the relationship between the
	mechanisms generating neuronal transients and how they are expressed
	in terms of evoked and induced power. This relationship is addressed
	using a neuronally realistic model of interacting neuronal subpopulations.
	Neuronal transients were generated by changing neuronal input (a
	dynamic mechanism) or by perturbing the systems coupling parameters
	(a structural mechanism) to produce induced responses. By applying
	conventional time-frequency analyses, we show that, in contradistinction
	to common conceptions, induced and evoked oscillations are perhaps
	more related than previously reported. Specifically, structural mechanisms
	normally associated with induced responses can be expressed in evoked
	power. Conversely, dynamic mechanisms posited for evoked responses
	can induce responses, if there is variation in neuronal input. We
	conclude, it may be better to consider evoked responses as the results
	of mixed dynamic and structural effects. We introduce adjusted power
	to complement induced power. Adjusted power is unaffected by trial-to-trial
	variations in input and can be attributed to structural perturbations
	without ambiguity.},
  doi = {10.1016/j.neuroimage.2006.02.034},
  institution = {Wellcome Department of Imaging Neuroscience, Institute of Neurology,
	12 Queen Square, London WC1N 3BG, UK.},
  keywords = {Algorithms; Data Interpretation, Statistical; Electroencephalography,
	statistics /&/ numerical data; Evoked Potentials, physiology; Fourier
	Analysis; Humans; Magnetoencephalography, statistics /&/ numerical
	data; Models, Neurological; Models, Statistical; Reproducibility
	of Results},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S1053-8119(06)00117-0},
  pmid = {16632378},
  timestamp = {2013.02.21},
  url = {http://dx.doi.org/10.1016/j.neuroimage.2006.02.034}
}

@ARTICLE{Davison_2008,
  author = {Andrew P Davison and Daniel Brüderle and Jochen Eppler and Jens Kremkow
	and Eilif Muller and Dejan Pecevski and Laurent Perrinet and Pierre
	Yger},
  title = {PyNN: A Common Interface for Neuronal Network Simulators.},
  journal = {Front. Neuroinform.},
  year = {2008},
  volume = {2},
  pages = {11},
  abstract = {Computational neuroscience has produced a diversity of software for
	simulations of networks of spiking neurons, with both negative and
	positive consequences. On the one hand, each simulator uses its own
	programming or configuration language, leading to considerable difficulty
	in porting models from one simulator to another. This impedes communication
	between investigators and makes it harder to reproduce and build
	on the work of others. On the other hand, simulation results can
	be cross-checked between different simulators, giving greater confidence
	in their correctness, and each simulator has different optimizations,
	so the most appropriate simulator can be chosen for a given modelling
	task. A common programming interface to multiple simulators would
	reduce or eliminate the problems of simulator diversity while retaining
	the benefits. PyNN is such an interface, making it possible to write
	a simulation script once, using the Python programming language,
	and run it without modification on any supported simulator (currently
	NEURON, NEST, PCSIM, Brian and the Heidelberg VLSI neuromorphic hardware).
	PyNN increases the productivity of neuronal network modelling by
	providing high-level abstraction, by promoting code sharing and reuse,
	and by providing a foundation for simulator-agnostic analysis, visualization
	and data-management tools. PyNN increases the reliability of modelling
	studies by making it much easier to check results on multiple simulators.
	PyNN is open-source software and is available from http://neuralensemble.org/PyNN.},
  doi = {10.3389/neuro.11.011.2008},
  institution = {Unité de Neurosciences Intégratives et Computationelles, CNRS Gif
	sur Yvette, France.},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {19194529},
  timestamp = {2013.02.01},
  url = {http://dx.doi.org/10.3389/neuro.11.011.2008}
}

@ARTICLE{Deco_2012,
  author = {Gustavo Deco and Jirsa, VK},
  title = {Ongoing cortical activity at rest: criticality, multistability, and
	ghost attractors.},
  journal = {J. Neurosci.},
  year = {2012},
  volume = {32},
  pages = {3366--3375},
  number = {10},
  month = {Mar},
  abstract = {The ongoing activity of the brain at rest, i.e., under no stimulation
	and in absence of any task, is astonishingly highly structured into
	spatiotemporal patterns. These spatiotemporal patterns, called resting
	state networks, display low-frequency characteristics (<0.1 Hz) observed
	typically in the BOLD-fMRI signal of human subjects. We aim here
	to understand the origins of resting state activity through modeling
	via a global spiking attractor network of the brain. This approach
	offers a realistic mechanistic model at the level of each single
	brain area based on spiking neurons and realistic AMPA, NMDA, and
	GABA synapses. Integrating the biologically realistic diffusion tensor
	imaging/diffusion spectrum imaging-based neuroanatomical connectivity
	into the brain model, the resultant emerging resting state functional
	connectivity of the brain network fits quantitatively best the experimentally
	observed functional connectivity in humans when the brain network
	operates at the edge of instability. Under these conditions, the
	slow fluctuating (<0.1 Hz) resting state networks emerge as structured
	noise fluctuations around a stable low firing activity equilibrium
	state in the presence of latent "ghost" multistable attractors. The
	multistable attractor landscape defines a functionally meaningful
	dynamic repertoire of the brain network that is inherently present
	in the neuroanatomical connectivity.},
  doi = {10.1523/JNEUROSCI.2523-11.2012},
  institution = {Center for Brain and Cognition, Computational Neuroscience Group,
	Department of Information and Communication Technologies, Universitat
	Pompeu Fabra, Barcelona, 08018, Spain. gustavo.deco@upf.edu},
  keywords = {Action Potentials, physiology/radiation effects; Brain Mapping, methods;
	Cerebral Cortex, physiology; Humans; Magnetic Resonance Imaging,
	methods; Male; Nerve Net, physiology; Rest, physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {32/10/3366},
  pmid = {22399758},
  timestamp = {2013.02.01},
  url = {http://dx.doi.org/10.1523/JNEUROSCI.2523-11.2012}
}

@ARTICLE{Deco_2011,
  author = {Deco, G and Jirsa, VK and McIntosh, AR},
  title = {Emerging concepts for the dynamical organization of resting-state
	activity in the brain},
  journal = {Nat. Rev. Neurosci.},
  year = {2011},
  volume = {12},
  pages = {43-56},
  number = {1},
  month = {dynamics, resting state},
  owner = {paula},
  timestamp = {2012.10.18}
}

@ARTICLE{Deco_2009,
  author = {Gustavo Deco and Jirsa, VK and McIntosh, AR and Olaf Sporns and Rolf
	Kötter},
  title = {Key role of coupling, delay, and noise in resting brain fluctuations.},
  journal = {Proc. Natl. Acad. Sci. U.S.A.},
  year = {2009},
  volume = {106},
  pages = {10302--10307},
  number = {25},
  month = {Jun},
  abstract = {A growing body of neuroimaging research has documented that, in the
	absence of an explicit task, the brain shows temporally coherent
	activity. This so-called "resting state" activity or, more explicitly,
	the default-mode network, has been associated with daydreaming, free
	association, stream of consciousness, or inner rehearsal in humans,
	but similar patterns have also been found under anesthesia and in
	monkeys. Spatiotemporal activity patterns in the default-mode network
	are both complex and consistent, which raises the question whether
	they are the expression of an interesting cognitive architecture
	or the consequence of intrinsic network constraints. In numerical
	simulation, we studied the dynamics of a simplified cortical network
	using 38 noise-driven (Wilson-Cowan) oscillators, which in isolation
	remain just below their oscillatory threshold. Time delay coupling
	based on lengths and strengths of primate corticocortical pathways
	leads to the emergence of 2 sets of 40-Hz oscillators. The sets showed
	synchronization that was anticorrelated at <0.1 Hz across the sets
	in line with a wide range of recent experimental observations. Systematic
	variation of conduction velocity, coupling strength, and noise level
	indicate a high sensitivity of emerging synchrony as well as simulated
	blood flow blood oxygen level-dependent (BOLD) on the underlying
	parameter values. Optimal sensitivity was observed around conduction
	velocities of 1-2 m/s, with very weak coupling between oscillators.
	An additional finding was that the optimal noise level had a characteristic
	scale, indicating the presence of stochastic resonance, which allows
	the network dynamics to respond with high sensitivity to changes
	in diffuse feedback activity.},
  doi = {10.1073/pnas.0901831106},
  institution = {Department of Computational Neuroscience, Institució Catalana de
	Recerca i Estudis Avancats, Universitat Pompeu Fabra, Barcelona,
	Spain. gustavo.deco@upf.edu},
  keywords = {Animals; Brain Mapping; Brain, physiology; Macaca; Noise; Rest},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {0901831106},
  pmid = {19497858},
  timestamp = {2012.11.14},
  url = {http://dx.doi.org/10.1073/pnas.0901831106}
}

@ARTICLE{Deco_2008a,
  author = {Gustavo Deco and VK Jirsa and Peter A Robinson and Michael Breakspear
	and Karl Friston},
  title = {The dynamic brain: from spiking neurons to neural masses and cortical
	fields.},
  journal = {PLoS Comput. Biol.},
  year = {2008},
  volume = {4},
  pages = {e1000092},
  number = {8},
  abstract = {The cortex is a complex system, characterized by its dynamics and
	architecture, which underlie many functions such as action, perception,
	learning, language, and cognition. Its structural architecture has
	been studied for more than a hundred years; however, its dynamics
	have been addressed much less thoroughly. In this paper, we review
	and integrate, in a unifying framework, a variety of computational
	approaches that have been used to characterize the dynamics of the
	cortex, as evidenced at different levels of measurement. Computational
	models at different space-time scales help us understand the fundamental
	mechanisms that underpin neural processes and relate these processes
	to neuroscience data. Modeling at the single neuron level is necessary
	because this is the level at which information is exchanged between
	the computing elements of the brain; the neurons. Mesoscopic models
	tell us how neural elements interact to yield emergent behavior at
	the level of microcolumns and cortical columns. Macroscopic models
	can inform us about whole brain dynamics and interactions between
	large-scale neural systems such as cortical regions, the thalamus,
	and brain stem. Each level of description relates uniquely to neuroscience
	data, from single-unit recordings, through local field potentials
	to functional magnetic resonance imaging (fMRI), electroencephalogram
	(EEG), and magnetoencephalogram (MEG). Models of the cortex can establish
	which types of large-scale neuronal networks can perform computations
	and characterize their emergent properties. Mean-field and related
	formulations of dynamics also play an essential and complementary
	role as forward models that can be inverted given empirical data.
	This makes dynamic models critical in integrating theory and experiments.
	We argue that elaborating principled and informed models is a prerequisite
	for grounding empirical neuroscience in a cogent theoretical framework,
	commensurate with the achievements in the physical sciences.},
  doi = {10.1371/journal.pcbi.1000092},
  institution = {Institució Catalana de Recerca i Estudis Avançats (ICREA), Universitat
	Pompeu Fabra, Department of Technology, Computational Neuroscience,
	Barcelona, Spain. Gustavo.Deco@upf.edu},
  keywords = {Animals; Biomedical Research, methods/standards; Cerebral Cortex,
	physiology; Computational Biology; Electrophysiology; Empirical Research;
	Humans; Models, Neurological; Nerve Net, chemistry/physiology; Neurons,
	physiology; Nonlinear Dynamics; Terminology as Topic; Thermodynamics},
  language = {eng},
  medline-pst = {epublish},
  owner = {paula},
  pmid = {18769680},
  timestamp = {2013.02.01},
  url = {http://dx.doi.org/10.1371/journal.pcbi.1000092}
}

@ARTICLE{Deco_2005,
  author = {Gustavo Deco and Anders Ledberg and Rita Almeida and Joaquín Fuster},
  title = {Neural dynamics of cross-modal and cross-temporal associations.},
  journal = {Exp. Brain Res.},
  year = {2005},
  volume = {166},
  pages = {325--336},
  number = {3-4},
  month = {Oct},
  abstract = {We have studied a neurodynamic model of cross-modal and cross-temporal
	associations. We show that a network of integrate-and-fire neurons
	can generate spiking activity with realistic dynamics during the
	delay period of a paired associates task. In particular, the activity
	of the model resembles reported data from single-cell recordings
	in the prefrontal cortex.},
  doi = {10.1007/s00221-005-2374-y},
  institution = {Institució Catalana de Recerca i Estudis Avançats (ICREA), Universitat
	Pompeu Fabra Computational Neuroscience, Passeig de Circumval.lació,
	8, 08003, Barcelona, Spain. Gustavo.Deco@upf.edu},
  keywords = {Acoustic Stimulation; Algorithms; Animals; Computer Simulation; Cues;
	Electrophysiology; Macaca mulatta; Models, Neurological; Nerve Net,
	physiology; Neurons, physiology; Photic Stimulation; Prefrontal Cortex,
	cytology/physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {16160822},
  timestamp = {2013.02.01},
  url = {http://dx.doi.org/10.1007/s00221-005-2374-y}
}

@ARTICLE{Deco_2013,
  author = {Gustavo Deco and Adrián Ponce-Alvarez and Dante Mantini and Gian
	Luca Romani and Patric Hagmann and Maurizio Corbetta},
  title = {Resting-state functional connectivity emerges from structurally and
	dynamically shaped slow linear fluctuations.},
  journal = {J Neurosci},
  year = {2013},
  volume = {33},
  pages = {11239--11252},
  number = {27},
  month = {Jul},
  abstract = {Brain fluctuations at rest are not random but are structured in spatial
	patterns of correlated activity across different brain areas. The
	question of how resting-state functional connectivity (FC) emerges
	from the brain's anatomical connections has motivated several experimental
	and computational studies to understand structure-function relationships.
	However, the mechanistic origin of resting state is obscured by large-scale
	models' complexity, and a close structure-function relation is still
	an open problem. Thus, a realistic but simple enough description
	of relevant brain dynamics is needed. Here, we derived a dynamic
	mean field model that consistently summarizes the realistic dynamics
	of a detailed spiking and conductance-based synaptic large-scale
	network, in which connectivity is constrained by diffusion imaging
	data from human subjects. The dynamic mean field approximates the
	ensemble dynamics, whose temporal evolution is dominated by the longest
	time scale of the system. With this reduction, we demonstrated that
	FC emerges as structured linear fluctuations around a stable low
	firing activity state close to destabilization. Moreover, the model
	can be further and crucially simplified into a set of motion equations
	for statistical moments, providing a direct analytical link between
	anatomical structure, neural network dynamics, and FC. Our study
	suggests that FC arises from noise propagation and dynamical slowing
	down of fluctuations in an anatomically constrained dynamical system.
	Altogether, the reduction from spiking models to statistical moments
	presented here provides a new framework to explicitly understand
	the building up of FC through neuronal dynamics underpinned by anatomical
	connections and to drive hypotheses in task-evoked studies and for
	clinical applications.},
  doi = {10.1523/JNEUROSCI.1091-13.2013},
  institution = {Center for Brain and Cognition, Computational Neuroscience Group,
	Department of Information and Communication Technologies, Universitat
	Pompeu Fabra, 08018 Barcelona, Spain.},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {33/27/11239},
  pmid = {23825427},
  timestamp = {2013.08.29},
  url = {http://dx.doi.org/10.1523/JNEUROSCI.1091-13.2013}
}

@ARTICLE{Deco_Senden_2012,
  author = {Gustavo Deco and Mario Senden and VK Jirsa},
  title = {How anatomy shapes dynamics: a semi-analytical study of the brain
	at rest by a simple spin model.},
  journal = {Front. Comput. Neurosci.},
  year = {2012},
  volume = {6},
  pages = {68},
  abstract = {Resting state networks (RSNs) show a surprisingly coherent and robust
	spatiotemporal organization. Previous theoretical studies demonstrated
	that these patterns can be understood as emergent on the basis of
	the underlying neuroanatomical connectivity skeleton. Integrating
	the biologically realistic DTI/DSI-(Diffusion Tensor Imaging/Diffusion
	Spectrum Imaging)based neuroanatomical connectivity into a brain
	model of Ising spin dynamics, we found a system with multiple attractors,
	which can be studied analytically. The multistable attractor landscape
	thus defines a functionally meaningful dynamic repertoire of the
	brain network that is inherently present in the neuroanatomical connectivity.
	We demonstrate that the more entropy of attractors exists, the richer
	is the dynamical repertoire and consequently the brain network displays
	more capabilities of computation. We hypothesize therefore that human
	brain connectivity developed a scale free type of architecture in
	order to be able to store a large number of different and flexibly
	accessible brain functions.},
  doi = {10.3389/fncom.2012.00068},
  institution = {Computational Neuroscience Group, Department of Information and Communication
	Technologies, Center for Brain and Cognition, Universitat Pompeu
	Fabra Barcelona, Spain ; Institució Catalana de la Recerca i Estudis
	Avançats, Universitat Pompeu Fabra Barcelona, Spain.},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {23024632},
  timestamp = {2012.11.14},
  url = {http://dx.doi.org/10.3389/fncom.2012.00068}
}

@ARTICLE{Dehghani_2012,
  author = {Nima Dehghani and Nicholas G Hatsopoulos and Zach D Haga and Rebecca
	A Parker and Bradley Greger and Eric Halgren and Sydney S Cash and
	Alain Destexhe},
  title = {Avalanche Analysis from Multielectrode Ensemble Recordings in Cat,
	Monkey, and Human Cerebral Cortex during Wakefulness and Sleep.},
  journal = {Front. Physiol.},
  year = {2012},
  volume = {3},
  pages = {302},
  abstract = {Self-organized critical states are found in many natural systems,
	from earthquakes to forest fires, they have also been observed in
	neural systems, particularly, in neuronal cultures. However, the
	presence of critical states in the awake brain remains controversial.
	Here, we compared avalanche analyses performed on different in vivo
	preparations during wakefulness, slow-wave sleep, and REM sleep,
	using high density electrode arrays in cat motor cortex (96 electrodes),
	monkey motor cortex and premotor cortex and human temporal cortex
	(96 electrodes) in epileptic patients. In neuronal avalanches defined
	from units (up to 160 single units), the size of avalanches never
	clearly scaled as power-law, but rather scaled exponentially or displayed
	intermediate scaling. We also analyzed the dynamics of local field
	potentials (LFPs) and in particular LFP negative peaks (nLFPs) among
	the different electrodes (up to 96 sites in temporal cortex or up
	to 128 sites in adjacent motor and premotor cortices). In this case,
	the avalanches defined from nLFPs displayed power-law scaling in
	double logarithmic representations, as reported previously in monkey.
	However, avalanche defined as positive LFP (pLFP) peaks, which are
	less directly related to neuronal firing, also displayed apparent
	power-law scaling. Closer examination of this scaling using the more
	reliable cumulative distribution function (CDF) and other rigorous
	statistical measures, did not confirm power-law scaling. The same
	pattern was seen for cats, monkey, and human, as well as for different
	brain states of wakefulness and sleep. We also tested other alternative
	distributions. Multiple exponential fitting yielded optimal fits
	of the avalanche dynamics with bi-exponential distributions. Collectively,
	these results show no clear evidence for power-law scaling or self-organized
	critical states in the awake and sleeping brain of mammals, from
	cat to man.},
  doi = {10.3389/fphys.2012.00302},
  institution = {Laboratory of Computational Neuroscience, Unité de Neurosciences,
	Information et Complexité, CNRS Gif-sur-Yvette, France.},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {22934053},
  timestamp = {2013.03.05},
  url = {http://dx.doi.org/10.3389/fphys.2012.00302}
}

@ARTICLE{Munck_1992,
  author = {De Munck, JC},
  title = {{A linear discretization of the volume conductor boundary integral
	equation using analytically integrated elements (electrophysiology
	application)}},
  journal = {IEEE Trans. Biomed. Eng.},
  year = {1992},
  volume = {39},
  pages = {986--990},
  number = {9},
  doi = {10.1109/10.256433},
  issn = {0018-9294}
}

@ARTICLE{Deneux2010,
  author = {Deneux, Thomas and Faugeras, Olivier},
  title = {EEG-fMRI fusion of paradigm-free activity using Kalman filtering.},
  journal = {Neural Comput.},
  year = {2010},
  volume = {22},
  pages = {906--948},
  number = {4},
  month = {Apr},
  abstract = {We address here the use of EEG and fMRI, and their combination, in
	order to estimate the full spatiotemporal patterns of activity on
	the cortical surface in the absence of any particular assumptions
	on this activity such as stimulation times. For handling such a high-dimension
	inverse problem, we propose the use of (1) a global forward model
	of how these measures are functions of the "neural activity" of a
	large number of sources distributed on the cortical surface, formalized
	as a dynamical system, and (2) adaptive filters, as a natural solution
	to solve this inverse problem iteratively along the temporal dimension.
	This estimation framework relies on realistic physiological models,
	uses EEG and fMRI in a symmetric manner, and takes into account both
	their temporal and spatial information. We use the Kalman filter
	and smoother to perform such an estimation on realistic artificial
	data and demonstrate that the algorithm can handle the high dimensionality
	of these data and that it succeeds in solving this inverse problem,
	combining efficiently the information provided by the two modalities
	(this information being naturally predominantly temporal for EEG
	and spatial for fMRI). It performs particularly well in reconstructing
	a random temporally and spatially smooth activity spread over the
	cortex. The Kalman filter and smoother show some limitations, however,
	which call for the development of more specific adaptive filters.
	First, they do not cope well with the strong nonlinearity in the
	model that is necessary for an adequate description of the relation
	between cortical electric activities and the metabolic demand responsible
	for fMRI signals. Second, they fail to estimate a sparse activity
	(i.e., presenting sharp peaks at specific locations and times). Finally
	their computational cost remains high. We use schematic examples
	to explain these limitations and propose further developments of
	our method to overcome them.},
  doi = {10.1162/neco.2009.05-08-793},
  institution = {Ecole Normale Supérieure, Département d'Informatique, Paris, France.
	thomas.deneux@weizmann.ac.il},
  keywords = {Algorithms; Animals; Brain Mapping; Cerebral Cortex, blood supply/physiology;
	Electroencephalography, methods; Humans; Image Processing, Computer-Assisted,
	methods; Magnetic Resonance Imaging, methods; Models, Neurological;
	Nonlinear Dynamics; Oxygen, blood; Signal Processing, Computer-Assisted;
	Wakefulness},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paupau},
  pmid = {20028225},
  timestamp = {2013.04.09},
  url = {http://dx.doi.org/10.1162/neco.2009.05-08-793}
}

@ARTICLE{Deneux_2006,
  author = {Deneux, Thomas and Faugeras, Olivier},
  title = {Using nonlinear models in fMRI data analysis: model selection and
	activation detection.},
  journal = {Neuroimage},
  year = {2006},
  volume = {32},
  pages = {1669--1689},
  number = {4},
  month = {Oct},
  abstract = {There is an increasing interest in using physiologically plausible
	models in fMRI analysis. These models do raise new mathematical problems
	in terms of parameter estimation and interpretation of the measured
	data. In this paper, we show how to use physiological models to map
	and analyze brain activity from fMRI data. We describe a maximum
	likelihood parameter estimation algorithm and a statistical test
	that allow the following two actions: selecting the most statistically
	significant hemodynamic model for the measured data and deriving
	activation maps based on such model. Furthermore, as parameter estimation
	may leave much incertitude on the exact values of parameters, model
	identifiability characterization is a particular focus of our work.
	We applied these methods to different variations of the Balloon Model
	(Buxton, R.B., Wang, E.C., and Frank, L.R. 1998. Dynamics of blood
	flow and oxygenation changes during brain activation: the balloon
	model. Magn. Reson. Med. 39: 855-864; Buxton, R.B., Uludağ, K., Dubowitz,
	D.J., and Liu, T.T. 2004. Modelling the hemodynamic response to brain
	activation. NeuroImage 23: 220-233; Friston, K. J., Mechelli, A.,
	Turner, R., and Price, C. J. 2000. Nonlinear responses in fMRI: the
	balloon model, volterra kernels, and other hemodynamics. NeuroImage
	12: 466-477) in a visual perception checkerboard experiment. Our
	model selection proved that hemodynamic models better explain the
	BOLD response than linear convolution, in particular because they
	are able to capture some features like poststimulus undershoot or
	nonlinear effects. On the other hand, nonlinear and linear models
	are comparable when signals get noisier, which explains that activation
	maps obtained in both frameworks are comparable. The tools we have
	developed prove that statistical inference methods used in the framework
	of the General Linear Model might be generalized to nonlinear models.},
  doi = {10.1016/j.neuroimage.2006.03.006},
  institution = {ENS/INRIA Odyssée Team, Ecole Normale Supérieure, 45 rue d'Ulm, 75
	005 Paris, France. deneux@di.ens.fr},
  keywords = {Adult; Algorithms; Bayes Theorem; Cerebrovascular Circulation, physiology;
	Female; Humans; Image Processing, Computer-Assisted; Likelihood Functions;
	Linear Models; Magnetic Resonance Imaging, statistics /&/ numerical
	data; Male; Models, Statistical; Nonlinear Dynamics; Oxygen, blood;
	Reproducibility of Results},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paupau},
  pii = {S1053-8119(06)00170-4},
  pmid = {16844388},
  timestamp = {2013.02.24},
  url = {http://dx.doi.org/10.1016/j.neuroimage.2006.03.006}
}

@ARTICLE{Diesmann_2002,
  author = {Diesmann, M. and Gewaltig, M},
  title = {NEST: an environment for neural systems simulations},
  journal = {In Forschung und wisschenschaftliches Rechnen},
  year = {2002},
  volume = {58},
  pages = {43-70},
  owner = {paula},
  timestamp = {2013.02.06}
}

@ARTICLE{Donoho_2010,
  author = {David L Donoho},
  title = {An invitation to reproducible computational research.},
  journal = {Biostatistics},
  year = {2010},
  volume = {11},
  pages = {385--388},
  number = {3},
  month = {Jul},
  doi = {10.1093/biostatistics/kxq028},
  institution = {Department of Statistics, Stanford University, Stanford, CA 94305,
	USA. donoho@stanford.edu},
  keywords = {Computational Biology, methods/standards; Reproducibility of Results;
	Statistics as Topic, methods/standards},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {kxq028},
  pmid = {20538873},
  timestamp = {2013.02.21},
  url = {http://dx.doi.org/10.1093/biostatistics/kxq028}
}

@ARTICLE{Donoho_2005,
  author = {David L Donoho and Jared Tanner},
  title = {Sparse nonnegative solution of underdetermined linear equations by
	linear programming.},
  journal = {Proc. Natl. Acad. Sci. U.S.A.},
  year = {2005},
  volume = {102},
  pages = {9446--9451},
  number = {27},
  month = {Jul},
  abstract = {Consider an underdetermined system of linear equations y = Ax with
	known y and d x n matrix A. We seek the nonnegative x with the fewest
	nonzeros satisfying y = Ax. In general, this problem is NP-hard.
	However, for many matrices A there is a threshold phenomenon: if
	the sparsest solution is sufficiently sparse, it can be found by
	linear programming. We explain this by the theory of convex polytopes.
	Let a(j) denote the jth column of A, 1 < or = j < or = n, let a0
	= 0 and P denote the convex hull of the a(j). We say the polytope
	P is outwardly k-neighborly if every subset of k vertices not including
	0 spans a face of P. We show that outward k-neighborliness is equivalent
	to the statement that, whenever y = Ax has a nonnegative solution
	with at most k nonzeros, it is the nonnegative solution to y = Ax
	having minimal sum. We also consider weak neighborliness, where the
	overwhelming majority of k-sets of a(j)s not containing 0 span a
	face of P. This implies that most nonnegative vectors x with k nonzeros
	are uniquely recoverable from y = Ax by linear programming. Numerous
	corollaries follow by invoking neighborliness results. For example,
	for most large n by 2n underdetermined systems having a solution
	with fewer nonzeros than roughly half the number of equations, the
	sparsest solution can be found by linear programming.},
  doi = {10.1073/pnas.0502269102},
  institution = {Department of Statistics, Stanford University, Stanford, CA 94305-4065,
	USA. donoho@stat.stanford.edu},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {0502269102},
  pmid = {15976026},
  timestamp = {2013.02.21},
  url = {http://dx.doi.org/10.1073/pnas.0502269102}
}

@ARTICLE{Drysdale_2010,
  author = {P. M. Drysdale and J. P. Huber and P. A. Robinson and K. M. Aquino},
  title = {Spatiotemporal BOLD dynamics from a poroelastic hemodynamic model.},
  journal = {J Theor Biol},
  year = {2010},
  volume = {265},
  pages = {524–534},
  month = {May},
  abstract = {A quantitative theory is developed for the relationship between stimulus
	and the resulting blood oxygen level dependent (BOLD) functional
	magnetic resonance imaging (fMRI) signal, including both spatial
	and temporal dynamics for the first time. The brain tissue is modeled
	as a porous elastic medium, whose interconnected pores represent
	the vasculature. The model explicitly incorporates conservation of
	blood mass, interconversion of oxygenated and deoxygenated hemoglobin,
	force balance within the blood and of blood pressure with vessel
	walls, and blood flow modulation due to neuronal activity. In appropriate
	limits it is shown to reproduce prior Balloon models of hemodynamic
	response, which do not include spatial variations. The regime of
	validity of such models is thereby clarified by elucidating their
	assumptions, and when these break down, for example when voxel sizes
	become small.},
  doi = {10.1016/j.jtbi.2010.05.026},
  institution = {School of Physics, University of Sydney, NSW 2006, Australia; Brain
	Dynamics Center, Westmead Millenium Institute, Sydney Medical School
	- Western, University of Sydney, NSW 2145, Australia.},
  language = {eng},
  medline-pst = {aheadofprint},
  owner = {paula},
  pii = {S0022-5193(10)00269-9},
  pmid = {20685213},
  timestamp = {2013.08.19},
  url = {http://dx.doi.org/10.1016/j.jtbi.2010.05.026}
}

@ARTICLE{Dumas_2012,
  author = {Guillaume Dumas and Mario Chavez and Jacqueline Nadel and Jacques
	Martinerie},
  title = {Anatomical connectivity influences both intra- and inter-brain synchronizations.},
  journal = {PLoS One},
  year = {2012},
  volume = {7},
  pages = {e36414},
  number = {5},
  abstract = {Recent development in diffusion spectrum brain imaging combined to
	functional simulation has the potential to further our understanding
	of how structure and dynamics are intertwined in the human brain.
	At the intra-individual scale, neurocomputational models have already
	started to uncover how the human connectome constrains the coordination
	of brain activity across distributed brain regions. In parallel,
	at the inter-individual scale, nascent social neuroscience provides
	a new dynamical vista of the coupling between two embodied cognitive
	agents. Using EEG hyperscanning to record simultaneously the brain
	activities of subjects during their ongoing interaction, we have
	previously demonstrated that behavioral synchrony correlates with
	the emergence of inter-brain synchronization. However, the functional
	meaning of such synchronization remains to be specified. Here, we
	use a biophysical model to quantify to what extent inter-brain synchronizations
	are related to the anatomical and functional similarity of the two
	brains in interaction. Pairs of interacting brains were numerically
	simulated and compared to real data. Results show a potential dynamical
	property of the human connectome to facilitate inter-individual synchronizations
	and thus may partly account for our propensity to generate dynamical
	couplings with others.},
  doi = {10.1371/journal.pone.0036414},
  institution = {Université Pierre et Marie Curie-Paris 6, Centre de Recherche de
	l'Institut du Cerveau et de la Moelle Épinière, UMR-S975, Paris,
	France. guillaume.dumas@centraliens.net},
  keywords = {Brain, physiology; Diffusion Magnetic Resonance Imaging; Electroencephalography;
	Female; Humans; Male; Models, Neurological},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {PONE-D-12-01160},
  pmid = {22590539},
  timestamp = {2013.02.18},
  url = {http://dx.doi.org/10.1371/journal.pone.0036414}
}

@ARTICLE{Ekstrom_2009,
  author = {Arne D Ekstrom and Adam J Bazih and Nanthia A Suthana and Ramsey
	Al-Hakim and Kenji Ogura and Michael Zeineh and Alison C Burggren
	and Susan Y Bookheimer},
  title = {Advances in high-resolution imaging and computational unfolding of
	the human hippocampus.},
  journal = {Neuroimage},
  year = {2009},
  volume = {47},
  pages = {42--49},
  number = {1},
  month = {Aug},
  abstract = {The hippocampus is often a difficult structure to visualize with magnetic
	resonance imaging (MRI) and functional MRI (fMRI) due to its convoluted
	nature and susceptibility to signal dropout. Improving our ability
	to pinpoint changes in neural activity using fMRI in this structure
	remains an important challenge. Current fMRI/MRI methods typically
	do not permit visualization of the hippocampus and surrounding cortex
	at a resolution less than 1 mm. We present here improvements to our
	previous methods for obtaining structural MR images of the hippocampus,
	which provided an in-plane resolution of 0.4 mm(2) mm and two-dimensional
	"flat" maps of the hippocampus with an interpolated isotropic resolution
	of 0.4 mm(3) (Engel, S.A., Glover, G.H., and Wandell, B.A., (1997).
	Retinotopic organization in human visual cortex and the spatial precision
	of functional MRI. Cereb. Cortex 7, 181-192.; Zeineh, M.M., Engel,
	S.A., and Bookheimer, S.Y., (2000). Application of cortical unfolding
	techniques to functional MRI of the human hippocampal region. NeuroImage
	11, 668-683.). We present changes to existing structural imaging
	sequences that now augment the resolution of previous scans, permitting
	visualization of the anterior portion of CA1, parts of the dentate
	gyrus, and CA23. These imaging improvements are of relevance generally
	to the field of imaging because they permit higher overall resolution
	imaging of the hippocampus than previously possible (at 3 T). We
	also introduce a novel application of a computational interpolation
	method that improves our ability to capture the convoluted three-dimensional
	shape of the hippocampus. Furthermore, we have developed a quantitative
	method for obtaining group activation patterns based on producing
	averaged flat maps using vector field warping techniques, allowing
	localization of activations to specific hippocampal subregions across
	groups of subjects. Together, these methods provide a means to improve
	imaging of neural activity in the human hippocampus and surrounding
	cortex during cognitive tasks.},
  doi = {10.1016/j.neuroimage.2009.03.017},
  institution = {Center for Cognitive Neuroscience, Semel Institute, Department of
	Psychiatry and Biobehavioral Sciences, University of California,
	Los Angeles, CA 90095-7039, USA.},
  keywords = {Adult; Cerebral Cortex, anatomy /&/ histology; Female; Hippocampus,
	anatomy /&/ histology/physiology; Humans; Image Processing, Computer-Assisted,
	methods; Imaging, Three-Dimensional, methods; Magnetic Resonance
	Imaging, methods; Male; Middle Aged; Young Adult},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S1053-8119(09)00239-0},
  pmid = {19303448},
  timestamp = {2013.08.19},
  url = {http://dx.doi.org/10.1016/j.neuroimage.2009.03.017}
}

@ARTICLE{Eliasmith_2012,
  author = {Chris Eliasmith and Terrence C Stewart and Xuan Choo and Trevor Bekolay
	and Travis DeWolf and Yichuan Tang and Charlie Tang and Daniel Rasmussen},
  title = {A large-scale model of the functioning brain.},
  journal = {Science},
  year = {2012},
  volume = {338},
  pages = {1202--1205},
  number = {6111},
  month = {Nov},
  abstract = {A central challenge for cognitive and systems neuroscience is to relate
	the incredibly complex behavior of animals to the equally complex
	activity of their brains. Recently described, large-scale neural
	models have not bridged this gap between neural activity and biological
	function. In this work, we present a 2.5-million-neuron model of
	the brain (called "Spaun") that bridges this gap by exhibiting many
	different behaviors. The model is presented only with visual image
	sequences, and it draws all of its responses with a physically modeled
	arm. Although simplified, the model captures many aspects of neuroanatomy,
	neurophysiology, and psychological behavior, which we demonstrate
	via eight diverse tasks.},
  doi = {10.1126/science.1225266},
  institution = {Centre for Theoretical Neuroscience, University of Waterloo, Waterloo,
	ON N2J 3G1, Canada. celiasmith@uwaterloo.ca},
  keywords = {Behavior; Brain, anatomy /&/ histology/physiology; Humans; Models,
	Neurological; Neural Networks (Computer); Software},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {338/6111/1202},
  pmid = {23197532},
  timestamp = {2012.12.27},
  url = {http://dx.doi.org/10.1126/science.1225266}
}

@ARTICLE{Ellenrieder_2012,
  author = {Nicolás von Ellenrieder and Leandro Beltrachini and Carlos H Muravchik},
  title = {Electrode and brain modeling in stereo-EEG.},
  journal = {Clin. Neurophysiol.},
  year = {2012},
  volume = {123},
  pages = {1745--1754},
  number = {9},
  month = {Sep},
  abstract = {To quantify the perturbation due to the presence of a measuring depth
	electrode on the intracranial electric potential distribution, and
	to study the effect of the heterogeneity and anisotropy of the brain
	tissues' electric conductivity.The governing differential equations
	are solved with the Boundary Elements Method to compute the perturbation
	on the electric potential distribution caused by the presence of
	the measuring electrode, and with the Finite Elements Method to simulate
	measurements in an heterogeneous anisotropic brain model.The perturbation
	on the measured electric potential is negligible if the source of
	electric activity is located more than approximately 1mm away from
	the electrode. The error induced by this perturbation in the estimation
	of the source position is below 1mm in all tested situations. The
	results hold for different sizes of the electrode's contacts. The
	effect of the brain's heterogeneity and anisotropy is more important.
	In a particular example simulated dipolar sources in the gray matter
	show localization differences of up to 5mm between homogeneous isotropic
	and heterogeneous anisotropic brain models.It is not necessary to
	include detailed electrode models in order to solve the stereo-EEG
	(sEEG) forward and inverse problems. The heterogeneity and anisotropy
	of the brain electric conductivity should be modeled if possible.
	The effect of using an homogeneous isotropic brain model approximation
	should be studied in a case by case basis, since it depends on the
	electrode positions, the subject's electric conductivity map, and
	the source configuration.This simulation study is helpful for interpreting
	the sEEG measurements, and for choosing appropriate electrode and
	brain models; a necessary first step in any attempt to solve the
	sEEG inverse problem.},
  doi = {10.1016/j.clinph.2012.01.019},
  institution = {Facultad de Ingeniería, Universidad Nacional de La Plata (UNLP),
	Argentina. nellen@ieee.org},
  keywords = {Brain, physiology; Computer Simulation; Electric Conductivity; Electrodes;
	Electroencephalography; Finite Element Analysis; Humans; Models,
	Biological},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S1388-2457(12)00067-3},
  pmid = {22364724},
  timestamp = {2013.04.17},
  url = {http://dx.doi.org/10.1016/j.clinph.2012.01.019}
}

@ARTICLE{Ellenrieder_2005,
  author = {von Ellenrieder, N. and Muravchik, C.H. and Nehorai, A.},
  title = {{MEG forward problem formulation using equivalent surface current
	densities}},
  journal = {IEEE Trans. Biomed. Eng.},
  year = {2005},
  volume = {52},
  pages = {1210--1217},
  number = {7},
  issn = {0018-9294},
  publisher = {IEEE}
}

@ARTICLE{Ellenrieder_2009,
  author = {von Ellenrieder, N. and Vald{\'e}s-Hern{\'a}ndez, P.A. and Muravchik,
	C.H.},
  title = {{On the EEG/MEG forward problem solution for distributed cortical
	sources}},
  journal = {Med. Biol. Eng. Comput.},
  year = {2009},
  volume = {47},
  pages = {1083--1091},
  number = {10},
  issn = {0140-0118},
  publisher = {Springer}
}

@ARTICLE{Engel_1997,
  author = {S. A. Engel and G. H. Glover and B. A. Wandell},
  title = {Retinotopic organization in human visual cortex and the spatial precision
	of functional MRI.},
  journal = {Cerebral Cortex},
  year = {1997},
  volume = {7},
  pages = {181-192},
  number = {2},
  owner = {paula},
  timestamp = {2013.08.19}
}

@ARTICLE{Engel_1994,
  author = {S. A. Engel and D. E. Rumelhart and B. A. Wandell and A. T. Lee and
	G. H. Glover and E. J. Chichilnisky and M. N. Shadlen},
  title = {fMRI of human visual cortex.},
  journal = {Nature},
  year = {1994},
  volume = {369},
  pages = {525},
  number = {6481},
  month = {Jun},
  doi = {10.1038/369525a0},
  keywords = {Animals; Brain Mapping; Humans; Magnetic Resonance Imaging, methods;
	Photic Stimulation; Primates; Visual Cortex, physiology; Visual Fields,
	physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {8031403},
  timestamp = {2013.08.19},
  url = {http://dx.doi.org/10.1038/369525a0}
}

@MISC{EnthoughtTraits,
  author = {Enthought, Inc.},
  title = {The Traits Framework for Validation and Event-Driven Programming
	in Python},
  howpublished = {http://code.enthought.com/projects/traits/},
  year = {2001},
  url = {http://code.enthought.com/projects/traits/}
}

@ARTICLE{Eppler_2008,
  author = {Jochen Martin Eppler and Moritz Helias and Eilif Muller and Markus
	Diesmann and Marc-Oliver Gewaltig},
  title = {PyNEST: A Convenient Interface to the NEST Simulator.},
  journal = {Front. Neuroinform.},
  year = {2008},
  volume = {2},
  pages = {12},
  abstract = {The neural simulation tool NEST (http://www.nest-initiative.org) is
	a simulator for heterogeneous networks of point neurons or neurons
	with a small number of compartments. It aims at simulations of large
	neural systems with more than 10(4) neurons and 10(7) to 10(9) synapses.
	NEST is implemented in C++ and can be used on a large range of architectures
	from single-core laptops over multi-core desktop computers to super-computers
	with thousands of processor cores. Python (http://www.python.org)
	is a modern programming language that has recently received considerable
	attention in Computational Neuroscience. Python is easy to learn
	and has many extension modules for scientific computing (e.g. http://www.scipy.org).
	In this contribution we describe PyNEST, the new user interface to
	NEST. PyNEST combines NEST's efficient simulation kernel with the
	simplicity and flexibility of Python. Compared to NEST's native simulation
	language SLI, PyNEST makes it easier to set up simulations, generate
	stimuli, and analyze simulation results. We describe how PyNEST connects
	NEST and Python and how it is implemented. With a number of examples,
	we illustrate how it is used.},
  doi = {10.3389/neuro.11.012.2008},
  institution = {Honda Research Institute Europe GmbH, Offenbach Germany.},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {19198667},
  timestamp = {2012.12.27},
  url = {http://dx.doi.org/10.3389/neuro.11.012.2008}
}

@ARTICLE{Ermentrout_2006,
  author = {Bard Ermentrout},
  title = {Gap junctions destroy persistent states in excitatory networks.},
  journal = {Phys Rev E Stat Nonlin Soft Matter Phys},
  year = {2006},
  volume = {74},
  pages = {031918},
  number = {3 Pt 1},
  month = {Sep},
  abstract = {Gap junctions between excitatory neurons are shown to disrupt the
	persistent state. The asynchronous state of the network loses stability
	via a Hopf bifurcation and then the active state is destroyed via
	a homoclinic bifurcation with a stationary state. A partial differential
	equation (PDE) is developed to analyze the Hopf and the homoclinic
	bifurcations. The simplified dynamics are compared to a biophysical
	model where similar behavior is observed. In the low noise case,
	the dynamics of the PDE is shown to be very complicated and includes
	possible chaotic behavior. The onset of synchrony is studied by the
	application of averaging to obtain a simple criterion for destabilization
	of the asynchronous persistent state.},
  institution = {Department of Mathematics, University of Pittsburgh, Pittsburgh,
	Pennsylvania 15260, USA.},
  keywords = {Excitatory Postsynaptic Potentials, physiology; Gap Junctions, physiology;
	Models, Neurological; Nerve Net; Neurons, physiology; Synapses, physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {17025678},
  timestamp = {2013.09.04}
}

@BOOK{XPPAUT,
  title = {Simulating, analyzing, and animating dynamical systems: a guide to
	XPPAUT for researchers and students},
  publisher = {Siam},
  year = {2002},
  author = {Ermentrout, Bard},
  volume = {14}
}

@ARTICLE{Ermentrout_2009,
  author = {Bard Ermentrout and Tae-Wook Ko},
  title = {Delays and weakly coupled neuronal oscillators.},
  journal = {Philos Trans A Math Phys Eng Sci},
  year = {2009},
  volume = {367},
  pages = {1097--1115},
  number = {1891},
  month = {Mar},
  abstract = {We use weakly coupled oscillator theory to study the effects of delays
	on coupled systems of neuronal oscillators. We explore, first, simple
	pairs with constant delays and then examine the role of distributed
	delays as would occur in systems with dendritic branches or in networks
	where there is a distance-dependent conductance delay. In the latter,
	we use mean field theory to show the emergence of travelling waves
	and the loss of synchronization. Next, we consider phase models with
	stronger coupling and delays in the state variables. We show that
	they have a richer dynamics but one that is still similar to the
	weakly coupled case.},
  doi = {10.1098/rsta.2008.0259},
  institution = {Department of Mathematics, University of Pittsburgh, Pittsburgh,
	PA 15260, USA. bard@pitt.edu},
  keywords = {Behavior; Circadian Rhythm; Dendrites, physiology; Humans; Models,
	Neurological; Nervous System Physiological Phenomena; Neurons, physiology;
	Nonlinear Dynamics; Oscillometry; Periodicity; Reaction Time, physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {A645682257121RM3},
  pmid = {19218153},
  timestamp = {2013.09.04},
  url = {http://dx.doi.org/10.1098/rsta.2008.0259}
}

@ARTICLE{Ermentrout_1994,
  author = {G. B. Ermentrout},
  title = {The mathematics of biological oscillators.},
  journal = {Methods Enzymol},
  year = {1994},
  volume = {240},
  pages = {198--216},
  institution = {Department of Mathematics, University of Pittsburgh, Pennsylvania
	15260.},
  keywords = {Animals; Biology, methods; Computer Simulation; Feedback; Glycolysis;
	Mammals; Mathematics; Models, Theoretical; Oscillometry; Periodicity},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {7823832},
  timestamp = {2013.09.04}
}

@ARTICLE{Ermentrout_1985,
  author = {G. B. Ermentrout},
  title = {The behavior of rings of coupled oscillators.},
  journal = {J Math Biol},
  year = {1985},
  volume = {23},
  pages = {55--74},
  number = {1},
  abstract = {Coupled oscillators in a ring are studied using perturbation and numerical
	methods. Stability of waves with nearest neighbor weak coupling is
	shown for a class of simple oscillators. Linkens' model for colorectal
	activity is analyzed and several stable modes are found. Stability
	of waves with general (non nearest neighbor coupling) is determined
	and comparisons to the nearest neighbor case are made. Approximate
	solutions to a ring with inhomogeneities are compared with numerical
	simulations.},
  keywords = {Animals; Colon, physiology; Mathematics; Models, Biological; Muscle,
	Smooth, physiology; Oscillometry; Rectum, physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {4078499},
  timestamp = {2013.09.04}
}

@ARTICLE{Ermentrout_2002,
  author = {G. Bard Ermentrout and Carson C Chow},
  title = {Modeling neural oscillations.},
  journal = {Physiol Behav},
  year = {2002},
  volume = {77},
  pages = {629--633},
  number = {4-5},
  month = {Dec},
  abstract = {A brief review of oscillatory activity in neurons and networks is
	given. Conditions required for neural oscillations are provided.
	Three mathematical methods for studying the coupling between neural
	oscillators are described: (i) weak coupling, (ii) firing time maps,
	and (iii) leaky integrate-and-fire methods. Several applications
	from macroscopic motor behavior to slice phenomena are provided.},
  institution = {Department of Mathematics, University of Pittsburgh, 15260, Pittsburgh,
	PA, USA. bard@pitt.edu},
  keywords = {Algorithms; Animals; Electrophysiology; Humans; Models, Neurological;
	Models, Statistical; Neurons, physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S0031938402008983},
  pmid = {12527010},
  timestamp = {2013.09.04}
}

@ARTICLE{Ermentrout_1979,
  author = {G. B. Ermentrout and J. D. Cowan},
  title = {A mathematical theory of visual hallucination patterns.},
  journal = {Biol Cybern},
  year = {1979},
  volume = {34},
  pages = {137--150},
  number = {3},
  month = {Oct},
  abstract = {Neuronal activity in a two-dimensional net is analyzed in the neighborhood
	of an instability. Bifurcation theory and group theory are used to
	demonstrate the existence of a variety of doubly-periodic patterns,
	hexagons, rolls, etc., as solutions to the field equations for the
	net activity. It is suggested that these simple geometric patterns
	are the cortical concomitants of the "form constants" seen during
	visual hallucinosis.},
  keywords = {Action Potentials; Hallucinations, physiopathology; Humans; Membrane
	Potentials; Models, Neurological; Nerve Net, physiology; Neural Inhibition;
	Periodicity; Vision, Ocular; Visual Cortex, physiology; Visual Fields},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {486593},
  timestamp = {2013.09.04}
}

@ARTICLE{Ermentrout_1979a,
  author = {G. B. Ermentrout and J. D. Cowan},
  title = {Temporal oscillations in neuronal nets.},
  journal = {J Math Biol},
  year = {1979},
  volume = {7},
  pages = {265--280},
  number = {3},
  month = {Apr},
  abstract = {A model for the interactions of cortical neurons is derived and analyzed.
	It is shown that small amplitude spatially inhomogeneous standing
	oscillations can bifurcate from the rest state. In a periodic domain,
	traveling wave trains exist. Stability of these patterns is discussed
	in terms of biological parameters. Homoclinic and heteroclinic orbits
	are demonstrated for the space-clamped system.},
  keywords = {Brain, physiology; Fourier Analysis; Models, Neurological; Nerve Net,
	physiology; Neural Inhibition; Neurons, physiology; Oscillometry;
	Periodicity; Synaptic Transmission},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {224126},
  timestamp = {2013.09.04}
}

@ARTICLE{Ermentrout_1993,
  author = {G. B. Ermentrout and L. Edelstein-Keshet},
  title = {Cellular automata approaches to biological modeling.},
  journal = {J Theor Biol},
  year = {1993},
  volume = {160},
  pages = {97--133},
  number = {1},
  month = {Jan},
  abstract = {We review a number of biologically motivated cellular automata (CA)
	that arise in models of excitable and oscillatory media, in developmental
	biology, in neurobiology, and in population biology. We suggest technical
	and theoretical arguments that permit greater speed and enhanced
	realism, and apply these to several classical examples of pattern
	formation. We also describe CA that arise in models for fibroblast
	aggregation, branching networks, trail following, and neuronal maps.},
  doi = {10.1006/jtbi.1993.1007},
  institution = {Department of Mathematics and Statistics, University of Pittsburgh,
	PA 15260.},
  keywords = {Allergy and Immunology; Animals; Bacteria, growth /&/ development;
	Computer Simulation; Developmental Biology; Ecology; Humans; Models,
	Biological; Neural Networks (Computer)},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S0022-5193(83)71007-6},
  pmid = {8474249},
  timestamp = {2013.09.04},
  url = {http://dx.doi.org/10.1006/jtbi.1993.1007}
}

@ARTICLE{Ermentrout_2008,
  author = {G. Bard Ermentrout and Roberto F Galán and Nathaniel N Urban},
  title = {Reliability, synchrony and noise.},
  journal = {Trends Neurosci},
  year = {2008},
  volume = {31},
  pages = {428--434},
  number = {8},
  month = {Aug},
  abstract = {The brain is noisy. Neurons receive tens of thousands of highly fluctuating
	inputs and generate spike trains that appear highly irregular. Much
	of this activity is spontaneous - uncoupled to overt stimuli or motor
	outputs - leading to questions about the functional impact of this
	noise. Although noise is most often thought of as disrupting patterned
	activity and interfering with the encoding of stimuli, recent theoretical
	and experimental work has shown that noise can play a constructive
	role - leading to increased reliability or regularity of neuronal
	firing in single neurons and across populations. These results raise
	fundamental questions about how noise can influence neural function
	and computation.},
  doi = {10.1016/j.tins.2008.06.002},
  institution = {Department of Mathematics, University of Pittsburgh, Thackery Hall,
	Pittsburgh, PA 15260, USA.},
  keywords = {Animals; Artifacts; Brain, physiology; Cortical Synchronization; Electrophysiology,
	methods; Humans; Neurons, physiology; Reproducibility of Results},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S0166-2236(08)00151-3},
  pmid = {18603311},
  timestamp = {2013.09.04},
  url = {http://dx.doi.org/10.1016/j.tins.2008.06.002}
}

@ARTICLE{Ermentrout_2007,
  author = {G. Bard Ermentrout and Roberto F Galán and Nathaniel N Urban},
  title = {Relating neural dynamics to neural coding.},
  journal = {Phys Rev Lett},
  year = {2007},
  volume = {99},
  pages = {248103},
  number = {24},
  month = {Dec},
  abstract = {We demonstrate that two key theoretical objects used widely in computational
	neuroscience, the phase-resetting curve (PRC) from dynamics and the
	spike triggered average (STA) from statistical analysis, are closely
	related when neurons fire in a nearly regular manner and the stimulus
	is sufficiently small. We prove that the STA due to injected noisy
	current is proportional to the derivative of the PRC. We compare
	these analytic results with numerical calculations for the Hodgkin-Huxley
	neuron and we apply the method to neurons in the olfactory bulb of
	mice. This observation allows us to relate the stimulus-response
	properties of a neuron to its dynamics, bridging the gap between
	dynamical and information theoretic approaches to understanding brain
	computations and facilitating the interpretation of changes in channels
	and other cellular properties as influencing the representation of
	stimuli.},
  institution = {University of Pittsburgh, Department of Mathematics, Thackeray Hall,
	Pittsburgh, Pennsylvania 15260, USA.},
  keywords = {Action Potentials, physiology; Animals; Models, Neurological; Neurons,
	physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {18233494},
  timestamp = {2013.09.04}
}

@ARTICLE{Ermentrout_2001,
  author = {G. B. Ermentrout and D. Kleinfeld},
  title = {Traveling electrical waves in cortex: insights from phase dynamics
	and speculation on a computational role.},
  journal = {Neuron},
  year = {2001},
  volume = {29},
  pages = {33--44},
  number = {1},
  month = {Jan},
  abstract = {The theory of coupled phase oscillators provides a framework to understand
	the emergent properties of networks of neuronal oscillators. When
	the architecture of the network is dominated by short-range connections,
	the pattern of electrical output is predicted to correspond to traveling
	plane and rotating waves, in addition to synchronized output. We
	argue that this theory provides the foundation for understanding
	the traveling electrical waves that are observed across olfactory,
	visual, and visuomotor areas of cortex in a variety of species. The
	waves are typically present during periods outside of stimulation,
	while synchronous activity typically dominates in the presence of
	a strong stimulus. We suggest that the continuum of phase shifts
	during epochs with traveling waves provides a means to scan the incoming
	sensory stream for novel features. Experiments to test our theoretical
	approach are presented.},
  institution = {Department of Mathematics, University of Pittsburgh, Pittsburgh,
	PA 15260, USA. bard@math.pitt.edu},
  keywords = {Animals; Biological Clocks, physiology; Cerebral Cortex, physiology;
	Humans; Models, Neurological; Nerve Net, physiology; Neural Networks
	(Computer); Synaptic Transmission, physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S0896-6273(01)00178-7},
  pmid = {11182079},
  timestamp = {2013.09.04}
}

@ARTICLE{Ermentrout_1998,
  author = {G. B. Ermentrout and N. Kopell},
  title = {Fine structure of neural spiking and synchronization in the presence
	of conduction delays.},
  journal = {Proc Natl Acad Sci U S A},
  year = {1998},
  volume = {95},
  pages = {1259--1264},
  number = {3},
  month = {Feb},
  abstract = {Hippocampal networks of excitatory and inhibitory neurons that produce
	gamma-frequency rhythms display behavior in which the inhibitory
	cells produce spike doublets when there is strong stimulation at
	separated sites. It has been suggested that the doublets play a key
	role in the ability to synchronize over a distance. Here we analyze
	the mechanisms by which timing in the spike doublet can affect the
	synchronization process. The analysis describes two independent effects:
	one comes from the timing of excitation from separated local circuits
	to an inhibitory cell, and the other comes from the timing of inhibition
	from separated local circuits to an excitatory cell. We show that
	a network with both of these effects has different synchronization
	properties than a network with either excitatory or inhibitory type
	of coupling alone, and we give a rationale for the shorter space
	scales associated with inhibitory interactions.},
  institution = {Department of Mathematics, University of Pittsburgh, Pittsburgh,
	PA 15260, USA.},
  keywords = {Brain Mapping; Cortical Synchronization; Electrophysiology; Hippocampus,
	physiology; Models, Neurological; Neural Conduction, physiology;
	Neurons, physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {9448319},
  timestamp = {2013.09.04}
}

@ARTICLE{Eskildsen2012,
  author = {Simon F Eskildsen and Pierrick Coupé and Vladimir Fonov and José
	V Manjón and Kelvin K Leung and Nicolas Guizard and Shafik N Wassef
	and Lasse Riis Østergaard and D. Louis Collins and Alzheimer's Disease
	Neuroimaging Initiative},
  title = {BEaST: brain extraction based on nonlocal segmentation technique.},
  journal = {Neuroimage},
  year = {2012},
  volume = {59},
  pages = {2362--2373},
  number = {3},
  month = {Feb},
  abstract = {Brain extraction is an important step in the analysis of brain images.
	The variability in brain morphology and the difference in intensity
	characteristics due to imaging sequences make the development of
	a general purpose brain extraction algorithm challenging. To address
	this issue, we propose a new robust method (BEaST) dedicated to produce
	consistent and accurate brain extraction. This method is based on
	nonlocal segmentation embedded in a multi-resolution framework. A
	library of 80 priors is semi-automatically constructed from the NIH-sponsored
	MRI study of normal brain development, the International Consortium
	for Brain Mapping, and the Alzheimer's Disease Neuroimaging Initiative
	databases. In testing, a mean Dice similarity coefficient of 0.9834±0.0053
	was obtained when performing leave-one-out cross validation selecting
	only 20 priors from the library. Validation using the online Segmentation
	Validation Engine resulted in a top ranking position with a mean
	Dice coefficient of 0.9781±0.0047. Robustness of BEaST is demonstrated
	on all baseline ADNI data, resulting in a very low failure rate.
	The segmentation accuracy of the method is better than two widely
	used publicly available methods and recent state-of-the-art hybrid
	approaches. BEaST provides results comparable to a recent label fusion
	approach, while being 40 times faster and requiring a much smaller
	library of priors.},
  doi = {10.1016/j.neuroimage.2011.09.012},
  institution = {McConnell Brain Imaging Centre, Montreal Neurological Institute,
	McGill University, 3801 University Street, Montreal, Canada. se@hst.aau.dk},
  keywords = {Adolescent; Adult; Algorithms; Brain Mapping, methods; Brain, anatomy
	/&/ histology; Computers; Databases, Factual; False Negative Reactions;
	False Positive Reactions; Female; Humans; Image Processing, Computer-Assisted,
	methods/statistics /&/ numerical data; Magnetic Resonance Imaging,
	methods/statistics /&/ numerical data; Male; Quality Control; Reference
	Standards; Reproducibility of Results; Software; Young Adult},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S1053-8119(11)01057-3},
  pmid = {21945694},
  timestamp = {2013.07.04},
  url = {http://dx.doi.org/10.1016/j.neuroimage.2011.09.012}
}

@ARTICLE{Essen_2012a,
  author = {David C Van Essen and Matthew F Glasser and Donna L Dierker and John
	Harwell},
  title = {Cortical parcellations of the macaque monkey analyzed on surface-based
	atlases.},
  journal = {Cereb. Cortex},
  year = {2012},
  volume = {22},
  pages = {2227--2240},
  number = {10},
  month = {Oct},
  abstract = {Surface-based atlases provide a valuable way to analyze and visualize
	the functional organization of cerebral cortex. Surface-based registration
	(SBR) is a primary method for aligning individual hemispheres to
	a surface-based atlas. We used landmark-constrained SBR to register
	many published parcellation schemes to the macaque F99 surface-based
	atlas. This enables objective comparison of both similarities and
	differences across parcellations. Cortical areas in the macaque vary
	in surface area by more than 2 orders of magnitude. Based on a composite
	parcellation derived from 3 major sources, the total number of macaque
	neocortical and transitional cortical areas is estimated to be about
	130-140 in each hemisphere.},
  doi = {10.1093/cercor/bhr290},
  institution = { Neurobiology, Washington University School of Medicine, St. Louis,
	MO 63110, USA. vanessen@wustl.edu},
  keywords = {Animals; Cerebral Cortex, anatomy /&/ histology/physiology; Connectome,
	methods; Macaca mulatta, anatomy /&/ histology/physiology; Models,
	Anatomic; Models, Neurological},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {bhr290},
  pmid = {22052704},
  timestamp = {2013.02.18},
  url = {http://dx.doi.org/10.1093/cercor/bhr290}
}

@ARTICLE{Essen_2012,
  author = {David C Van Essen and Matthew F Glasser and Donna L Dierker and John
	Harwell and Timothy Coalson},
  title = {Parcellations and hemispheric asymmetries of human cerebral cortex
	analyzed on surface-based atlases.},
  journal = {Cereb. Cortex},
  year = {2012},
  volume = {22},
  pages = {2241--2262},
  number = {10},
  month = {Oct},
  abstract = {We report on surface-based analyses that enhance our understanding
	of human cortical organization, including its convolutions and its
	parcellation into many distinct areas. The surface area of human
	neocortex averages 973 cm(2) per hemisphere, based on cortical midthickness
	surfaces of 2 cohorts of subjects. We implemented a method to register
	individual subjects to a hybrid version of the FreeSurfer "fsaverage"
	atlas whose left and right hemispheres are in precise geographic
	correspondence. Cortical folding patterns in the resultant population-average
	"fs_LR" midthickness surfaces are remarkably similar in the left
	and right hemispheres, even in regions showing significant asymmetry
	in 3D position. Both hemispheres are equal in average surface area,
	but hotspots of surface area asymmetry are present in the Sylvian
	Fissure and elsewhere, together with a broad pattern of asymmetries
	that are significant though small in magnitude. Multiple cortical
	parcellation schemes registered to the human atlas provide valuable
	reference data sets for comparisons with other studies. Identified
	cortical areas vary in size by more than 2 orders of magnitude. The
	total number of human neocortical areas is estimated to be ∼150 to
	200 areas per hemisphere, which is modestly larger than a recent
	estimate for the macaque.},
  doi = {10.1093/cercor/bhr291},
  institution = { Neurobiology, Washington University School of Medicine, St. Louis,
	MO 63110, USA. vanessen@wustl.edu},
  keywords = {Cerebral Cortex, anatomy /&/ histology/physiology; Connectome, methods;
	Humans; Models, Anatomic; Models, Neurological},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {bhr291},
  pmid = {22047963},
  timestamp = {2013.02.18},
  url = {http://dx.doi.org/10.1093/cercor/bhr291}
}

@ARTICLE{Essen_2012b,
  author = {D. C. Van Essen and K. Ugurbil},
  title = {The future of the human connectome.},
  journal = {Neuroimage},
  year = {2012},
  volume = {62},
  pages = {1299--1310},
  number = {2},
  month = {Aug},
  abstract = {The opportunity to explore the human connectome using cutting-edge
	neuroimaging methods has elicited widespread interest. How far will
	the field be able to progress in deciphering long-distance connectivity
	patterns and in relating differences in connectivity to phenotypic
	characteristics in health and disease? We discuss the daunting nature
	of this challenge in relation to specific complexities of brain circuitry
	and known limitations of in vivo imaging methods. We also discuss
	the excellent prospects for continuing improvements in data acquisition
	and analysis. Accordingly, we are optimistic that major insights
	will emerge from human connectomics in the coming decade.},
  doi = {10.1016/j.neuroimage.2012.01.032},
  institution = { Neurobiology, 660 S Euclid Avenue, St Louis, MO 63110, USA. vanessen@wustl.edu},
  keywords = {Animals; Brain Mapping, methods/trends; Brain, physiology; History,
	20th Century; History, 21st Century; Humans; Image Processing, Computer-Assisted,
	history/methods/trends; Nerve Net, physiology; Neuroimaging, history/methods/trends},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S1053-8119(12)00049-3},
  pmid = {22245355},
  timestamp = {2013.02.18},
  url = {http://dx.doi.org/10.1016/j.neuroimage.2012.01.032}
}

@ARTICLE{Essen_2012c,
  author = {D. C. Van Essen and K. Ugurbil and E. Auerbach and D. Barch and T.
	E J Behrens and R. Bucholz and A. Chang and L. Chen and M. Corbetta
	and S. W. Curtiss and S. Della Penna and D. Feinberg and M. F. Glasser
	and N. Harel and A. C. Heath and L. Larson-Prior and D. Marcus and
	G. Michalareas and S. Moeller and R. Oostenveld and S. E. Petersen
	and F. Prior and B. L. Schlaggar and S. M. Smith and A. Z. Snyder
	and J. Xu and E. Yacoub and W. U-Minn HCP Consortium},
  title = {The Human Connectome Project: a data acquisition perspective.},
  journal = {Neuroimage},
  year = {2012},
  volume = {62},
  pages = {2222--2231},
  number = {4},
  month = {Oct},
  abstract = {The Human Connectome Project (HCP) is an ambitious 5-year effort to
	characterize brain connectivity and function and their variability
	in healthy adults. This review summarizes the data acquisition plans
	being implemented by a consortium of HCP investigators who will study
	a population of 1200 subjects (twins and their non-twin siblings)
	using multiple imaging modalities along with extensive behavioral
	and genetic data. The imaging modalities will include diffusion imaging
	(dMRI), resting-state fMRI (R-fMRI), task-evoked fMRI (T-fMRI), T1-
	and T2-weighted MRI for structural and myelin mapping, plus combined
	magnetoencephalography and electroencephalography (MEG/EEG). Given
	the importance of obtaining the best possible data quality, we discuss
	the efforts underway during the first two years of the grant (Phase
	I) to refine and optimize many aspects of HCP data acquisition, including
	a new 7T scanner, a customized 3T scanner, and improved MR pulse
	sequences.},
  institution = {is, MO, USA. vanessen@wustl.edu},
  keywords = {Brain Mapping, methods; Brain, anatomy /&/ histology/physiology; Connectome,
	methods; Humans},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {22366334},
  timestamp = {2013.02.18}
}

@ARTICLE{Ferguson_1994,
  author = {Ferguson, AS and Zhang, X. and Stroink, G.},
  title = {{A complete linear discretization for calculating the magnetic field
	using the boundary element method}},
  journal = {IEEE Trans. Biomed. Eng.},
  year = {1994},
  volume = {41},
  pages = {455--460},
  number = {5},
  doi = {10.1109/10.293220},
  issn = {0018-9294}
}

@ARTICLE{FitzHugh_1961,
  author = {R FitzHugh},
  title = {Impulses and physiological states in theoretical models of nerve
	membrane},
  journal = {Biophys. J.},
  year = {1961},
  volume = {1},
  pages = {445-466},
  number = {6},
  month = {July},
  abstract = {Van der Pol's equation for a relaxation oscillator is generalized
	by the addition of terms to produce a pair of non-linear differential
	equations with either a stable singular point or a limit cycle. The
	resulting “BVP model” has two variables of state, representing excitability
	and refractoriness, and qualitatively resembles Bonhoeffer's theoretical
	model for the iron wire model of nerve. This BVP model serves as
	a simple representative of a class of excitable-oscillatory systems
	including the Hodgkin-Huxley (HH) model of the squid giant axon.
	The BVP phase plane can be divided into regions corresponding to
	the physiological states of nerve fiber (resting, active, refractory,
	enhanced, depressed, etc.) to form a “physiological state diagram,”
	with the help of which many physiological phenomena can be summarized.
	A properly chosen projection from the 4-dimensional HH phase space
	onto a plane produces a similar diagram which shows the underlying
	relationship between the two models. Impulse trains occur in the
	BVP and HH models for a range of constant applied currents which
	make the singular point representing the resting state unstable.},
  keywords = {model},
  owner = {paula},
  timestamp = {2012.10.18}
}

@ARTICLE{Folias_2011,
  author = {S. E. Folias and G. B. Ermentrout},
  title = {New patterns of activity in a pair of interacting excitatory-inhibitory
	neural fields.},
  journal = {Phys Rev Lett},
  year = {2011},
  volume = {107},
  pages = {228103},
  number = {22},
  month = {Nov},
  abstract = {In this Letter, we study stationary bump solutions in a pair of interacting
	excitatory-inhibitory (E-I) neural fields in one dimension. We demonstrate
	the existence of localized bump solutions of persistent activity
	that can be maintained by the pair of interacting layers when a stationary
	bump is not supported by either layer in isolation--a scenario which
	may be relevant as a mechanism for the persistent activity associated
	with working memory in the prefrontal cortex and may explain why
	bumps are not seen in in vitro slice preparations. Furthermore, we
	describe a new type of stationary bump solution arising from a pitchfork
	bifurcation which produces a stationary bump in each layer with a
	spatial offset that increases with the bifurcation parameter.},
  institution = {Department of Mathematics, University of Pittsburgh, Pittsburgh,
	Pennsylvania 15260, USA.},
  keywords = {Models, Neurological; Nerve Net, cytology/physiology; Neurons, cytology;
	Synaptic Potentials},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {22182044},
  timestamp = {2013.09.04}
}

@ARTICLE{Fornito_2012,
  author = {Alex Fornito and Ben J Harrison and Andrew Zalesky and Jon S Simons},
  title = {Competitive and cooperative dynamics of large-scale brain functional
	networks supporting recollection.},
  journal = {Proc. Natl. Acad. Sci. U.S.A.},
  year = {2012},
  volume = {109},
  pages = {12788--12793},
  number = {31},
  month = {Jul},
  abstract = {Analyses of functional interactions between large-scale brain networks
	have identified two broad systems that operate in apparent competition
	or antagonism with each other. One system, termed the default mode
	network (DMN), is thought to support internally oriented processing.
	The other system acts as a generic external attention system (EAS)
	and mediates attention to exogenous stimuli. Reports that the DMN
	and EAS show anticorrelated activity across a range of experimental
	paradigms suggest that competition between these systems supports
	adaptive behavior. Here, we used functional MRI to characterize functional
	interactions between the DMN and different EAS components during
	performance of a recollection task known to coactivate regions of
	both networks. Using methods to isolate task-related, context-dependent
	changes in functional connectivity between these systems, we show
	that increased cooperation between the DMN and a specific right-lateralized
	frontoparietal component of the EAS is associated with more rapid
	memory recollection. We also show that these cooperative dynamics
	are facilitated by a dynamic reconfiguration of the functional architecture
	of the DMN into core and transitional modules, with the latter serving
	to enhance integration with frontoparietal regions. In particular,
	the right posterior cingulate cortex may act as a critical information-processing
	hub that provokes these context-dependent reconfigurations from an
	intrinsic or default state of antagonism. Our findings highlight
	the dynamic, context-dependent nature of large-scale brain dynamics
	and shed light on their contribution to individual differences in
	behavior.},
  doi = {10.1073/pnas.1204185109},
  institution = {ourne and Melbourne Health, Parkville, Victoria 3053, Australia.
	fornitoa@unimelb.edu.au},
  keywords = {Adaptation, Psychological, physiology; Adult; Attention, physiology;
	Brain, physiology; Humans; Male; Mental Recall, physiology; Models,
	Neurological},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {1204185109},
  pmid = {22807481},
  timestamp = {2013.03.14},
  url = {http://dx.doi.org/10.1073/pnas.1204185109}
}

@ARTICLE{Fornito_2010,
  author = {Alex Fornito and Andrew Zalesky and Edward T Bullmore},
  title = {Network scaling effects in graph analytic studies of human resting-state
	FMRI data.},
  journal = {Front. Syst. Neurosci.},
  year = {2010},
  volume = {4},
  pages = {22},
  abstract = {Graph analysis has become an increasingly popular tool for characterizing
	topological properties of brain connectivity networks. Within this
	approach, the brain is modeled as a graph comprising N nodes connected
	by M edges. In functional magnetic resonance imaging (fMRI) studies,
	the nodes typically represent brain regions and the edges some measure
	of interaction between them. These nodes are commonly defined using
	a variety of regional parcellation templates, which can vary both
	in the volume sampled by each region, and the number of regions parcellated.
	Here, we sought to investigate how such variations in parcellation
	templates affect key graph analytic measures of functional brain
	organization using resting-state fMRI in 30 healthy volunteers. Seven
	different parcellation resolutions (84, 91, 230, 438, 890, 1314,
	and 4320 regions) were investigated. We found that gross inferences
	regarding network topology, such as whether the brain is small-world
	or scale-free, were robust to the template used, but that both absolute
	values of, and individual differences in, specific parameters such
	as path length, clustering, small-worldness, and degree distribution
	descriptors varied considerably across the resolutions studied. These
	findings underscore the need to consider the effect that a specific
	parcellation approach has on graph analytic findings in human fMRI
	studies, and indicate that results obtained using different templates
	may not be directly comparable.},
  doi = {10.3389/fnsys.2010.00022},
  institution = {Department of Psychiatry, Brain Mapping Unit, University of Cambridge
	UK.},
  language = {eng},
  medline-pst = {epublish},
  owner = {paula},
  pmid = {20592949},
  timestamp = {2013.03.14},
  url = {http://dx.doi.org/10.3389/fnsys.2010.00022}
}

@ARTICLE{Foster2011,
  author = {Foster, Brett L. and Bojak, Ingo and Liley, David T J.},
  title = {Understanding the effects of anesthetic agents on the EEG through
	neural field theory.},
  journal = {Conf. Proc. IEEE. Eng. Med. Biol. Soc.},
  year = {2011},
  volume = {2011},
  pages = {4709--4712},
  abstract = {Anesthetic and analgesic agents act through a diverse range of pharmacological
	mechanisms. Existing empirical data clearly shows that such "microscopic"
	pharmacological diversity is reflected in their "macroscopic" effects
	on the human electroencephalogram (EEG). Based on a detailed mesoscopic
	neural field model we theoretically posit that anesthetic induced
	EEG activity is due to selective parametric changes in synaptic efficacy
	and dynamics. Specifically, on the basis of physiologically constrained
	modeling, it is speculated that the selective modification of inhibitory
	or excitatory synaptic activity may differentially effect the EEG
	spectrum. Such results emphasize the importance of neural field theories
	of brain electrical activity for elucidating the principles whereby
	pharmacological agents effect the EEG. Such insights will contribute
	to improved methods for monitoring depth of anesthesia using the
	EEG.},
  doi = {10.1109/IEMBS.2011.6091166},
  institution = {Department of Neurology and Neurological Sciences, School of Medicine
	Stanford University, Stanford, CA 94305, USA. blfoster@stanford.edu},
  keywords = {Anesthetics, pharmacology; Electroencephalography, methods; Humans;
	Models, Theoretical},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paupau},
  pmid = {22255389},
  timestamp = {2013.04.09},
  url = {http://dx.doi.org/10.1109/IEMBS.2011.6091166}
}

@ARTICLE{Foster2008,
  author = {Foster, Brett L. and Bojak, Ingo and Liley, David T J.},
  title = {Population based models of cortical drug response: insights from
	anaesthesia.},
  journal = {Cognitive Neurodynamics},
  year = {2008},
  volume = {2},
  pages = {283--296},
  number = {4},
  month = {Dec},
  abstract = {A great explanatory gap lies between the molecular pharmacology of
	psychoactive agents and the neurophysiological changes they induce,
	as recorded by neuroimaging modalities. Causally relating the cellular
	actions of psychoactive compounds to their influence on population
	activity is experimentally challenging. Recent developments in the
	dynamical modelling of neural tissue have attempted to span this
	explanatory gap between microscopic targets and their macroscopic
	neurophysiological effects via a range of biologically plausible
	dynamical models of cortical tissue. Such theoretical models allow
	exploration of neural dynamics, in particular their modification
	by drug action. The ability to theoretically bridge scales is due
	to a biologically plausible averaging of cortical tissue properties.
	In the resulting macroscopic neural field, individual neurons need
	not be explicitly represented (as in neural networks). The following
	paper aims to provide a non-technical introduction to the mean field
	population modelling of drug action and its recent successes in modelling
	anaesthesia.},
  doi = {10.1007/s11571-008-9063-z},
  institution = {Brain Sciences Institute, Swinburne University of Technology, 400
	Burwood Rd., Hawthorn, 3122, Melbourne, Australia, bfoster@swin.edu.au.},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paupau},
  pmid = {19003456},
  timestamp = {2013.04.09},
  url = {http://dx.doi.org/10.1007/s11571-008-9063-z}
}

@ARTICLE{Foster_2013,
  author = {Foster, Brett L. and Liley, David T J.},
  title = {Effects of nitrous oxide sedation on resting electroencephalogram
	topography.},
  journal = {Clin Neurophysiol},
  year = {2013},
  volume = {124},
  pages = {417--423},
  number = {2},
  month = {Feb},
  abstract = {To quantify the effects of nitrous oxide (N(2)O) gas on electroencephalogram
	(EEG) topography in healthy male participants.Healthy male participants
	were administered 20\% (n=8) or 40\% (n=8) N(2)O while having high-density
	(modified 10-20) noise minimized EEG recordings.Nitrous oxide was
	found to produce clear reductions in resting total power, particularly
	at frontal-vertex sites. These reductions were found to principally
	reflect reductions in band-limited delta power. Following the termination
	of N(2)O inhalation, during N(2)O washout, selective increases in
	frontal theta power were observed that increased above baseline values.Nitrous
	oxide does not produce the classical anteriorization of slow wave
	activity typically seen during anesthetic induction. Instead N(2)O
	reduces frontal slow wave (delta) activity, which during gas washout
	produces a withdrawal response of enhanced frontal slow wave (theta)
	activity.Attempts to characterize a unitary mechanism of loss of
	consciousness during anesthesia on the basis of the topographic electroencephalographic
	changes is challenged by the distinct EEG effects that N(2)O has
	when compared to other well known anesthetic agents that include
	propofol and sevoflurane.},
  doi = {10.1016/j.clinph.2012.08.007},
  institution = {Department of Neurology and Neurological Sciences, School of Medicine,
	Stanford University, Stanford, CA 94305-5235, United States. blfoster@stanford.edu},
  keywords = {Adult; Anesthetics, Inhalation, pharmacology; Brain Mapping; Delta
	Rhythm, drug effects/physiology; Dose-Response Relationship, Drug;
	Electroencephalography, drug effects; Frontal Lobe, drug effects/physiology;
	Humans; Male; Nitrous Oxide, pharmacology; Rest, physiology; Theta
	Rhythm, drug effects/physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paupau},
  pii = {S1388-2457(12)00574-3},
  pmid = {22968005},
  timestamp = {2013.08.24},
  url = {http://dx.doi.org/10.1016/j.clinph.2012.08.007}
}

@ARTICLE{Foster2011b,
  author = {Foster, Brett L. and Liley, David T J.},
  title = {Nitrous oxide paradoxically modulates slow electroencephalogram oscillations:
	implications for anesthesia monitoring.},
  journal = {Anesth Analg},
  year = {2011},
  volume = {113},
  pages = {758--765},
  number = {4},
  month = {Oct},
  abstract = {Nitrous oxide (N(2)O) is one of the oldest analgesics/adjuvant agents
	still in use today; however, its effects on the human electroencephalogram
	(EEG) remain unclear. It has been proposed that N(2)O may enhance
	higher-frequency EEG activity (often indicative of alert states and
	cognition) duration sedation. This possibly paradoxical effect has
	been used to explain the failure of many EEG monitors to capture
	the effects of N(2)O on patient state during anesthesia. To better
	understand the poor efficacy of current EEG approaches to monitoring
	N(2)O action, we quantitatively studied the sole effect of N(2)O
	on the resting EEG in healthy volunteers using multichannel EEG recordings
	under noise-minimized laboratory conditions.Healthy male volunteers
	were administered 20\% (n = 10), 40\% (n = 10), or 60\% (n = 5) inspired
	N(2)O mixed with oxygen during noise-shielded EEG recordings. N(2)O
	was administered over a 20-minute period involving a 5-minute equilibration
	period and 5-minute washout. EEG spectral edge frequency (95\%),
	median power frequency, total power, and band-limited power (δ, ,
	α, β, and γ) were used as quantitative EEG parameters. The changes
	in these EEG parameters were quantified throughout N(2)O inhalation
	and compared between predrug baseline, peak drug effect, and washout.Quantification
	of changes in spectral power during N(2)O inhalation showed only
	minor changes in estimates of spectral edge and median power frequency,
	whereas significant reductions in total power were observed at frontal
	sites during peak gas effect (P = 0.001; mean reduction [95\% confidence
	interval]: 41.90 μV(2) [18.19-65.61 μV(2)]) that rebounded during
	N(2)O washout. Such changes in total power were driven by shifts
	in low-frequency power (δ/), which were most elevated at frontal
	sites.Rather than directly enhancing high-frequency EEG power (β
	or γ bands), N(2)O seems to preserve the awake features of resting
	EEG (α band) and suppress power in those bands in which increases
	are typically associated with sedation/hypnosis (δ and ). These data
	suggest that N(2)O's suppression of low-frequency EEG power may help
	to explain previously reported difficulties in attempting to monitor
	patient state with the EEG during anesthesia involving N(2)O. Because
	increases in low-frequency power typically indicate increasing anesthesia,
	N(2)O's suppression of such activity and its rebound during washout
	would paradoxically influence EEG monitoring parameters. Therefore,
	correcting for such effects is expected to improve future monitoring
	methods.},
  doi = {10.1213/ANE.0b013e318227b688},
  institution = {Faculty of Life and Social Sciences, Brain and Psychological Sciences
	Research Centre, Swinburne University of Technology, Melbourne, Australia.
	blfoster@stanford.edu},
  keywords = {Acoustic Stimulation; Adult; Analysis of Variance; Anesthesia, General;
	Anesthetics, Inhalation, administration /&/ dosage; Auditory Perception,
	drug effects; Brain Waves, drug effects; Cognition, drug effects;
	Dose-Response Relationship, Drug; Electroencephalography, instrumentation;
	Humans; Male; Monitoring, Intraoperative, instrumentation/methods;
	Nitrous Oxide, administration /&/ dosage; Predictive Value of Tests;
	Reproducibility of Results; Signal Processing, Computer-Assisted;
	Time Factors; Victoria; Young Adult},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paupau},
  pii = {ANE.0b013e318227b688},
  pmid = {21788312},
  timestamp = {2013.08.24},
  url = {http://dx.doi.org/10.1213/ANE.0b013e318227b688}
}

@ARTICLE{Fox_2009,
  author = {Charles Fox and Mark Humphries and Ben Mitchinson and Tamas Kiss
	and Zoltan Somogyvari and Tony Prescott},
  title = {Technical integration of hippocampus, Basal Ganglia and physical
	models for spatial navigation.},
  journal = {Front. Neuroinform.},
  year = {2009},
  volume = {3},
  pages = {6},
  abstract = {Computational neuroscience is increasingly moving beyond modeling
	individual neurons or neural systems to consider the integration
	of multiple models, often constructed by different research groups.
	We report on our preliminary technical integration of recent hippocampal
	formation, basal ganglia and physical environment models, together
	with visualisation tools, as a case study in the use of Python across
	the modelling tool-chain. We do not present new modeling results
	here. The architecture incorporates leaky-integrator and rate-coded
	neurons, a 3D environment with collision detection and tactile sensors,
	3D graphics and 2D plots. We found Python to be a flexible platform,
	offering a significant reduction in development time, without a corresponding
	significant increase in execution time. We illustrate this by implementing
	a part of the model in various alternative languages and coding styles,
	and comparing their execution times. For very large-scale system
	integration, communication with other languages and parallel execution
	may be required, which we demonstrate using the BRAHMS framework's
	Python bindings.},
  doi = {10.3389/neuro.11.006.2009},
  institution = {Adaptive Behaviour Research Group, Department of Psychology, University
	of Sheffield Sheffield, UK.},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {19333376},
  timestamp = {2013.02.01},
  url = {http://dx.doi.org/10.3389/neuro.11.006.2009}
}

@ARTICLE{Fox_2007a,
  author = {Michael D Fox and Marcus E Raichle},
  title = {Spontaneous fluctuations in brain activity observed with functional
	magnetic resonance imaging.},
  journal = {Nat. Rev. Neurosci.},
  year = {2007},
  volume = {8},
  pages = {700--711},
  number = {9},
  month = {Sep},
  abstract = {The majority of functional neuroscience studies have focused on the
	brain's response to a task or stimulus. However, the brain is very
	active even in the absence of explicit input or output. In this Article
	we review recent studies examining spontaneous fluctuations in the
	blood oxygen level dependent (BOLD) signal of functional magnetic
	resonance imaging as a potentially important and revealing manifestation
	of spontaneous neuronal activity. Although several challenges remain,
	these studies have provided insight into the intrinsic functional
	architecture of the brain, variability in behaviour and potential
	physiological correlates of neurological and psychiatric disease.},
  doi = {10.1038/nrn2201},
  institution = {Mallinckrodt Institute of Radiology, Washington University School
	of Medicine, 4525 Scott Avenue, St. Louis, Missouri 63110, USA. foxm@npg.wustl.edu},
  keywords = {Animals; Brain Mapping; Brain, blood supply/physiology; Humans; Image
	Processing, Computer-Assisted; Magnetic Resonance Imaging; Oxygen,
	blood},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {nrn2201},
  pmid = {17704812},
  timestamp = {2012.11.14},
  url = {http://dx.doi.org/10.1038/nrn2201}
}

@ARTICLE{Fox_2005,
  author = {Michael D Fox and Abraham Z Snyder and Deanna M Barch and Debra A
	Gusnard and Marcus E Raichle},
  title = {Transient BOLD responses at block transitions.},
  journal = {Neuroimage},
  year = {2005},
  volume = {28},
  pages = {956--966},
  number = {4},
  month = {Dec},
  abstract = {Block-design fMRI responses include sustained components present for
	the duration of each task block as well as transient components at
	the beginning and end of each block. Almost all prior block-design
	fMRI studies have focused on the sustained response components while
	the transient responses at block transitions have been largely ignored.
	These transients, therefore, remain poorly characterized. We here
	present a systematic study of block-transition transient responses
	obtained using four widely divergent tasks. We characterize transient
	response topography and examine the extent to which these responses
	vary across different tasks and between block onset and offset. Our
	analysis reveals that certain regions show transient responses regardless
	of task or transition type. However, our analysis also shows that
	specific task state transitions give rise to transient responses
	with unique spatial profiles. Relevance of the current findings to
	studies of exogenous attention, task shifting, and the BOLD overshoot
	is discussed.},
  doi = {10.1016/j.neuroimage.2005.06.025},
  institution = {Department of Radiology, Mallinckrodt Institute of Radiology, Washington
	University School of Medicine, St. Louis, MO 63110, USA. foxm@npg.wustl.edu},
  keywords = {Adult; Brain Chemistry, physiology; Cognition, physiology; Electrophysiology;
	Female; Fixation, Ocular, physiology; Humans; Image Processing, Computer-Assisted;
	Magnetic Resonance Imaging; Male; Memory, Short-Term, physiology;
	Memory, physiology; Oxygen, blood; Photic Stimulation; Psychomotor
	Performance, physiology; Reading; Visual Perception, physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S1053-8119(05)00464-7},
  pmid = {16043368},
  timestamp = {2013.03.05},
  url = {http://dx.doi.org/10.1016/j.neuroimage.2005.06.025}
}

@ARTICLE{Fox_2005b,
  author = {Michael D Fox and Abraham Z Snyder and Mark P McAvoy and Deanna M
	Barch and Marcus E Raichle},
  title = {The BOLD onset transient: identification of novel functional differences
	in schizophrenia.},
  journal = {Neuroimage},
  year = {2005},
  volume = {25},
  pages = {771--782},
  number = {3},
  month = {Apr},
  abstract = {Blood oxygen level dependent (BOLD) signals characteristically exhibit
	an overshoot (transient signal increase) at the beginning of fMRI
	task blocks. This onset transient has often been overlooked as an
	independent measure of neuronal activity, but it may represent unique
	functional processes. We examined onset transient responses in normal
	subjects and individuals with schizophrenia performing three cognitive
	tasks. These analyses revealed a regionally specific and task specific
	attenuation of the onset transient in individuals with schizophrenia
	during performance of a working memory task. Furthermore, this attenuation
	was often not accompanied by a corresponding population difference
	in the sustained response, and is missed through conventional fMRI
	analysis techniques. Relevance of these findings to both an interpretation
	of the onset transient and the pathology of schizophrenia are discussed.},
  doi = {10.1016/j.neuroimage.2004.12.025},
  institution = {Department of Radiology, Mallinckrodt Institute of Radiology, Washington
	University School of Medicine, 4525 Scott Avenue, St. Louis, MO 63110,
	USA. foxm@npg.wustl.edu},
  keywords = {Adult; Arousal, physiology; Attention, physiology; Brain Mapping;
	Brain, blood supply; Female; Hemodynamics, physiology; Humans; Image
	Enhancement; Image Processing, Computer-Assisted; Magnetic Resonance
	Imaging; Male; Mathematical Computing; Memory, Short-Term, physiology;
	Oxygen, blood; Reference Values; Retention (Psychology), physiology;
	Schizophrenia, physiopathology; Schizophrenic Psychology; Statistics
	as Topic; Visual Cortex, blood supply},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S1053-8119(04)00786-4},
  pmid = {15808978},
  timestamp = {2013.03.05},
  url = {http://dx.doi.org/10.1016/j.neuroimage.2004.12.025}
}

@ARTICLE{Fox_2006,
  author = {Michael D Fox and Abraham Z Snyder and Jeffrey M Zacks and Marcus
	E Raichle},
  title = {Coherent spontaneous activity accounts for trial-to-trial variability
	in human evoked brain responses.},
  journal = {Nat. Neurosci.},
  year = {2006},
  volume = {9},
  pages = {23--25},
  number = {1},
  month = {Jan},
  abstract = {Trial-to-trial variability in the blood oxygen level-dependent (BOLD)
	response of functional magnetic resonance imaging has been shown
	to be relevant to human perception and behavior, but the sources
	of this variability remain unknown. We demonstrate that coherent
	spontaneous fluctuations in human brain activity account for a significant
	fraction of the variability in measured event-related BOLD responses
	and that spontaneous and task-related activity are linearly superimposed
	in the human brain.},
  doi = {10.1038/nn1616},
  institution = {Department of Radiology, Washington University in St. Louis, St.
	Louis, Missouri 63110, USA. foxm@npg.wustl.edu},
  keywords = {Brain, physiology; Evoked Potentials, physiology; Humans; Magnetic
	Resonance Imaging; Oxygen, blood; Photic Stimulation; Psychomotor
	Performance, physiology; Reproducibility of Results},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {nn1616},
  pmid = {16341210},
  timestamp = {2013.03.05},
  url = {http://dx.doi.org/10.1038/nn1616}
}

@ARTICLE{Fox_1988,
  author = {Fox, R and Gatland, I and Rot, R and Vemuri, G},
  title = {Fast, accurate algorithm for numerical simulation of exponentially
	correlated colored noise},
  journal = {Phys. Rev. A},
  year = {1988},
  volume = {38},
  pages = {5938-5940},
  number = {11},
  owner = {paula},
  timestamp = {2012.11.07}
}

@ARTICLE{Freeman_1992,
  author = {Freeman, W. J.},
  title = {Tutorial on Neurobiology: from Single Neurons to Brain Chaos},
  journal = {International Journal of Bifurcation and Chaos},
  year = {1992},
  volume = {2},
  pages = {451-482},
  month = sep,
  adsnote = {Provided by the SAO/NASA Astrophysics Data System},
  adsurl = {http://adsabs.harvard.edu/abs/1992IJBC....2..451F},
  doi = {10.1142/S0218127492000653}
}

@ARTICLE{Freeman_1987,
  author = {Freeman, W. J.},
  title = {Simulation of chaotic EEG patterns with a dynamic model of the olfactory
	system.},
  journal = {Biol. Cybern.},
  year = {1987},
  volume = {56},
  pages = {139--150},
  number = {2-3},
  abstract = {The main parts of the central olfactory system are the bulb (OB),
	anterior nucleus (AON), and prepyriform cortex (PC). Each part consists
	of a mass of excitatory or inhibitory neurons that is modelled in
	its noninteractive state by a 2nd order ordinary differential equation
	(ODE) having a static nonlinearity. The model is called a KOe or
	a KOi set respectively; it is evaluated in the "open loop" state
	under deep anesthesia. Interactions in waking states are represented
	by coupled KO sets, respectively KIe (mutual excitation) and KIi
	(mutual inhibition). The coupled KIe and KIi sets form a KII set,
	which suffices to represent the dynamics of the OB, AON, and PC separately.
	The coupling of these three structures by both excitatory and inhibitory
	feedback loops forms a KIII set. The solutions to this high-dimensional
	system of ODEs suffice to simulate the chaotic patterns of the EEG,
	including the normal low-level background activity, the high-level
	relatively coherent "bursts" of oscillation that accompany reception
	of input to the bulb, and a degenerate state of an epileptic seizure
	determined by a toroidal chaotic attractor. An example is given of
	the Ruelle-Takens-Newhouse route to chaos in the olfactory system.
	Due to the simplicity and generality of the elements of the model
	and their interconnections, the model can serve as the starting point
	for other neural systems that generate deterministic chaotic activity.},
  keywords = {Animals; Brain, physiology; Central Nervous System, physiology; Electroencephalography;
	Mathematics; Models, Neurological; Neurons, physiology; Olfactory
	Bulb, physiology; Olfactory Pathways, physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {3593783},
  timestamp = {2013.03.28}
}

@BOOK{Freeman_1975book,
  title = {Mass Action in the Nervous System},
  publisher = {ACADEMIC PRESS New York San Francisco London},
  year = {1975},
  author = {Freeman, W. J.},
  owner = {paula},
  timestamp = {2013.03.28}
}

@ARTICLE{Freestone_2011,
  author = {D. R. Freestone and P. Aram and M. Dewar and K. Scerri and D. B.
	Grayden and V. Kadirkamanathan},
  title = {A data-driven framework for neural field modeling.},
  journal = {Neuroimage},
  year = {2011},
  volume = {56},
  pages = {1043--1058},
  number = {3},
  month = {Jun},
  abstract = {This paper presents a framework for creating neural field models from
	electrophysiological data. The Wilson and Cowan or Amari style neural
	field equations are used to form a parametric model, where the parameters
	are estimated from data. To illustrate the estimation framework,
	data is generated using the neural field equations incorporating
	modeled sensors enabling a comparison between the estimated and true
	parameters. To facilitate state and parameter estimation, we introduce
	a method to reduce the continuum neural field model using a basis
	function decomposition to form a finite-dimensional state-space model.
	Spatial frequency analysis methods are introduced that systematically
	specify the basis function configuration required to capture the
	dominant characteristics of the neural field. The estimation procedure
	consists of a two-stage iterative algorithm incorporating the unscented
	Rauch-Tung-Striebel smoother for state estimation and a least squares
	algorithm for parameter estimation. The results show that it is theoretically
	possible to reconstruct the neural field and estimate intracortical
	connectivity structure and synaptic dynamics with the proposed framework.},
  doi = {10.1016/j.neuroimage.2011.02.027},
  institution = {Department of Electrical and Electronic Engineering, University of
	Melbourne, Melbourne, VIC, Australia. dfreestone@bionicear.org},
  keywords = {Algorithms; Cerebral Cortex, physiology; Computer Simulation; Data
	Interpretation, Statistical; Electrophysiological Phenomena; Electrophysiology,
	methods/statistics /&/ numerical data; Humans; Least-Squares Analysis;
	Membrane Potentials, physiology; Models, Neurological; Models, Statistical;
	Monte Carlo Method; Nerve Net, physiology; Neurons, physiology; Nonlinear
	Dynamics; Presynaptic Terminals, physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S1053-8119(11)00183-2},
  pmid = {21329758},
  timestamp = {2013.04.29},
  url = {http://dx.doi.org/10.1016/j.neuroimage.2011.02.027}
}

@ARTICLE{Freestone_2009,
  author = {Dean R Freestone and David B Grayden and Alan Lai and Timothy S Nelson
	and Amy Halliday and Anthony N Burkitt and Mark J Cook},
  title = {The thalamocortical circuit and the generation of epileptic spikes
	in rat models of focal epilepsy.},
  journal = {Conf Proc IEEE Eng Med Biol Soc},
  year = {2009},
  volume = {2009},
  pages = {1533--1536},
  abstract = {We investigate thalamocortical interactions in the tetanus toxin and
	the cortical stimulation rat models of epilepsy. Using local field
	potential recordings from the cortex and the thalamus of the rat,
	the nonlinear regression index is calculated to create the direction
	index in order to study neurodynamics during seizures. Coarse time-scale
	analysis reveals that the cortex drives the thalamus for the majority
	of the time during seizures. However, fine time-scale analysis provides
	evidence that epileptic spikes are driven from the thalamus. This
	new result has implications for understanding, diagnosing and using
	electrical stimulation to treat epileptic seizures.},
  doi = {10.1109/IEMBS.2009.5333073},
  institution = {Department of Electrical and Electronic Engineering, University of
	Melbourne and The Bionic Ear Institute, 384 Albert St, East Melbourne,
	Victoria, 3002, Australia. dfreestone@bionicear.org},
  keywords = {Action Potentials; Animals; Disease Models, Animal; Epilepsy, physiopathology;
	Rats; Thalamus, physiopathology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {19963756},
  timestamp = {2013.04.29},
  url = {http://dx.doi.org/10.1109/IEMBS.2009.5333073}
}

@ARTICLE{Freyer_2009,
  author = {Frank Freyer and Kevin Aquino and Peter A Robinson and Petra Ritter
	and Michael Breakspear},
  title = {Bistability and non-Gaussian fluctuations in spontaneous cortical
	activity.},
  journal = {J. Neurosci.},
  year = {2009},
  volume = {29},
  pages = {8512--8524},
  number = {26},
  month = {Jul},
  abstract = {The brain is widely assumed to be a paradigmatic example of a complex,
	self-organizing system. As such, it should exhibit the classic hallmarks
	of nonlinearity, multistability, and "nondiffusivity" (large coherent
	fluctuations). Surprisingly, at least at the very large scale of
	neocortical dynamics, there is little empirical evidence to support
	this, and hence most computational and methodological frameworks
	for healthy brain activity have proceeded very reasonably from a
	purely linear and diffusive perspective. By studying the temporal
	fluctuations of power in human resting-state electroencephalograms,
	we show that, although these simple properties may hold true at some
	temporal scales, there is strong evidence for bistability and nondiffusivity
	in key brain rhythms. Bistability is manifest as nonclassic bursting
	between high- and low-amplitude modes in the alpha rhythm. Nondiffusivity
	is expressed through the irregular appearance of high amplitude "extremal"
	events in beta rhythm power fluctuations. The statistical robustness
	of these observations was confirmed through comparison with Gaussian-rendered
	phase-randomized surrogate data. Although there is a good conceptual
	framework for understanding bistability in cortical dynamics, the
	implications of the extremal events challenge existing frameworks
	for understanding large-scale brain systems.},
  doi = {10.1523/JNEUROSCI.0754-09.2009},
  institution = {Berlin Neuroimaging Center and Department of Neurology, Charité Universitaetsmedizin,
	Berlin, Germany.},
  keywords = {Adult; Bayes Theorem; Brain Mapping; Cerebral Cortex, blood supply/physiology;
	Electroencephalography, methods; Female; Humans; Image Processing,
	Computer-Assisted, methods; Magnetic Resonance Imaging, methods;
	Male; Models, Neurological; Models, Statistical; Nonlinear Dynamics;
	Normal Distribution; Oxygen, blood; Principal Component Analysis;
	Rest, physiology; Spectrum Analysis; Stochastic Processes; Time Factors;
	Young Adult},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {29/26/8512},
  pmid = {19571142},
  timestamp = {2013.02.18},
  url = {http://dx.doi.org/10.1523/JNEUROSCI.0754-09.2009}
}

@ARTICLE{Freyer_2012a,
  author = {Frank Freyer and Matthias Reinacher and Guido Nolte and Hubert R
	Dinse and Petra Ritter},
  title = {Repetitive tactile stimulation changes resting-state functional connectivity-implications
	for treatment of sensorimotor decline.},
  journal = {Front. Hum. Neurosci.},
  year = {2012},
  volume = {6},
  pages = {144},
  abstract = {Neurological disorders and physiological aging can lead to a decline
	of perceptual abilities. In contrast to the conventional therapeutic
	approach that comprises intensive training and practicing, passive
	repetitive sensory stimulation (RSS) has recently gained increasing
	attention as an alternative to countervail the sensory decline by
	improving perceptual abilities without the need of active participation.
	A particularly effective type of high-frequency RSS, utilizing Hebbian
	learning principles, improves perceptual acuity as well as sensorimotor
	functions and has been successfully applied to treat chronic stroke
	patients and elderly subjects. High-frequency RSS has been shown
	to induce plastic changes of somatosensory cortex such as representational
	map reorganization, but its impact on the brain's ongoing network
	activity and resting-state functional connectivity has not been investigated
	so far. Here, we applied high-frequency RSS in healthy human subjects
	and analyzed resting state Electroencephalography (EEG) functional
	connectivity patterns before and after RSS by means of imaginary
	coherency (ImCoh), a frequency-specific connectivity measure which
	is known to reduce over-estimation biases due to volume conduction
	and common reference. Thirty minutes of passive high-frequency RSS
	lead to significant ImCoh-changes of the resting state mu-rhythm
	in the individual upper alpha frequency band within distributed sensory
	and motor cortical areas. These stimulation induced distributed functional
	connectivity changes likely underlie the previously observed improvement
	in sensorimotor integration.},
  doi = {10.3389/fnhum.2012.00144},
  institution = {Bernstein Focus State Dependencies of Learning and Bernstein Center
	for Computational Neuroscience Berlin, Germany.},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {22654748},
  timestamp = {2012.11.27},
  url = {http://dx.doi.org/10.3389/fnhum.2012.00144}
}

@ARTICLE{Freyer_2011,
  author = {Frank Freyer and James A Roberts and Robert Becker and Peter A Robinson
	and Petra Ritter and Michael Breakspear},
  title = {Biophysical mechanisms of multistability in resting-state cortical
	rhythms.},
  journal = {J. Neurosci.},
  year = {2011},
  volume = {31},
  pages = {6353--6361},
  number = {17},
  month = {Apr},
  abstract = {The human alpha (8-12 Hz) rhythm is one of the most prominent, robust,
	and widely studied attributes of ongoing cortical activity. Contrary
	to the prevalent notion that it simply "waxes and wanes," spontaneous
	alpha activity bursts erratically between two distinct modes of activity.
	We now establish a mechanism for this multistable phenomenon in resting-state
	cortical recordings by characterizing the complex dynamics of a biophysical
	model of macroscopic corticothalamic activity. This is achieved by
	studying the predicted activity of cortical and thalamic neuronal
	populations in this model as a function of its dynamic stability
	and the role of nonspecific synaptic noise. We hence find that fluctuating
	noisy inputs into thalamic neurons elicit spontaneous bursts between
	low- and high-amplitude alpha oscillations when the system is near
	a particular type of dynamical instability, namely a subcritical
	Hopf bifurcation. When the postsynaptic potentials associated with
	these noisy inputs are modulated by cortical feedback, the SD of
	power within each of these modes scale in proportion to their mean,
	showing remarkable concordance with empirical data. Our state-dependent
	corticothalamic model hence exhibits multistability and scale-invariant
	fluctuations-key features of resting-state cortical activity and
	indeed, of human perception, cognition, and behavior-thus providing
	a unified account of these apparently divergent phenomena.},
  doi = {10.1523/JNEUROSCI.6693-10.2011},
  institution = {Bernstein Focus State Dependencies of Learning and Bernstein Center
	for Computational Neuroscience, 10115 Berlin, Germany.},
  keywords = {Alpha Rhythm, physiology; Biophysical Processes, physiology; Cerebral
	Cortex, cytology/physiology; Electroencephalography, methods; Humans;
	Models, Neurological; Neural Pathways, physiology; Neurons, physiology;
	Probability; Rest, physiology; Thalamus, cytology/physiology; Time
	Factors},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {31/17/6353},
  pmid = {21525275},
  timestamp = {2013.02.18},
  url = {http://dx.doi.org/10.1523/JNEUROSCI.6693-10.2011}
}

@ARTICLE{Freyer_2012,
  author = {Frank Freyer and James A Roberts and Petra Ritter and Michael Breakspear},
  title = {A canonical model of multistability and scale-invariance in biological
	systems.},
  journal = {PLoS Comput. Biol.},
  year = {2012},
  volume = {8},
  pages = {e1002634},
  number = {8},
  month = {Aug},
  abstract = {Multistability and scale-invariant fluctuations occur in a wide variety
	of biological organisms from bacteria to humans as well as financial,
	chemical and complex physical systems. Multistability refers to noise
	driven switches between multiple weakly stable states. Scale-invariant
	fluctuations arise when there is an approximately constant ratio
	between the mean and standard deviation of a system's fluctuations.
	Both are an important property of human perception, movement, decision
	making and computation and they occur together in the human alpha
	rhythm, imparting it with complex dynamical behavior. Here, we elucidate
	their fundamental dynamical mechanisms in a canonical model of nonlinear
	bifurcations under stochastic fluctuations. We find that the co-occurrence
	of multistability and scale-invariant fluctuations mandates two important
	dynamical properties: Multistability arises in the presence of a
	subcritical Hopf bifurcation, which generates co-existing attractors,
	whilst the introduction of multiplicative (state-dependent) noise
	ensures that as the system jumps between these attractors, fluctuations
	remain in constant proportion to their mean and their temporal statistics
	become long-tailed. The simple algebraic construction of this model
	affords a systematic analysis of the contribution of stochastic and
	nonlinear processes to cortical rhythms, complementing a recently
	proposed biophysical model. Similar dynamics also occur in a kinetic
	model of gene regulation, suggesting universality across a broad
	class of biological phenomena.},
  doi = {10.1371/journal.pcbi.1002634},
  institution = { Bernstein Center for Computational Neuroscience, Berlin, Germany.},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {PCOMPBIOL-D-12-00002},
  pmid = {22912567},
  timestamp = {2012.11.27},
  url = {http://dx.doi.org/10.1371/journal.pcbi.1002634}
}

@ARTICLE{Friston_2012,
  author = {Karl Friston},
  title = {The history of the future of the Bayesian brain.},
  journal = {Neuroimage},
  year = {2012},
  volume = {62},
  pages = {1230--1233},
  number = {2},
  month = {Aug},
  abstract = {The slight perversion of the original title of this piece (The Future
	of the Bayesian Brain) reflects my attempt to write prospectively
	about 'Science and Stories' over the past 20 years. I will meet this
	challenge by dealing with the future and then turning to its history.
	The future of the Bayesian brain (in neuroimaging) is clear: it is
	the application of dynamic causal modeling to understand how the
	brain conforms to the free energy principle. In this context, the
	Bayesian brain is a corollary of the free energy principle, which
	says that any self organizing system (like a brain or neuroimaging
	community) must maximize the evidence for its own existence, which
	means it must minimize its free energy using a model of its world.
	Dynamic causal modeling involves finding models of the brain that
	have the greatest evidence or the lowest free energy. In short, the
	future of imaging neuroscience is to refine models of the brain to
	minimize free energy, where the brain refines models of the world
	to minimize free energy. This endeavor itself minimizes free energy
	because our community is itself a self organizing system. I cannot
	imagine an alternative future that has the same beautiful self consistency
	as mine. Having dispensed with the future, we can now focus on the
	past, which is much more interesting:},
  doi = {10.1016/j.neuroimage.2011.10.004},
  institution = {The Wellcome Trust Centre for Neuroimaging, UCL, 12 Queen Square,
	London WC1N 3BG, UK. k.friston@fil.ion.ucl.ac.uk},
  keywords = {Animals; Bayes Theorem; Brain, physiology; History, 20th Century;
	History, 21st Century; Humans; Models, Neurological; Neuroimaging,
	history/trends; Neurosciences, history/trends},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S1053-8119(11)01165-7},
  pmid = {22023743},
  timestamp = {2013.04.11},
  url = {http://dx.doi.org/10.1016/j.neuroimage.2011.10.004}
}

@ARTICLE{Friston_2011,
  author = {Karl Friston},
  title = {Dynamic causal modeling and Granger causality Comments on: the identification
	of interacting networks in the brain using fMRI: model selection,
	causality and deconvolution.},
  journal = {Neuroimage},
  year = {2011},
  volume = {58},
  pages = {303--5; author reply 310-1},
  number = {2},
  month = {Sep},
  doi = {10.1016/j.neuroimage.2009.09.031},
  institution = {The Wellcome Trust Centre for Neuroimaging, Institute of Neurology,
	UCL, 12 Queen Square, London, WC1N 3BG, UK. k.friston@fil.ion.ucl.ac.uk},
  keywords = {Brain, physiology; Causality; Humans; Magnetic Resonance Imaging,
	methods; Models, Neurological; Nerve Net, physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S1053-8119(09)01010-6},
  pmid = {19770049},
  timestamp = {2013.04.11},
  url = {http://dx.doi.org/10.1016/j.neuroimage.2009.09.031}
}

@ARTICLE{Friston_2003,
  author = {Friston, KJ and Harrison, L and Penny, W},
  title = {Dynamic causal modelling},
  journal = {Neuroimage},
  year = {2003},
  volume = {19},
  pages = {1273-1302},
  owner = {paula},
  timestamp = {2012.10.18}
}

@ARTICLE{Friston_1995,
  author = {K.J. Friston and A.P. Holmes and K.J. Worsley and J.B. Poline and
	C.D. Frith and R.S.J. Frackowiak},
  title = {Statistical Parametric Maps in functional imaging: A general linear
	approach.},
  journal = {Hum. Brain Mapp.},
  year = {1995},
  volume = {2},
  pages = {189-210},
  owner = {paula},
  timestamp = {2013.04.11}
}

@ARTICLE{Friston_2012a,
  author = {K. J. Friston and A. Bastos and V. Litvak and K. E. Stephan and P.
	Fries and R. J. Moran},
  title = {DCM for complex-valued data: cross-spectra, coherence and phase-delays.},
  journal = {Neuroimage},
  year = {2012},
  volume = {59},
  pages = {439--455},
  number = {1},
  month = {Jan},
  abstract = {This note describes an extension of Bayesian model inversion procedures
	for the Dynamic Causal Modeling (DCM) of complex-valued data. Modeling
	complex data can be particularly useful in the analysis of multivariate
	ergodic (stationary) time-series. We illustrate this with a generalization
	of DCM for steady-state responses that models both the real and imaginary
	parts of sample cross-spectra. DCM allows one to infer underlying
	biophysical parameters generating data (like synaptic time constants,
	connection strengths and conduction delays). Because transfer functions
	and complex cross-spectra can be generated from these parameters,
	one can also describe the implicit system architecture in terms of
	conventional (linear systems) measures; like coherence, phase-delay
	or cross-correlation functions. Crucially, these measures can be
	derived in both sensor and source-space. In other words, one can
	examine the cross-correlation or phase-delay functions between hidden
	neuronal sources using non-invasive data and relate these functions
	to synaptic parameters and neuronal conduction delays. We illustrate
	these points using local field potential recordings from the subthalamic
	nucleus and globus pallidus, with a special focus on the relationship
	between conduction delays and the ensuing phase relationships and
	cross-correlation time lags between population activities.},
  doi = {10.1016/j.neuroimage.2011.07.048},
  institution = {The Wellcome Trust Centre for Neuroimaging, University College London,
	Queen Square, London WC1N 3BG, UK.},
  keywords = {Algorithms; Bayes Theorem; Brain Mapping, methods; Brain, physiology;
	Humans; Models, Neurological; Models, Theoretical},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S1053-8119(11)00825-1},
  pmid = {21820062},
  timestamp = {2013.04.11},
  url = {http://dx.doi.org/10.1016/j.neuroimage.2011.07.048}
}

@ARTICLE{Friston_1995a,
  author = {Friston, K. J. and Holmes, A. P. and Poline, J. B. and Grasby, P.
	J. and Williams, S. C. and Frackowiak, R. S. and Turner, R.},
  title = {Analysis of fMRI time-series revisited.},
  journal = {Neuroimage},
  year = {1995},
  volume = {2},
  pages = {45--53},
  number = {1},
  month = {Mar},
  abstract = {This paper presents a general approach to the analysis of functional
	MRI time-series from one or more subjects. The approach is predicated
	on an extension of the general linear model that allows for correlations
	between error terms due to physiological noise or correlations that
	ensue after temporal smoothing. This extension uses the effective
	degrees of freedom associated with the error term. The effective
	degrees of freedom are a simple function of the number of scans and
	the temporal auto correlation function. A specific form for the latter
	can be assumed if the data are smoothed, in time, to accentuate hemodynamic
	responses with a neural basis. This assumption leads to an expedient
	implementation of a flexible statistical framework. The importance
	of this small extension is that, in contradistinction to our previous
	approach, any parametric statistical analysis can be implemented.
	We demonstrate this point using a multiple regression analysis that
	tests for effects of interest (activations due to word generation),
	while taking explicit account of some obvious confounds.},
  doi = {10.1006/nimg.1995.1007},
  institution = {Wellcome Department of Cognitive Neurology, Institute of Neurology,
	United Kingdom.},
  keywords = {Arousal, physiology; Artifacts; Brain Mapping; Brain, blood supply/physiology;
	Hemodynamics, physiology; Humans; Image Processing, Computer-Assisted;
	Linear Models; Magnetic Resonance Imaging; Nerve Net, physiology;
	Reference Values; Regional Blood Flow, physiology; Sensitivity and
	Specificity},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paupau},
  pii = {S1053-8119(85)71007-5},
  pmid = {9343589},
  timestamp = {2013.08.21},
  url = {http://dx.doi.org/10.1006/nimg.1995.1007}
}

@OTHER{Friston_1994,
  abstract = { A method for detecting significant and regionally specific correlations
	between sensory input and the brain&#039;s physiological response,
	as measured with functional magnetic resonance imaging (MRI), is
	presented in this paper. The method involves testing for correlations
	between sensory input and the hemodynamic response after convolving
	the sensory input with an estimate of the hernodynamic response function.
	This estimate is obtained without reference to any assumed input.
	To lend the approach statistical validity, it is brought into the
	framework of statistical parametric mapping by using a measure of
	cross-correlations between sensory input and hemodynamic response
	that is valid in the presence of intrinsic autocorrelations. These
	autocorrelations are necessarily present, due to the hemodynamic
	response function or temporal point spread function. },
  author = {Friston, K. J. and Jezzard, P. and Turner, R.},
  owner = {paupau},
  timestamp = {2013.08.21},
  title = {Analysis of Functional MRI Time-Series},
  year = {1994}
}

@ARTICLE{Friston_2000,
  author = {K. J. Friston and A. Mechelli and R. Turner and C. J. Price},
  title = {Nonlinear responses in fMRI: the Balloon model, Volterra kernels,
	and other hemodynamics.},
  journal = {Neuroimage},
  year = {2000},
  volume = {12},
  pages = {466--477},
  number = {4},
  month = {Oct},
  abstract = {There is a growing appreciation of the importance of nonlinearities
	in evoked responses in fMRI, particularly with the advent of event-related
	fMRI. These nonlinearities are commonly expressed as interactions
	among stimuli that can lead to the suppression and increased latency
	of responses to a stimulus that are incurred by a preceding stimulus.
	We have presented previously a model-free characterization of these
	effects using generic techniques from nonlinear system identification,
	namely a Volterra series formulation. At the same time Buxton et
	al. (1998) described a plausible and compelling dynamical model of
	hemodynamic signal transduction in fMRI. Subsequent work by Mandeville
	et al. (1999) provided important theoretical and empirical constraints
	on the form of the dynamic relationship between blood flow and volume
	that underpins the evolution of the fMRI signal. In this paper we
	combine these system identification and model-based approaches and
	ask whether the Balloon model is sufficient to account for the nonlinear
	behaviors observed in real time series. We conclude that it can,
	and furthermore the model parameters that ensue are biologically
	plausible. This conclusion is based on the observation that the Balloon
	model can produce Volterra kernels that emulate empirical kernels.
	To enable this evaluation we had to embed the Balloon model in a
	hemodynamic input-state-output model that included the dynamics of
	perfusion changes that are contingent on underlying synaptic activation.
	This paper presents (i) the full hemodynamic model (ii), how its
	associated Volterra kernels can be derived, and (iii) addresses the
	model's validity in relation to empirical nonlinear characterizations
	of evoked responses in fMRI and other neurophysiological constraints.},
  doi = {10.1006/nimg.2000.0630},
  institution = {The Wellcome Department of Cognitive Neurology, Institute of Neurology,
	Queen Square, London WC1N 3BG, United Kingdom.},
  keywords = {Brain, physiology; Cerebrovascular Circulation, physiology; Hemodynamics,
	physiology; Magnetic Resonance Imaging; Models, Cardiovascular; Models,
	Neurological; Nonlinear Dynamics},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paupau},
  pii = {S1053-8119(00)90630-X},
  pmid = {10988040},
  timestamp = {2013.02.24},
  url = {http://dx.doi.org/10.1006/nimg.2000.0630}
}

@ARTICLE{Friston_2005,
  author = {Karl J Friston and William Penny and Olivier David},
  title = {Modeling brain responses.},
  journal = {Int. Rev. Neurobiol.},
  year = {2005},
  volume = {66},
  pages = {89--124},
  doi = {10.1016/S0074-7742(05)66003-5},
  institution = {The Wellcome Department of Cognitive Neurology, University College
	London, London WC1N 3BG, United Kingdom.},
  keywords = {Brain, physiology; Humans; Models, Neurological},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S0074-7742(05)66003-5},
  pmid = {16387201},
  timestamp = {2013.02.21},
  url = {http://dx.doi.org/10.1016/S0074-7742(05)66003-5}
}

@ARTICLE{Fung_2013a,
  author = {P. K. Fung and A. L. Haber and P. A. Robinson},
  title = {Neural field theory of plasticity in the cerebral cortex.},
  journal = {J. Theor. Biol.},
  year = {2013},
  volume = {318},
  pages = {44--57},
  month = {Feb},
  abstract = {A generalized timing-dependent plasticity rule is incorporated into
	a recent neural field theory to explore synaptic plasticity in the
	cerebral cortex, with both excitatory and inhibitory populations
	included. Analysis in the time and frequency domains reveals that
	cortical network behavior gives rise to a saddle-node bifurcation
	and resonant frequencies, including a gamma-band resonance. These
	system resonances constrain cortical synaptic dynamics and divide
	it into four classes, which depend on the type of synaptic plasticity
	window. Depending on the dynamical class, synaptic strengths can
	either have a stable fixed point, or can diverge in the absence of
	a separate saturation mechanism. Parameter exploration shows that
	time-asymmetric plasticity windows, which are signatures of spike-timing
	dependent plasticity, enable the richest variety of synaptic dynamics
	to occur. In particular, we predict a zone in parameter space which
	may allow brains to attain the marginal stability phenomena observed
	experimentally, although additional regulatory mechanisms may be
	required to maintain these parameters.},
  doi = {10.1016/j.jtbi.2012.09.030},
  institution = {School of Physics, The University of Sydney, NSW 2006, Australia.
	F.Fung@physics.usyd.edu.au},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S0022-5193(12)00508-5},
  pmid = {23036915},
  timestamp = {2013.03.25},
  url = {http://dx.doi.org/10.1016/j.jtbi.2012.09.030}
}

@ARTICLE{Fung_2013,
  author = {P. K. Fung and P. A. Robinson},
  title = {Neural field theory of calcium dependent plasticity with applications
	to transcranial magnetic stimulation.},
  journal = {J. Theor. Biol.},
  year = {2013},
  volume = {324C},
  pages = {72--83},
  month = {Feb},
  abstract = {Calcium dependent plasticity (CaDP), a physiologically realistic plasticity
	mechanism in the microscopic regime, is incorporated into a neural
	field theory to explore system-level plasticity. This system-level
	plasticity model is capable of reproducing the characteristic plasticity
	window of spike-timing dependent plasticity (STDP) in paired associative
	stimulation (PAS), where a peripheral electric pulse stimulation
	is paired to transcranial magnetic stimulation (TMS) in the cortex,
	and rTMS frequency dependent plasticity, where low and high frequency
	rTMS trains induce depression and potentiation, respectively. These
	thus reproduce experimental results for system-level plasticity for
	the first time. This also bridges the gap between microscopic plasticity
	theory and system-level plasticity observed experimentally, and addresses
	long standing problems of stability and adaptability by predicting
	stable plasticity, a possible seizure state where neurons fire at
	a high rate, and spike-rate adaptation.},
  doi = {10.1016/j.jtbi.2013.01.013},
  institution = {School of Physics, The University of Sydney, NSW 2006, Australia;
	Brain Dynamics Center, Sydney Medical School, Western, The University
	of Sydney, Westmead, NSW 2145, Australia. Electronic address: F.Fung@physics.usyd.edu.au.},
  language = {eng},
  medline-pst = {aheadofprint},
  owner = {paula},
  pii = {S0022-5193(13)00038-6},
  pmid = {23376643},
  timestamp = {2013.03.25},
  url = {http://dx.doi.org/10.1016/j.jtbi.2013.01.013}
}

@ARTICLE{Galan_2007,
  author = {Roberto F Galán and G. Bard Ermentrout and Nathaniel N Urban},
  title = {Stochastic dynamics of uncoupled neural oscillators: Fokker-Planck
	studies with the finite element method.},
  journal = {Phys Rev E Stat Nonlin Soft Matter Phys},
  year = {2007},
  volume = {76},
  pages = {056110},
  number = {5 Pt 2},
  month = {Nov},
  abstract = {We have investigated the effect of the phase response curve on the
	dynamics of oscillators driven by noise in two limit cases that are
	especially relevant for neuroscience. Using the finite element method
	to solve the Fokker-Planck equation we have studied (i) the impact
	of noise on the regularity of the oscillations quantified as the
	coefficient of variation, (ii) stochastic synchronization of two
	uncoupled phase oscillators driven by correlated noise, and (iii)
	their cross-correlation function. We show that, in general, the limit
	of type II oscillators is more robust to noise and more efficient
	at synchronizing by correlated noise than type I.},
  institution = {Department of Biological Sciences, Carnegie Mellon University, Pittsburgh,
	Pennsylvania 15213, USA. galan@cnbc.cmu.edu},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {18233721},
  timestamp = {2013.09.04}
}

@ARTICLE{Gardner_2008,
  author = {Daniel Gardner and Huda Akil and Giorgio A Ascoli and Douglas M Bowden
	and William Bug and Duncan E Donohue and David H Goldberg and Bernice
	Grafstein and Jeffrey S Grethe and Amarnath Gupta and Maryam Halavi
	and David N Kennedy and Luis Marenco and Maryann E Martone and Perry
	L Miller and Hans-Michael Müller and Adrian Robert and Gordon M Shepherd
	and Paul W Sternberg and David C Van Essen and Robert W Williams},
  title = {The neuroscience information framework: a data and knowledge environment
	for neuroscience.},
  journal = {Neuroinformatics},
  year = {2008},
  volume = {6},
  pages = {149--160},
  number = {3},
  month = {Sep},
  abstract = {With support from the Institutes and Centers forming the NIH Blueprint
	for Neuroscience Research, we have designed and implemented a new
	initiative for integrating access to and use of Web-based neuroscience
	resources: the Neuroscience Information Framework. The Framework
	arises from the expressed need of the neuroscience community for
	neuroinformatic tools and resources to aid scientific inquiry, builds
	upon prior development of neuroinformatics by the Human Brain Project
	and others, and directly derives from the Society for Neuroscience's
	Neuroscience Database Gateway. Partnered with the Society, its Neuroinformatics
	Committee, and volunteer consultant-collaborators, our multi-site
	consortium has developed: (1) a comprehensive, dynamic, inventory
	of Web-accessible neuroscience resources, (2) an extended and integrated
	terminology describing resources and contents, and (3) a framework
	accepting and aiding concept-based queries. Evolving instantiations
	of the Framework may be viewed at http://nif.nih.gov , http://neurogateway.org
	, and other sites as they come on line.},
  doi = {10.1007/s12021-008-9024-z},
  institution = {Laboratory of Neuroinformatics and Department of Physiology, Weill
	Medical College, Cornell University, 1300 York Avenue, New York,
	NY, 10065, USA. dan@med.cornell.edu},
  keywords = {Academic Medical Centers, trends; Access to Information; Animals;
	Computational Biology, organization /&/ administration/trends; Databases
	as Topic; Humans; Internet, organization /&/ administration/trends;
	Meta-Analysis as Topic; National Institutes of Health (U.S.), organization
	/&/ administration/trends; Neurosciences, organization /&/ administration/trends;
	Software, trends; United States},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {18946742},
  timestamp = {2012.12.27},
  url = {http://dx.doi.org/10.1007/s12021-008-9024-z}
}

@ARTICLE{Gerhard_2011,
  author = {Stephan Gerhard and Alessandro Daducci and Alia Lemkaddem and Reto
	Meuli and Jean-Philippe Thiran and Patric Hagmann},
  title = {The connectome viewer toolkit: an open source framework to manage,
	analyze, and visualize connectomes.},
  journal = {Front. Neuroinform.},
  year = {2011},
  volume = {5},
  pages = {3},
  abstract = {Advanced neuroinformatics tools are required for methods of connectome
	mapping, analysis, and visualization. The inherent multi-modality
	of connectome datasets poses new challenges for data organization,
	integration, and sharing. We have designed and implemented the Connectome
	Viewer Toolkit - a set of free and extensible open source neuroimaging
	tools written in Python. The key components of the toolkit are as
	follows: (1) The Connectome File Format is an XML-based container
	format to standardize multi-modal data integration and structured
	metadata annotation. (2) The Connectome File Format Library enables
	management and sharing of connectome files. (3) The Connectome Viewer
	is an integrated research and development environment for visualization
	and analysis of multi-modal connectome data. The Connectome Viewer's
	plugin architecture supports extensions with network analysis packages
	and an interactive scripting shell, to enable easy development and
	community contributions. Integration with tools from the scientific
	Python community allows the leveraging of numerous existing libraries
	for powerful connectome data mining, exploration, and comparison.
	We demonstrate the applicability of the Connectome Viewer Toolkit
	using Diffusion MRI datasets processed by the Connectome Mapper.
	The Connectome Viewer Toolkit is available from http://www.cmtk.org/},
  doi = {10.3389/fninf.2011.00003},
  institution = {Signal Processing Laboratory 5, Ecole Polytechnique Fédérale de Lausanne
	Lausanne, Switzerland.},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {21713110},
  timestamp = {2012.12.26},
  url = {http://dx.doi.org/10.3389/fninf.2011.00003}
}

@ARTICLE{Gewaltig_2007scholarpedia,
  author = {Gewaltig, M and Diesmann, M.},
  title = {{NEST} (Neural Simulation Tool)},
  journal = {Scholarpedia},
  year = {2007},
  volume = {2},
  pages = {1430},
  number = {4},
  owner = {paula},
  timestamp = {2013.05.13}
}

@ARTICLE{Ghosh_2008,
  author = {Ghosh, A and Rho, Y and McIntosh, AR and Kötter, R and Jirsa, VK},
  title = {Noise during Rest Enables the Exploration of the Brain's Dynamic
	Repertoire},
  journal = {PLoS Comput. Biol.},
  year = {2008},
  volume = {4},
  pages = {e1000196-e1000196},
  number = {10},
  month = {October},
  doi = {doi:10.1371/journal.pcbi.1000196},
  owner = {paula},
  timestamp = {2012.10.25}
}

@ARTICLE{Ghosh_2012,
  author = {Satrajit S Ghosh and Arno Klein and Brian Avants and K. Jarrod Millman},
  title = {Learning from open source software projects to improve scientific
	review.},
  journal = {Front. Comput. Neurosci.},
  year = {2012},
  volume = {6},
  pages = {18},
  abstract = {Peer-reviewed publications are the primary mechanism for sharing scientific
	results. The current peer-review process is, however, fraught with
	many problems that undermine the pace, validity, and credibility
	of science. We highlight five salient problems: (1) reviewers are
	expected to have comprehensive expertise; (2) reviewers do not have
	sufficient access to methods and materials to evaluate a study; (3)
	reviewers are neither identified nor acknowledged; (4) there is no
	measure of the quality of a review; and (5) reviews take a lot of
	time, and once submitted cannot evolve. We propose that these problems
	can be resolved by making the following changes to the review process.
	Distributing reviews to many reviewers would allow each reviewer
	to focus on portions of the article that reflect the reviewer's specialty
	or area of interest and place less of a burden on any one reviewer.
	Providing reviewers materials and methods to perform comprehensive
	evaluation would facilitate transparency, greater scrutiny, and replication
	of results. Acknowledging reviewers makes it possible to quantitatively
	assess reviewer contributions, which could be used to establish the
	impact of the reviewer in the scientific community. Quantifying review
	quality could help establish the importance of individual reviews
	and reviewers as well as the submitted article. Finally, we recommend
	expediting post-publication reviews and allowing for the dialog to
	continue and flourish in a dynamic and interactive manner. We argue
	that these solutions can be implemented by adapting existing features
	from open-source software management and social networking technologies.
	We propose a model of an open, interactive review system that quantifies
	the significance of articles, the quality of reviews, and the reputation
	of reviewers.},
  doi = {10.3389/fncom.2012.00018},
  institution = {McGovern Institute for Brain Research, Massachusetts Institute of
	Technology, Cambridge MA, USA.},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {22529798},
  timestamp = {2013.02.21},
  url = {http://dx.doi.org/10.3389/fncom.2012.00018}
}

@ARTICLE{Giaume_2010,
  author = {Giaume, C and Koulakoff, A and Roux, L and Holcman, D and Rouach,
	N},
  title = {Astroglial networks: a step further in neuroglial and gliovascular
	interactions},
  journal = {Nat. Rev. Neurosci.},
  year = {2010},
  volume = {11},
  pages = {87-99},
  number = {2},
  keywords = {neural network, neuroglia},
  owner = {paula},
  review = {Dynamic aspects of interactions between astrocytes, neurons and the
	vasculature have recently been in the neuroscience spotlight. It
	has emerged that not only neurons but also astrocytes are organized
	into networks. Whereas neuronal networks exchange information through
	electrical and chemical synapses, astrocytes are interconnected through
	gapjunction channels that are regulated by extra- and intracellular
	signals and allow exchange of information. This intercellular communication
	between glia has implications for neuroglial and gliovascular interactions
	and hence has added another level of complexity to our understanding
	of brain function.},
  timestamp = {2012.10.18}
}

@ARTICLE{Glasser_2011,
  author = {Matthew F Glasser and David C Van Essen},
  title = {Mapping human cortical areas in vivo based on myelin content as revealed
	by T1- and T2-weighted MRI.},
  journal = {J Neurosci},
  year = {2011},
  volume = {31},
  pages = {11597--11616},
  number = {32},
  month = {Aug},
  abstract = {Noninvasively mapping the layout of cortical areas in humans is a
	continuing challenge for neuroscience. We present a new method of
	mapping cortical areas based on myelin content as revealed by T1-weighted
	(T1w) and T2-weighted (T2w) MRI. The method is generalizable across
	different 3T scanners and pulse sequences. We use the ratio of T1w/T2w
	image intensities to eliminate the MR-related image intensity bias
	and enhance the contrast to noise ratio for myelin. Data from each
	subject were mapped to the cortical surface and aligned across individuals
	using surface-based registration. The spatial gradient of the group
	average myelin map provides an observer-independent measure of sharp
	transitions in myelin content across the surface--i.e., putative
	cortical areal borders. We found excellent agreement between the
	gradients of the myelin maps and the gradients of published probabilistic
	cytoarchitectonically defined cortical areas that were registered
	to the same surface-based atlas. For other cortical regions, we used
	published anatomical and functional information to make putative
	identifications of dozens of cortical areas or candidate areas. In
	general, primary and early unimodal association cortices are heavily
	myelinated and higher, multimodal, association cortices are more
	lightly myelinated, but there are notable exceptions in the literature
	that are confirmed by our results. The overall pattern in the myelin
	maps also has important correlations with the developmental onset
	of subcortical white matter myelination, evolutionary cortical areal
	expansion in humans compared with macaques, postnatal cortical expansion
	in humans, and maps of neuronal density in non-human primates.},
  doi = {10.1523/JNEUROSCI.2180-11.2011},
  institution = {Department of Anatomy and Neurobiology, Washington University School
	of Medicine, St. Louis, Missouri 63110, USA.},
  keywords = {Adolescent; Adult; Brain Mapping, methods; Cerebral Cortex, physiology;
	Female; Humans; Image Processing, Computer-Assisted, methods; Magnetic
	Resonance Imaging, methods; Male; Middle Aged; Myelin Sheath, physiology;
	Nerve Fibers, Myelinated, physiology; Young Adult},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {31/32/11597},
  pmid = {21832190},
  timestamp = {2013.07.04},
  url = {http://dx.doi.org/10.1523/JNEUROSCI.2180-11.2011}
}

@ARTICLE{Glasser_2013a,
  author = {Matthew F Glasser and Manu S Goyal and Todd M Preuss and Marcus E
	Raichle and David C Van Essen},
  title = {Trends and properties of human cerebral cortex: Correlations with
	cortical myelin content.},
  journal = {Neuroimage},
  year = {2013},
  volume = {--},
  pages = {--},
  month = {Apr},
  abstract = {"In vivo Brodmann mapping" or non-invasive cortical parcellation using
	MRI, especially by measuring cortical myelination, has recently become
	a popular research topic, though myeloarchitectonic cortical parcellation
	in humans previously languished in favor of cytoarchitecture. We
	review recent in vivo myelin mapping studies and discuss some of
	the different methods for estimating myelin content. We discuss some
	ways in which myelin maps may improve surface registration and be
	useful for cross-modal and cross-species comparisons, including some
	preliminary cross-species results. Next, we consider neurobiological
	aspects of why some parts of cortex are more myelinated than others.
	Myelin content is inversely correlated with intracortical circuit
	complexity - in general, more myelin content means simpler and perhaps
	less dynamic intracortical circuits. Using existing PET data and
	functional network parcellations, we examine metabolic differences
	in the differently myelinated cortical functional networks. Lightly
	myelinated cognitive association networks tend to have higher aerobic
	glycolysis than heavily myelinated early sensory-motor ones, perhaps
	reflecting greater ongoing dynamic anabolic cortical processes. This
	finding is consistent with the hypothesis that intracortical myelination
	may stabilize intracortical circuits and inhibit synaptic plasticity.
	Finally, we discuss the future of the in vivo myeloarchitectural
	field and cortical parcellation - "in vivo Brodmann mapping" - in
	general.},
  doi = {10.1016/j.neuroimage.2013.03.060},
  institution = {Department of Anatomy and Neurobiology, Washington University School
	of Medicine, 660 S. Euclid Avenue, St. Louis, MO 63110, USA. Electronic
	address: glasserm@wusm.wustl.edu.},
  language = {eng},
  medline-pst = {aheadofprint},
  owner = {paula},
  pii = {S1053-8119(13)00310-8},
  pmid = {23567887},
  timestamp = {2013.07.04},
  url = {http://dx.doi.org/10.1016/j.neuroimage.2013.03.060}
}

@ARTICLE{Glasser_2013,
  author = {Matthew F Glasser and Stamatios N Sotiropoulos and J. Anthony Wilson
	and Timothy S Coalson and Bruce Fischl and Jesper L Andersson and
	Junqian Xu and Saad Jbabdi and Matthew Webster and Jonathan R Polimeni
	and David C Van Essen and Mark Jenkinson and for the WU-Minn HCP
	Consortium},
  title = {The minimal preprocessing pipelines for the Human Connectome Project.},
  journal = {Neuroimage},
  year = {2013},
  volume = {--},
  pages = {--},
  month = {May},
  language = {eng},
  medline-pst = {aheadofprint},
  owner = {paula},
  pmid = {23668970},
  timestamp = {2013.07.04}
}

@MISC{Glickenstein_2008,
  author = {David Glickenstein},
  title = {Geometric triangulations and discrete Laplacians on manifolds },
  year = {2008}
}

@ARTICLE{Glover_1999,
  author = {G. H. Glover},
  title = {Deconvolution of impulse response in event-related BOLD fMRI.},
  journal = {Neuroimage},
  year = {1999},
  volume = {9},
  pages = {416--429},
  number = {4},
  month = {Apr},
  abstract = {The temporal characteristics of the BOLD response in sensorimotor
	and auditory cortices were measured in subjects performing finger
	tapping while listening to metronome pacing tones. A repeated trial
	paradigm was used with stimulus durations of 167 ms to 16 s and intertrial
	times of 30 s. Both cortical systems were found to be nonlinear in
	that the response to a long stimulus could not be predicted by convolving
	the 1-s response with a rectangular function. In the short-time regime,
	the amplitude of the response varied only slowly with stimulus duration.
	It was found that this character was predicted with a modification
	to Buxton's balloon model. Wiener deconvolution was used to deblur
	the response to concatenated short episodes of finger tapping at
	different temporal separations and at rates from 1 to 4 Hz. While
	the measured response curves were distorted by overlap between the
	individual episodes, the deconvolved response at each rate was found
	to agree well with separate scans at each of the individual rates.
	Thus, although the impulse response cannot predict the response to
	fully overlapping stimuli, linear deconvolution is effective when
	the stimuli are separated by at least 4 s. The deconvolution filter
	must be measured for each subject using a short-stimulus paradigm.
	It is concluded that deconvolution may be effective in diminishing
	the hemodynamically imposed temporal blurring and may have potential
	applications in quantitating responses in eventrelated fMRI.},
  institution = { Diagnostic Radiology, Stanford, California, 94305-5488, USA.},
  keywords = {Acoustic Stimulation; Auditory Cortex, physiology; Data Interpretation,
	Statistical; Evoked Potentials, Auditory, physiology; Humans; Image
	Processing, Computer-Assisted; Magnetic Resonance Imaging, methods;
	Nonlinear Dynamics; Oxygen, blood; Somatosensory Cortex, physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S1053811998904190},
  pmid = {10191170},
  timestamp = {2013.08.23}
}

@ARTICLE{Golomb_2002,
  author = {David Golomb and G. Bard Ermentrout},
  title = {Slow excitation supports propagation of slow pulses in networks of
	excitatory and inhibitory populations.},
  journal = {Phys Rev E Stat Nonlin Soft Matter Phys},
  year = {2002},
  volume = {65},
  pages = {061911},
  number = {6 Pt 1},
  month = {Jun},
  abstract = {We study the propagation of traveling solitary pulses in one-dimensional
	networks of excitatory and inhibitory neurons. Each neuron is represented
	by the integrate-and-fire model, and is allowed to fire only one
	spike. Two types of propagating pulses are observed. During fast
	pulses, inhibitory neurons fire a short time before or after the
	excitatory neurons. During slow pulses, inhibitory cells fire well
	before neighboring excitatory cells, and potentials of excitatory
	cells become negative and then positive before they fire. There is
	a bistable parameter regime in which both fast and slow pulses can
	propagate. Fast pulses can propagate at low levels of inhibition,
	are affected by fast excitation but are almost unaffected by slow
	excitation, and are easily elicited by stimulating groups of neurons.
	In contrast, slow pulses can propagate at intermediate levels of
	inhibition, and are difficult to evoke. They can propagate without
	slow excitation, but slow excitation makes their propagation substantially
	more robust. Fast pulses can propagate in a wider parameter regime
	if inhibition decays slowly with time, whereas slow pulses can propagate
	in a wider parameter regime if the passive time constant of inhibitory
	cells is large. Strong inhibitory-to-inhibitory conductance eliminates
	the slow pulses and converts the fast traveling pulses into irregular
	pulses, in which the inhibitory neurons segregate into two groups
	that have different firing delays with respect to their neighboring
	excitatory cells. In general, the velocity of the fast pulse increases
	with the axonal conductance velocity c, but there are cases in which
	it decreases with c. We suggest that the fast and slow pulses observed
	in our model correspond to the fast and slow propagating activity
	observed in experiments on neocortical slices.},
  institution = {Department of Physiology and Zlotowski Center for Neuroscience, Faculty
	of Health Sciences, Ben Gurion University of the Negev, Be'er-Sheva
	84105, Israel.},
  keywords = {Biophysical Phenomena; Biophysics; Electrophysiology; Models, Neurological;
	Models, Statistical; Nerve Net, physiology; Neural Conduction, physiology;
	Neurons, physiology; Synapses, physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {12188763},
  timestamp = {2013.09.04}
}

@ARTICLE{Golomb_1999,
  author = {D. Golomb and G. B. Ermentrout},
  title = {Continuous and lurching traveling pulses in neuronal networks with
	delay and spatially decaying connectivity.},
  journal = {Proc Natl Acad Sci U S A},
  year = {1999},
  volume = {96},
  pages = {13480--13485},
  number = {23},
  month = {Nov},
  abstract = {Propagation of discharges in cortical and thalamic systems, which
	is used as a probe for examining network circuitry, is studied by
	constructing a one-dimensional model of integrate-and-fire neurons
	that are coupled by excitatory synapses with delay. Each neuron fires
	only one spike. The velocity and stability of propagating continuous
	pulses are calculated analytically. Above a certain critical value
	of the constant delay, these pulses lose stability. Instead, lurching
	pulses propagate with discontinuous and periodic spatio-temporal
	characteristics. The parameter regime for which lurching occurs is
	strongly affected by the footprint (connectivity) shape; bistability
	may occur with a square footprint shape but not with an exponential
	footprint shape. For strong synaptic coupling, the velocity of both
	continuous and lurching pulses increases logarithmically with the
	synaptic coupling strength g(syn) for an exponential footprint shape,
	and it is bounded for a step footprint shape. We conclude that the
	differences in velocity and shape between the front of thalamic spindle
	waves in vitro and cortical paroxysmal discharges stem from their
	different effective delay; in thalamic networks, large effective
	delay between inhibitory neurons arises from their effective interaction
	via the excitatory cells which display postinhibitory rebound.},
  institution = {Zlotowski Center for Neuroscience, Department of Physiology, Faculty
	of Health Sciences, Ben-Gurion University of the Negev, Beer-Sheva
	84105, Israel. golomb@bgumail.bgu.ac.il},
  keywords = {Axons, physiology; Cerebral Cortex, physiology; Membrane Potentials;
	Models, Neurological; Nerve Net; Thalamus, physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {10557346},
  timestamp = {2013.09.04}
}

@ARTICLE{Gong_2008,
  author = {Gaolang Gong and Luis Concha and Christian Beaulieu and Donald W
	Gross},
  title = {Thalamic diffusion and volumetry in temporal lobe epilepsy with and
	without mesial temporal sclerosis.},
  journal = {Epilepsy Res},
  year = {2008},
  volume = {80},
  pages = {184--193},
  number = {2-3},
  month = {Aug},
  abstract = {As an important connection within the limbic system, considerable
	attention has been paid to thalamic pathology in temporal lobe epilepsy
	(TLE). Magnetic resonance imaging (MRI) volumetric studies have yielded
	variable results and have largely been focused on TLE with mesial
	temporal sclerosis (TLE+). Diffusion tensor imaging (DTI) provides
	unique information on microstructure based on the measurement of
	water diffusion. To date, DTI properties of thalamus have not been
	well characterized in adult TLE patients with unilateral MTS or without
	MTS (TLE-). The purpose of this study was to investigate the status
	of thalamic integrity by using DTI as well as volumetric MRI in adult
	TLE+ and TLE- patients.In 17 unilateral TLE+ patients, 10 TLE- patients
	and 26 controls, the thalamus was segmented by using an automated
	atlas-based method. Mean diffusivity (MD), fractional anisotropy
	(FA) and volume were then quantified from DTI and 3D T1-weighted
	scans.No significant changes were found in either DTI parameters
	or volume of thalamus in TLE- patients, as compared to healthy controls.
	However, both DTI parameters and MRI volumetry showed bilateral thalamic
	pathology in TLE+ patients, as compared to healthy controls. Also,
	TLE+ patients showed significant reduction of thalamic volume as
	compared to TLE- patients. In addition, thalamic FA ipsilateral to
	seizure focus showed significant correlation with age at onset of
	epilepsy in TLE+ patients.Our finding demonstrates bilateral pathology
	of thalamus in unilateral TLE+ patients. The discrepancy in thalamic
	pathology between TLE+ and TLE- patients suggests that along with
	differences in mesial temporal pathology, TLE+ and TLE- have unique
	extratemporal structural abnormalities.},
  doi = {10.1016/j.eplepsyres.2008.04.002},
  institution = {Department of Biomedical Engineering, University of Alberta, Alberta,
	Canada.},
  keywords = {Adolescent; Adult; Age Factors; Anisotropy; Brain Mapping; Diffusion
	Magnetic Resonance Imaging; Epilepsy, Temporal Lobe, complications/pathology;
	Female; Functional Laterality; Humans; Imaging, Three-Dimensional,
	methods; Male; Middle Aged; Reproducibility of Results; Sclerosis,
	complications/pathology; Statistics as Topic; Temporal Lobe, pathology;
	Thalamus, pathology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S0920-1211(08)00090-9},
  pmid = {18490143},
  timestamp = {2013.07.04},
  url = {http://dx.doi.org/10.1016/j.eplepsyres.2008.04.002}
}

@ARTICLE{Gong_2009,
  author = {Gaolang Gong and Yong He and Luis Concha and Catherine Lebel and
	Donald W Gross and Alan C Evans and Christian Beaulieu},
  title = {Mapping anatomical connectivity patterns of human cerebral cortex
	using in vivo diffusion tensor imaging tractography.},
  journal = {Cereb Cortex},
  year = {2009},
  volume = {19},
  pages = {524--536},
  number = {3},
  month = {Mar},
  abstract = {The characterization of the topological architecture of complex networks
	underlying the structural and functional organization of the brain
	is a basic challenge in neuroscience. However, direct evidence for
	anatomical connectivity networks in the human brain remains scarce.
	Here, we utilized diffusion tensor imaging deterministic tractography
	to construct a macroscale anatomical network capturing the underlying
	common connectivity pattern of human cerebral cortex in a large sample
	of subjects (80 young adults) and further quantitatively analyzed
	its topological properties with graph theoretical approaches. The
	cerebral cortex was divided into 78 cortical regions, each representing
	a network node, and 2 cortical regions were considered connected
	if the probability of fiber connections exceeded a statistical criterion.
	The topological parameters of the established cortical network (binarized)
	resemble that of a "small-world" architecture characterized by an
	exponentially truncated power-law distribution. These characteristics
	imply high resilience to localized damage. Furthermore, this cortical
	network was characterized by major hub regions in association cortices
	that were connected by bridge connections following long-range white
	matter pathways. Our results are compatible with previous structural
	and functional brain networks studies and provide insight into the
	organizational principles of human brain anatomical networks that
	underlie functional states.},
  doi = {10.1093/cercor/bhn102},
  institution = {Department of Biomedical Engineering, 1098 Research Transition Facility,
	University of Alberta, Edmonton, Alberta, Canada.},
  keywords = {Adolescent; Adult; Brain Mapping, methods; Cerebral Cortex, anatomy
	/&/ histology/physiology; Diffusion Magnetic Resonance Imaging, methods;
	Female; Humans; Male; Nerve Net, anatomy /&/ histology/physiology;
	Neural Pathways, anatomy /&/ histology/physiology; Young Adult},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {bhn102},
  pmid = {18567609},
  timestamp = {2013.07.04},
  url = {http://dx.doi.org/10.1093/cercor/bhn102}
}

@ARTICLE{Goodale_1992,
  author = {M. A. Goodale and A. D. Milner},
  title = {Separate visual pathways for perception and action.},
  journal = {Trends Neurosci.},
  year = {1992},
  volume = {15},
  pages = {20--25},
  number = {1},
  month = {Jan},
  abstract = {Accumulating neuropsychological, electrophysiological and behavioural
	evidence suggests that the neural substrates of visual perception
	may be quite distinct from those underlying the visual control of
	actions. In other words, the set of object descriptions that permit
	identification and recognition may be computed independently of the
	set of descriptions that allow an observer to shape the hand appropriately
	to pick up an object. We propose that the ventral stream of projections
	from the striate cortex to the inferotemporal cortex plays the major
	role in the perceptual identification of objects, while the dorsal
	stream projecting from the striate cortex to the posterior parietal
	region mediates the required sensorimotor transformations for visually
	guided actions directed at such objects.},
  institution = {Dept of Psychology, University of Western Ontario, London, Canada.},
  keywords = {APPLICATION, Animals; Humans; Psychomotor Performance, physiology;
	Visual Pathways, physiology; Visual Perception, physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {0166-2236(92)90344-8},
  pmid = {1374953},
  timestamp = {2013.02.11}
}

@ARTICLE{Goodman_2009,
  author = {Dan F M Goodman and Romain Brette},
  title = {The Brian simulator.},
  journal = {Front. Neurosc.},
  year = {2009},
  volume = {3},
  pages = {192--197},
  number = {2},
  month = {Sep},
  abstract = {"Brian" is a simulator for spiking neural networks (http://www.briansimulator.org).
	The focus is on making the writing of simulation code as quick and
	easy as possible for the user, and on flexibility: new and non-standard
	models are no more difficult to define than standard ones. This allows
	scientists to spend more time on the details of their models, and
	less on their implementation. Neuron models are defined by writing
	differential equations in standard mathematical notation, facilitating
	scientific communication. Brian is written in the Python programming
	language, and uses vector-based computation to allow for efficient
	simulations. It is particularly useful for neuroscientific modelling
	at the systems level, and for teaching computational neuroscience.},
  doi = {10.3389/neuro.01.026.2009},
  institution = {Laboratoire Psychologie de la Perception, CNRS and Université Paris
	Descartes Paris, France.},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {20011141},
  timestamp = {2012.12.27},
  url = {http://dx.doi.org/10.3389/neuro.01.026.2009}
}

@ARTICLE{Goodman_2008,
  author = {Dan F M Goodman and Romain Brette},
  title = {Brian: a simulator for spiking neural networks in python.},
  journal = {Front. Neuroinform.},
  year = {2008},
  volume = {2},
  pages = {5},
  abstract = {"Brian" is a new simulator for spiking neural networks, written in
	Python (http://brian. di.ens.fr). It is an intuitive and highly flexible
	tool for rapidly developing new models, especially networks of single-compartment
	neurons. In addition to using standard types of neuron models, users
	can define models by writing arbitrary differential equations in
	ordinary mathematical notation. Python scientific libraries can also
	be used for defining models and analysing data. Vectorisation techniques
	allow efficient simulations despite the overheads of an interpreted
	language. Brian will be especially valuable for working on non-standard
	neuron models not easily covered by existing software, and as an
	alternative to using Matlab or C for simulations. With its easy and
	intuitive syntax, Brian is also very well suited for teaching computational
	neuroscience.},
  doi = {10.3389/neuro.11.005.2008},
  institution = {Département d'Informatique, Ecole Normale Supérieure Paris, France.},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {19115011},
  timestamp = {2012.12.27},
  url = {http://dx.doi.org/10.3389/neuro.11.005.2008}
}

@ARTICLE{Goulet_2011,
  author = {Julie Goulet and G. Bard Ermentrout},
  title = {The mechanisms for compression and reflection of cortical waves.},
  journal = {Biol Cybern},
  year = {2011},
  volume = {105},
  pages = {253--268},
  number = {3-4},
  month = {Oct},
  abstract = {Waves are common in cortical networks and may be important for carrying
	information about a stimulus from one local circuit to another. In
	a recent study of visually evoked waves in rat cortex, compression
	and reflection of waves are observed as the activation passes from
	visual areas V1 to V2. The authors of this study apply bicuculline
	(BMI) and demonstrate that the reflection disappears. They conclude
	that inhibition plays a major role in compression and reflection.
	We present several models for propagating waves in heterogeneous
	media and show that the velocity and thus compression depends weakly
	on inhibition. We propose that the main site of action of BMI with
	respect to wave propagation is on the threshold for firing which
	we suggest is related to action on potassium channels. We combine
	numerical and analytic methods to explore both compression and reflection
	in an excitable system with synaptic coupling.},
  doi = {10.1007/s00422-011-0465-3},
  institution = {Physik Department T35 and Bernstein Center for Computational Neuroscience,
	TU München, Garching bei München, Germany. julie@ph.tum.de},
  keywords = {Algorithms; Animals; Cerebral Cortex, physiology; Models, Neurological;
	Models, Theoretical; Rats},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {22105740},
  timestamp = {2013.09.04},
  url = {http://dx.doi.org/10.1007/s00422-011-0465-3}
}

@ARTICLE{Gouws_2009,
  author = {Gouws, André and Woods, Will and Millman, Rebecca and Morland, Antony
	and Green, Gary},
  title = {DataViewer3D: An Open-Source, Cross-Platform Multi-Modal Neuroimaging
	Data Visualization Tool.},
  journal = {Front. Neuroinform.},
  year = {2009},
  volume = {3},
  pages = {9},
  abstract = {Integration and display of results from multiple neuroimaging modalities
	[e.g. magnetic resonance imaging (MRI), magnetoencephalography, EEG]
	relies on display of a diverse range of data within a common, defined
	coordinate frame. DataViewer3D (DV3D) is a multi-modal imaging data
	visualization tool offering a cross-platform, open-source solution
	to simultaneous data overlay visualization requirements of imaging
	studies. While DV3D is primarily a visualization tool, the package
	allows an analysis approach where results from one imaging modality
	can guide comparative analysis of another modality in a single coordinate
	space. DV3D is built on Python, a dynamic object-oriented programming
	language with support for integration of modular toolkits, and development
	of cross-platform software for neuroimaging. DV3D harnesses the power
	of the Visualization Toolkit (VTK) for two-dimensional (2D) and 3D
	rendering, calling VTK's low level C++ functions from Python. Users
	interact with data via an intuitive interface that uses Python to
	bind wxWidgets, which in turn calls the user's operating system dialogs
	and graphical user interface tools. DV3D currently supports NIfTI-1,
	ANALYZE and DICOM formats for MRI data display (including statistical
	data overlay). Formats for other data types are supported. The modularity
	of DV3D and ease of use of Python allows rapid integration of additional
	format support and user development. DV3D has been tested on Mac
	OSX, RedHat Linux and Microsoft Windows XP. DV3D is offered for free
	download with an extensive set of tutorial resources and example
	data.},
  doi = {10.3389/neuro.11.009.2009},
  institution = {Department of Psychology, York NeuroImaging Centre University of
	York UK.},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paupau},
  pmid = {19352444},
  timestamp = {2013.02.25},
  url = {http://dx.doi.org/10.3389/neuro.11.009.2009}
}

@ARTICLE{Gramfort_2012,
  author = {Alexandre Gramfort and Matthieu Kowalski and Matti Hämäläinen},
  title = {Mixed-norm estimates for the M/EEG inverse problem using accelerated
	gradient methods.},
  journal = {Phys. Med. Biol.},
  year = {2012},
  volume = {57},
  pages = {1937--1961},
  number = {7},
  month = {Apr},
  abstract = {Magneto- and electroencephalography (M/EEG) measure the electromagnetic
	fields produced by the neural electrical currents. Given a conductor
	model for the head, and the distribution of source currents in the
	brain, Maxwell's equations allow one to compute the ensuing M/EEG
	signals. Given the actual M/EEG measurements and the solution of
	this forward problem, one can localize, in space and in time, the
	brain regions that have produced the recorded data. However, due
	to the physics of the problem, the limited number of sensors compared
	to the number of possible source locations, and measurement noise,
	this inverse problem is ill-posed. Consequently, additional constraints
	are needed. Classical inverse solvers, often called minimum norm
	estimates (MNE), promote source estimates with a small ℓ₂ norm. Here,
	we consider a more general class of priors based on mixed norms.
	Such norms have the ability to structure the prior in order to incorporate
	some additional assumptions about the sources. We refer to such solvers
	as mixed-norm estimates (MxNE). In the context of M/EEG, MxNE can
	promote spatially focal sources with smooth temporal estimates with
	a two-level ℓ₁/ℓ₂ mixed-norm, while a three-level mixed-norm can
	be used to promote spatially non-overlapping sources between different
	experimental conditions. In order to efficiently solve the optimization
	problems of MxNE, we introduce fast first-order iterative schemes
	that for the ℓ₁/ℓ₂ norm give solutions in a few seconds making such
	a prior as convenient as the simple MNE. Furthermore, thanks to the
	convexity of the optimization problem, we can provide optimality
	conditions that guarantee global convergence. The utility of the
	methods is demonstrated both with simulations and experimental MEG
	data.},
  doi = {10.1088/0031-9155/57/7/1937},
  institution = {Parietal Project Team, INRIA Saclay-Ile de France, France. alexandre.gramfort@inria.fr},
  keywords = {Acceleration; Algorithms; Electroencephalography, methods; Magnetoencephalography,
	methods; Signal Processing, Computer-Assisted; Somatosensory Cortex,
	physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {22421459},
  timestamp = {2013.03.11},
  url = {http://dx.doi.org/10.1088/0031-9155/57/7/1937}
}

@ARTICLE{Gramfort_2011,
  author = {Alexandre Gramfort and Théodore Papadopoulo and Emmanuel Olivi and
	Maureen Clerc},
  title = {Forward field computation with OpenMEEG.},
  journal = {Comput. Intell. Neurosci.},
  year = {2011},
  volume = {2011},
  pages = {923703},
  abstract = {To recover the sources giving rise to electro- and magnetoencephalography
	in individual measurements, realistic physiological modeling is required,
	and accurate numerical solutions must be computed. We present OpenMEEG,
	which solves the electromagnetic forward problem in the quasistatic
	regime, for head models with piecewise constant conductivity. The
	core of OpenMEEG consists of the symmetric Boundary Element Method,
	which is based on an extended Green Representation theorem. OpenMEEG
	is able to provide lead fields for four different electromagnetic
	forward problems: Electroencephalography (EEG), Magnetoencephalography
	(MEG), Electrical Impedance Tomography (EIT), and intracranial electric
	potentials (IPs). OpenMEEG is open source and multiplatform. It can
	be used from Python and Matlab in conjunction with toolboxes that
	solve the inverse problem; its integration within FieldTrip is operational
	since release 2.0.},
  doi = {10.1155/2011/923703},
  institution = {Parietal Project Team, INRIA Saclay Ile-de-France, Neurospin-CEA,
	Gif/Yvette, France. alexandre.gramfort@inria.fr},
  keywords = {Brain Mapping; Brain, physiology; Computer Simulation; Electroencephalography,
	methods; Finite Element Analysis; Head; Humans; Magnetocardiography,
	methods; Models, Neurological; Software},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {21437231},
  timestamp = {2013.02.01},
  url = {http://dx.doi.org/10.1155/2011/923703}
}

@ARTICLE{Gramfort_2010,
  author = {Alexandre Gramfort and Théodore Papadopoulo and Emmanuel Olivi and
	Maureen Clerc},
  title = {OpenMEEG: opensource software for quasistatic bioelectromagnetics.},
  journal = {Biomed. Eng. Online},
  year = {2010},
  volume = {9},
  pages = {45},
  abstract = {Interpreting and controlling bioelectromagnetic phenomena require
	realistic physiological models and accurate numerical solvers. A
	semi-realistic model often used in practise is the piecewise constant
	conductivity model, for which only the interfaces have to be meshed.
	This simplified model makes it possible to use Boundary Element Methods.
	Unfortunately, most Boundary Element solutions are confronted with
	accuracy issues when the conductivity ratio between neighboring tissues
	is high, as for instance the scalp/skull conductivity ratio in electro-encephalography.
	To overcome this difficulty, we proposed a new method called the
	symmetric BEM, which is implemented in the OpenMEEG software. The
	aim of this paper is to present OpenMEEG, both from the theoretical
	and the practical point of view, and to compare its performances
	with other competing software packages.We have run a benchmark study
	in the field of electro- and magneto-encephalography, in order to
	compare the accuracy of OpenMEEG with other freely distributed forward
	solvers. We considered spherical models, for which analytical solutions
	exist, and we designed randomized meshes to assess the variability
	of the accuracy. Two measures were used to characterize the accuracy.
	the Relative Difference Measure and the Magnitude ratio. The comparisons
	were run, either with a constant number of mesh nodes, or a constant
	number of unknowns across methods. Computing times were also compared.We
	observed more pronounced differences in accuracy in electroencephalography
	than in magnetoencephalography. The methods could be classified in
	three categories: the linear collocation methods, that run very fast
	but with low accuracy, the linear collocation methods with isolated
	skull approach for which the accuracy is improved, and OpenMEEG that
	clearly outperforms the others. As far as speed is concerned, OpenMEEG
	is on par with the other methods for a constant number of unknowns,
	and is hence faster for a prescribed accuracy level.This study clearly
	shows that OpenMEEG represents the state of the art for forward computations.
	Moreover, our software development strategies have made it handy
	to use and to integrate with other packages. The bioelectromagnetic
	research community should therefore be able to benefit from OpenMEEG
	with a limited development effort.},
  doi = {10.1186/1475-925X-9-45},
  institution = {Athena Project Team, INRIA Sophia Antipolis Méditerranée, France.
	alexandre.gramfort@inria.fr},
  keywords = {Benchmarking; Computers; Electric Impedance; Electricity; Electroencephalography;
	Electromagnetic Phenomena; Licensure; Magnetics; Magnetoencephalography;
	Models, Theoretical; Quality Control; Software, legislation /&/ jurisprudence/standards;
	Time Factors; Tomography},
  language = {eng},
  medline-pst = {epublish},
  owner = {paula},
  pii = {1475-925X-9-45},
  pmid = {20819204},
  timestamp = {2013.02.01},
  url = {http://dx.doi.org/10.1186/1475-925X-9-45}
}

@ARTICLE{Gramfort_2011b,
  author = {Alexandre Gramfort and Daniel Strohmeier and Jens Haueisen and Matti
	Hamalainen and Matthieu Kowalski},
  title = {Functional brain imaging with M/EEG using structured sparsity in
	time-frequency dictionaries.},
  journal = {Inf. Process. Med. Imaging.},
  year = {2011},
  volume = {22},
  pages = {600--611},
  abstract = {Magnetoencephalography (MEG) and electroencephalography (EEG) allow
	functional brain imaging with high temporal resolution. While time-frequency
	analysis is often used in the field, it is not commonly employed
	in the context of the ill-posed inverse problem that maps the MEG
	and EEG measurements to the source space in the brain. In this work,
	we detail how convex structured sparsity can be exploited to achieve
	a principled and more accurate functional imaging approach. Importantly,
	time-frequency dictionaries can capture the non-stationary nature
	of brain signals and state-of-the-art convex optimization procedures
	based on proximal operators allow the derivation of a fast estimation
	algorithm. We compare the accuracy of our new method to recently
	proposed inverse solvers with help of simulations and analysis of
	real MEG data.},
  institution = {INRIA, Parietal team, Saclay, France.},
  keywords = {Action Potentials, physiology; Algorithms; Brain Mapping, methods;
	Brain, physiology; Electroencephalography, methods; Humans; Image
	Enhancement, methods; Image Interpretation, Computer-Assisted, methods;
	Magnetoencephalography, methods; Reproducibility of Results; Sensitivity
	and Specificity},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {21761689},
  timestamp = {2013.03.11}
}

@ARTICLE{Gross_2001,
  author = {J. Gross and J. Kujala and M. Hamalainen and L. Timmermann and A.
	Schnitzler and R. Salmelin},
  title = {Dynamic imaging of coherent sources: Studying neural interactions
	in the human brain.},
  journal = {Proc. Natl. Acad. Sci. U.S.A.},
  year = {2001},
  volume = {98},
  pages = {694--699},
  number = {2},
  month = {Jan},
  abstract = {Functional connectivity between cortical areas may appear as correlated
	time behavior of neural activity. It has been suggested that merging
	of separate features into a single percept ("binding") is associated
	with coherent gamma band activity across the cortical areas involved.
	Therefore, it would be of utmost interest to image cortico-cortical
	coherence in the working human brain. The frequency specificity and
	transient nature of these interactions requires time-sensitive tools
	such as magneto- or electroencephalography (MEG/EEG). Coherence between
	signals of sensors covering different scalp areas is commonly taken
	as a measure of functional coupling. However, this approach provides
	vague information on the actual cortical areas involved, owing to
	the complex relation between the active brain areas and the sensor
	recordings. We propose a solution to the crucial issue of proceeding
	beyond the MEG sensor level to estimate coherences between cortical
	areas. Dynamic imaging of coherent sources (DICS) uses a spatial
	filter to localize coherent brain regions and provides the time courses
	of their activity. Reference points for the computation of neural
	coupling may be based on brain areas of maximum power or other physiologically
	meaningful information, or they may be estimated starting from sensor
	coherences. The performance of DICS is evaluated with simulated data
	and illustrated with recordings of spontaneous activity in a healthy
	subject and a parkinsonian patient. Methods for estimating functional
	connectivities between brain areas will facilitate characterization
	of cortical networks involved in sensory, motor, or cognitive tasks
	and will allow investigation of pathological connectivities in neurological
	disorders.},
  doi = {10.1073/pnas.98.2.694},
  institution = {Department of Neurology, Heinrich-Heine-University, Moorenstrasse
	5, D-40225 Duesseldorf, Germany.},
  keywords = {Algorithms; Brain Mapping, methods; Brain, physiology; Electroencephalography;
	Humans; Image Processing, Computer-Assisted; Magnetoencephalography;
	Motor Cortex, physiology; Neurons, physiology; Parkinson Disease,
	physiopathology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {98/2/694},
  pmid = {11209067},
  timestamp = {2013.03.11},
  url = {http://dx.doi.org/10.1073/pnas.98.2.694}
}

@ARTICLE{Gutkin_2003,
  author = {Boris Gutkin and David Pinto and Bard Ermentrout},
  title = {Mathematical neuroscience: from neurons to circuits to systems.},
  journal = {J Physiol Paris},
  year = {2003},
  volume = {97},
  pages = {209--219},
  number = {2-3},
  abstract = {Applications of mathematics and computational techniques to our understanding
	of neuronal systems are provided. Reduction of membrane models to
	simplified canonical models demonstrates how neuronal spike-time
	statistics follow from simple properties of neurons. Averaging over
	space allows one to derive a simple model for the whisker barrel
	circuit and use this to explain and suggest several experiments.
	Spatio-temporal pattern formation methods are applied to explain
	the patterns seen in the early stages of drug-induced visual hallucinations.},
  doi = {10.1016/j.jphysparis.2003.09.005},
  institution = {Division of Biology and Medicine, Department of Neuroscience, Brown
	University, Providence, RI, USA.},
  keywords = {Action Potentials, physiology; Animals; Hallucinations, physiopathology;
	Humans; Mathematics; Neural Networks (Computer); Neurons, physiology;
	Neurosciences, methods; Photic Stimulation, methods},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S0928-4257(03)00061-5},
  pmid = {14766142},
  timestamp = {2013.09.04},
  url = {http://dx.doi.org/10.1016/j.jphysparis.2003.09.005}
}

@ARTICLE{Gutschalk_2010,
  author = {Alexander Gutschalk and Matti S Hämäläinen and Jennifer R Melcher},
  title = {BOLD responses in human auditory cortex are more closely related
	to transient MEG responses than to sustained ones.},
  journal = {J. Neurophysiol.},
  year = {2010},
  volume = {103},
  pages = {2015--2026},
  number = {4},
  month = {Apr},
  abstract = {Blood oxygen level dependent-functional magnetic resonance imaging
	(BOLD-fMRI) and magnetoencephalographic (MEG) signals are both coupled
	to postsynaptic potentials, although their relationship is incompletely
	understood. Here, the wide range of BOLD-fMRI and MEG responses produced
	by auditory cortex was exploited to better understand the BOLD-fMRI/MEG
	relationship. Measurements of BOLD and MEG responses were made in
	the same subjects using the same stimuli for both modalities. The
	stimuli, 24-s sequences of click trains, had duty cycles of 2.5,
	25, 72, and 100\%. For the 2.5\% sequence, the BOLD response was
	elevated throughout the sequence, whereas for 100\%, it peaked after
	sequence onset and offset and showed a diminished elevation in between.
	On the finer timescale of MEG, responses at 2.5\% consisted of a
	complex of transients, including N(1)m, to each click train of the
	sequence, whereas for 100\% the only transients occurred at sequence
	onset and offset between which there was a sustained elevation in
	the MEG signal (a sustained field). A model that separately estimated
	the contributions of transient and sustained MEG signals to the BOLD
	response best fit BOLD measurements when the transient contribution
	was weighted 8- to 10-fold more than the sustained one. The findings
	suggest that BOLD responses in the auditory cortex are tightly coupled
	to the neural activity underlying transient, not sustained, MEG signals.},
  doi = {10.1152/jn.01005.2009},
  institution = {Department of Neurology, Ruprecht-Karls-Universität Heidelberg, 69120
	Heidelberg, Germany. Alexander.Gutschalk@med.uni.heidelberg.de},
  keywords = {Adult; Auditory Cortex, physiology; Brain Mapping; Female; Humans;
	Magnetic Resonance Imaging; Magnetoencephalography; Male; Models,
	Biological; Oxygen, blood; Reaction Time; Synaptic Potentials, physiology;
	Time Factors},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {01005.2009},
  pmid = {20107131},
  timestamp = {2013.03.11},
  url = {http://dx.doi.org/10.1152/jn.01005.2009}
}

@ARTICLE{Hagmann_2008,
  author = {Patric Hagmann and Leila Cammoun and Xavier Gigandet and Reto Meuli
	and Christopher J Honey and Van J Wedeen and Olaf Sporns},
  title = {Mapping the structural core of human cerebral cortex.},
  journal = {PLoS Biol.},
  year = {2008},
  volume = {6},
  pages = {e159},
  number = {7},
  month = {Jul},
  abstract = {Structurally segregated and functionally specialized regions of the
	human cerebral cortex are interconnected by a dense network of cortico-cortical
	axonal pathways. By using diffusion spectrum imaging, we noninvasively
	mapped these pathways within and across cortical hemispheres in individual
	human participants. An analysis of the resulting large-scale structural
	brain networks reveals a structural core within posterior medial
	and parietal cerebral cortex, as well as several distinct temporal
	and frontal modules. Brain regions within the structural core share
	high degree, strength, and betweenness centrality, and they constitute
	connector hubs that link all major structural modules. The structural
	core contains brain regions that form the posterior components of
	the human default network. Looking both within and outside of core
	regions, we observed a substantial correspondence between structural
	connectivity and resting-state functional connectivity measured in
	the same participants. The spatial and topological centrality of
	the core within cortex suggests an important role in functional integration.},
  doi = {10.1371/journal.pbio.0060159},
  institution = {Department of Radiology, University Hospital Center and University
	of Lausanne (CHUV), Lausanne, Switzerland.},
  keywords = {Adult; Brain Mapping; Cerebral Cortex, anatomy /&/ histology/physiology;
	Diffusion Magnetic Resonance Imaging; Humans; Imaging, Three-Dimensional;
	Male; Models, Neurological; Nerve Net, physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {07-PLBI-RA-4028},
  pmid = {18597554},
  timestamp = {2012.11.14},
  url = {http://dx.doi.org/10.1371/journal.pbio.0060159}
}

@ARTICLE{Haken_2001,
  author = {Haken, H.},
  title = {Delay, noise and phase locking in pulse coupled neural networks.},
  journal = {Biosystems},
  year = {2001},
  volume = {63},
  pages = {15--20},
  number = {1-3},
  abstract = {This paper studies the effect of several delay times and noise on
	the stability of the phase-locked state in the lighthouse model and
	the integrate and fire model of a pulse coupled neural network. The
	coupling between neurons may be arbitrary. In both models the increase
	of delay times leads to a weakening of the stability and to the occurrence
	of relaxation oscillations.},
  institution = {Institute for Theoretical Physics, Center of Synergetics, Pfaffenwaldring
	57/4, D-70550, Stuttgart, Germany.},
  keywords = {Dendrites, physiology; Models, Biological; Nerve Net},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paupau},
  pii = {S0303264701001435},
  pmid = {11595326},
  timestamp = {2013.02.15}
}

@BOOK{book_Haken_1983,
  title = {Synergetics, an Introduction: Nonequilibrium Phase Transitions and
	Self-Organization in Physics, Chemistry, and Biology},
  publisher = {New York Springer Verlag},
  year = {1983},
  author = {H Haken},
  edition = {3},
  owner = {paula},
  timestamp = {2012.10.18}
}

@ARTICLE{Halchenko_2012,
  author = {Yaroslav O Halchenko and Michael Hanke},
  title = {Open is Not Enough. Let's Take the Next Step: An Integrated, Community-Driven
	Computing Platform for Neuroscience.},
  journal = {Front. Neuroinform.},
  year = {2012},
  volume = {6},
  pages = {22},
  doi = {10.3389/fninf.2012.00022},
  institution = {Center for Cognitive Neuroscience, Dartmouth College Hanover, NH,
	USA ; Department of Psychological and Brain Sciences, Dartmouth College
	Hanover, NH, USA ; Debian Project http://www.debian.org.},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {23055966},
  timestamp = {2013.01.18},
  url = {http://dx.doi.org/10.3389/fninf.2012.00022}
}

@ARTICLE{Hamalainen_1989,
  author = {Hamalainen, M.S. and Sarvas, J.},
  title = {{Realistic conductivity geometry model of the human head for interpretation
	of neuromagnetic data}},
  journal = {IEEE Trans. Biomed. Eng.},
  year = {1989},
  volume = {36},
  pages = {165--171},
  number = {2},
  issn = {0018-9294},
  publisher = {IEEE}
}

@ARTICLE{Haemaelaeinen_1992,
  author = {M. S. Hämäläinen},
  title = {Magnetoencephalography: a tool for functional brain imaging.},
  journal = {Brain Topogr.},
  year = {1992},
  volume = {5},
  pages = {95--102},
  number = {2},
  abstract = {At present, one of the most promising windows to the functional organization
	of the human brain is magnetoencephalography (MEG). By mapping the
	magnetic field distribution outside the head the sites of neural
	events can be located with an accuracy of a few millimeters and the
	temporal evolution of the activation can be traced with a millisecond
	resolution. This paper reviews some forward field calculation approaches
	suitable for the interpretation of the brain's electromagnetic signals.
	Inverse modelling with multiple dipoles is described in detail. An
	example of the analysis of the somatosensory evoked-responses illustrates
	the potential of multiple signal classification (MUSIC) algorithm
	in finding optimal dipole positions.},
  institution = {Low Temperature Laboratory, Helsinki University of Technology, Espoo,
	Finland.},
  keywords = {Algorithms; Brain, anatomy /&/ histology/physiology; Humans; Magnetic
	Resonance Imaging; Magnetoencephalography; Models, Neurological},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {1489655},
  timestamp = {2013.03.11}
}

@ARTICLE{Haemaelaeinen_1993,
  author = {Hämäläinen, M. S. and Hari, Riitta and Ilmoniemi, R. J. and Knuutila,
	Jukka and Lounasmaa, O. V.},
  title = {Magnetoencephalography-theory, instrumentation, and applications
	to noninvasive studies of the working human brain},
  journal = {Rev. Modern Phys.},
  year = {1993},
  volume = {65},
  pages = {413-497},
  number = {2},
  month = {4},
  owner = {paula},
  timestamp = {2013.03.11}
}

@ARTICLE{Haemaelaeinen_1987,
  author = {M. S. Hämäläinen and J. Sarvas},
  title = {Feasibility of the homogeneous head model in the interpretation of
	neuromagnetic fields.},
  journal = {Phys. Med. Biol.},
  year = {1987},
  volume = {32},
  pages = {91--97},
  number = {1},
  month = {Jan},
  abstract = {During the past few years it has been demonstrated that active areas
	in the human brain can be located by measuring the magnetic fields
	arising from the electric currents in the neurons. An established
	model for the conductivity geometry of the head in these studies
	is the layerwise homogeneous sphere. If, however, the measurement
	grid is too large or the local radius of curvature of the head is
	changing rapidly in the measurement area, this simple model may become
	inadequate. In this paper we investigate the feasibility of replacing
	the conducting sphere by a homogeneous body having the shape of the
	brain. We show by a semi-quantitative argument that the homogeneous
	body model is justified. A numerical procedure for the calculation
	of the magnetic field is presented with examples of the accuracy
	that can be obtained. An example of significant differences between
	the predictions of the homogeneous and sphere models is discussed.},
  keywords = {Animals; Brain, anatomy /&/ histology/physiology; Humans; Magnetics;
	Mathematics; Models, Neurological},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {3823145},
  timestamp = {2013.03.11}
}

@ARTICLE{Havlicek2011,
  author = {Martin Havlicek and Karl J Friston and Jiri Jan and Milan Brazdil
	and Vince D Calhoun},
  title = {Dynamic modeling of neuronal responses in fMRI using cubature Kalman
	filtering.},
  journal = {Neuroimage},
  year = {2011},
  volume = {56},
  pages = {2109--2128},
  number = {4},
  month = {Jun},
  abstract = {This paper presents a new approach to inverting (fitting) models of
	coupled dynamical systems based on state-of-the-art (cubature) Kalman
	filtering. Crucially, this inversion furnishes posterior estimates
	of both the hidden states and parameters of a system, including any
	unknown exogenous input. Because the underlying generative model
	is formulated in continuous time (with a discrete observation process)
	it can be applied to a wide variety of models specified with either
	ordinary or stochastic differential equations. These are an important
	class of models that are particularly appropriate for biological
	time-series, where the underlying system is specified in terms of
	kinetics or dynamics (i.e., dynamic causal models). We provide comparative
	evaluations with generalized Bayesian filtering (dynamic expectation
	maximization) and demonstrate marked improvements in accuracy and
	computational efficiency. We compare the schemes using a series of
	difficult (nonlinear) toy examples and conclude with a special focus
	on hemodynamic models of evoked brain responses in fMRI. Our scheme
	promises to provide a significant advance in characterizing the functional
	architectures of distributed neuronal systems, even in the absence
	of known exogenous (experimental) input; e.g., resting state fMRI
	studies and spontaneous fluctuations in electrophysiological studies.
	Importantly, unlike current Bayesian filters (e.g. DEM), our scheme
	provides estimates of time-varying parameters, which we will exploit
	in future work on the adaptation and enabling of connections in the
	brain.},
  doi = {10.1016/j.neuroimage.2011.03.005},
  institution = {Department of Biomedical Engineering, Brno University of Technology,
	Brno, Czech Republic. havlicekmartin@gmail.com},
  keywords = {Algorithms; Brain, blood supply/physiology; Hemodynamics, physiology;
	Humans; Image Interpretation, Computer-Assisted, methods; Magnetic
	Resonance Imaging; Models, Neurological; Monte Carlo Method; Neural
	Pathways, physiology; Neurons, physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S1053-8119(11)00264-3},
  pmid = {21396454},
  timestamp = {2013.04.11},
  url = {http://dx.doi.org/10.1016/j.neuroimage.2011.03.005}
}

@ARTICLE{Helmholtz_1853,
  author = {H Helmholtz},
  title = {Ueber einige Gesetze der Vertheilung elektrischer Ströme in körperlichen
	Leitern mit Anwendung auf die thierisch-elektrischen Versuche},
  journal = {Annalen der Physik},
  year = {1853},
  volume = {165},
  pages = {211-233},
  number = {6},
  owner = {paula},
  timestamp = {2012.10.18}
}

@ARTICLE{Henke_2009,
  author = {H. Henke and P. A. Robinson and P. M. Drysdale and P. N. Loxley},
  title = {Spatiotemporal dynamics of pattern formation in the primary visual
	cortex and hallucinations.},
  journal = {Biol. Cybern.},
  year = {2009},
  volume = {101},
  pages = {3--18},
  number = {1},
  month = {Jul},
  abstract = {The existence of visual hallucinations with prominent temporal oscillations
	is well documented in conditions such as Charles Bonnett Syndrome.
	To explore these phenomena, a continuum model of cortical activity
	that includes additional physiological features of axonal propagation
	and synapto-dendritic time constants, is used to study the generation
	of hallucinations featuring both temporal and spatial oscillations.
	A detailed comparison of the physiological features of this model
	with those of two others used previously in the modeling of hallucinations
	is made, and differences, particularly regarding temporal dynamics,
	relevant to pattern formation are analyzed. Linear analysis and numerical
	calculation are then employed to examine the pattern forming behavior
	of this new model for two different forms of spatiotemporal coupling
	between neurons. Numerical calculations reveal an oscillating mode
	whose frequency depends on synaptic, dendritic, and axonal time constants
	not previously simultaneously included in such analyses. Its properties
	are qualitatively consistent with descriptions of a number of physiological
	disorders and conditions with temporal dynamics, but the analysis
	implies that corticothalamic effects will need to be incorporated
	to treat the consequences quantitatively.},
  doi = {10.1007/s00422-009-0315-8},
  institution = {School of Physics, The University of Sydney, Sydney, NSW 2006, Australia.
	henke@physics.usyd.edu.au},
  keywords = {Animals; Hallucinations, pathology; Humans; Models, Neurological;
	Neurons, physiology; Nonlinear Dynamics; Pattern Recognition, Visual,
	physiology; Photic Stimulation, methods; Space Perception, physiology;
	Visual Cortex, pathology/physiopathology; Visual Pathways, physiopathology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {19504122},
  timestamp = {2013.02.18},
  url = {http://dx.doi.org/10.1007/s00422-009-0315-8}
}

@ARTICLE{Hille_1981,
  author = {M. Hille and A. van Rotterdam},
  title = {Latency distributions in homogeneous bundles of myelinated axons.},
  journal = {Biol Cybern},
  year = {1981},
  volume = {41},
  pages = {235--238},
  number = {3},
  keywords = {Action Potentials; Animals; Axons, physiology; Humans; Models, Biological;
	Myelin Sheath, physiology; Neural Conduction; Time Factors},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {7317521},
  timestamp = {2013.08.19}
}

@ARTICLE{Hindmarsh_1984,
  author = {Hindmarsh, JL and Rose, RM},
  title = {A model of neuronal bursting using three coupled first order differential
	equations.},
  journal = {Proc. R. Soc. London, Ser. B},
  year = {1984},
  volume = {221},
  pages = {87-122},
  number = {1222},
  month = {March},
  abstract = {We describe a modification to our recent model of the action potential
	which introduces two additional equilibrium points. By using stability
	analysis we show that one of these equilibrium points is a saddle
	point from which there are two separatrices which divide the phase
	plane into two regions. In one region all phase paths approach a
	limit cycle and in the other all phase paths approach a stable equilibrium
	point. A consequence of this is that a short depolarizing current
	pulse will change an initially silent model neuron into one that
	fires repetitively. Addition of a third equation limits this firing
	to either an isolated burst or a depolarizing afterpotential. When
	steady depolarizing current was applied to this model it resulted
	in periodic bursting. The equations, which were initially developed
	to explain isolated triggered bursts, therefore provide one of the
	simplest models of the more general phenomenon of oscillatory burst
	discharge.},
  keywords = {model},
  owner = {paula},
  timestamp = {2012.10.18}
}

@ARTICLE{Hinds_2009,
  author = {Oliver Hinds and Jonathan R Polimeni and Niranjini Rajendran and
	Mukund Balasubramanian and Katrin Amunts and Karl Zilles and Eric
	L Schwartz and Bruce Fischl and Christina Triantafyllou},
  title = {Locating the functional and anatomical boundaries of human primary
	visual cortex.},
  journal = {Neuroimage},
  year = {2009},
  volume = {46},
  pages = {915--922},
  number = {4},
  month = {Jul},
  abstract = {The primary visual cortex (V1) can be delineated both functionally
	by its topographic map of the visual field and anatomically by its
	distinct pattern of laminar myelination. Although it is commonly
	assumed that the specialized anatomy V1 exhibits corresponds in location
	with functionally defined V1, demonstrating this in human has not
	been possible thus far due to the difficulty of determining the location
	of V1 both functionally and anatomically in the same individual.
	In this study we use MRI to measure the anatomical and functional
	V1 boundaries in the same individual and demonstrate close agreement
	between them. Functional V1 location was measured by parcellating
	occipital cortex of 10 living humans into visual cortical areas based
	on the topographic map of the visual field measured using functional
	MRI. Anatomical V1 location was estimated for these same subjects
	using a surface-based probabilistic atlas derived from high-resolution
	structural MRI of the stria of Gennari in 10 intact ex vivo human
	hemispheres. To ensure that the atlas prediction was correct, it
	was validated against V1 location measured using an observer-independent
	cortical parcellation based on the laminar pattern of cell density
	in serial brain sections from 10 separate individuals. The close
	agreement between the independent anatomically and functionally derived
	V1 boundaries indicates that the whole extent of V1 can be accurately
	predicted based on cortical surface reconstructions computed from
	structural MRI scans, eliminating the need for functional localizers
	of V1. In addition, that the primary cortical folds predict the location
	of functional V1 suggests that the mechanism giving rise to V1 location
	is tied to the development of the cortical folds.},
  doi = {10.1016/j.neuroimage.2009.03.036},
  institution = {Brain and Cognitive Sciences, Massachusetts Institute of Technology,
	USA. ohinds@mit.edu},
  keywords = {Brain Mapping, methods; Humans; Image Interpretation, Computer-Assisted;
	Magnetic Resonance Imaging; Visual Cortex, anatomy /&/ histology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S1053-8119(09)00275-4},
  pmid = {19328238},
  timestamp = {2013.04.24},
  url = {http://dx.doi.org/10.1016/j.neuroimage.2009.03.036}
}

@ARTICLE{Hines_2001,
  author = {M. L. Hines and N. T. Carnevale},
  title = {NEURON: a tool for neuroscientists.},
  journal = {Neuroscientist.},
  year = {2001},
  volume = {7},
  pages = {123--135},
  number = {2},
  month = {Apr},
  abstract = {NEURON is a simulation environment for models of individual neurons
	and networks of neurons that are closely linked to experimental data.
	NEURON provides tools for conveniently constructing, exercising,
	and managing models, so that special expertise in numerical methods
	or programming is not required for its productive use. This article
	describes two tools that address the problem of how to achieve computational
	efficiency and accuracy.},
  institution = {Department of Computer Science, Yale University, New Haven Connecticut
	06520-8001, USA. michael.hines@yale.},
  keywords = {Animals; Computer Simulation; Humans; Models, Neurological; Nerve
	Net, physiology; Neurons, physiology; Neurosciences, methods},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {11496923},
  timestamp = {2013.02.06}
}

@ARTICLE{Hines_2009,
  author = {Michael L Hines and Andrew P Davison and Eilif Muller},
  title = {NEURON and Python.},
  journal = {Front. Neuroinform.},
  year = {2009},
  volume = {3},
  pages = {1},
  abstract = {The NEURON simulation program now allows Python to be used, alone
	or in combination with NEURON's traditional Hoc interpreter. Adding
	Python to NEURON has the immediate benefit of making available a
	very extensive suite of analysis tools written for engineering and
	science. It also catalyzes NEURON software development by offering
	users a modern programming tool that is recognized for its flexibility
	and power to create and maintain complex programs. At the same time,
	nothing is lost because all existing models written in Hoc, including
	graphical user interface tools, continue to work without change and
	are also available within the Python context. An example of the benefits
	of Python availability is the use of the xml module in implementing
	NEURON's Import3D and CellBuild tools to read MorphML and NeuroML
	model specifications.},
  doi = {10.3389/neuro.11.001.2009},
  institution = {Computer Science, Yale University New Haven, CT, USA.},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {19198661},
  timestamp = {2013.02.01},
  url = {http://dx.doi.org/10.3389/neuro.11.001.2009}
}

@ARTICLE{Hines_2008,
  author = {Michael L Hines and Henry Markram and Felix Schürmann},
  title = {Fully implicit parallel simulation of single neurons.},
  journal = {J. Comput. Neurosci.},
  year = {2008},
  volume = {25},
  pages = {439--448},
  number = {3},
  month = {Dec},
  abstract = {When a multi-compartment neuron is divided into subtrees such that
	no subtree has more than two connection points to other subtrees,
	the subtrees can be on different processors and the entire system
	remains amenable to direct Gaussian elimination with only a modest
	increase in complexity. Accuracy is the same as with standard Gaussian
	elimination on a single processor. It is often feasible to divide
	a 3-D reconstructed neuron model onto a dozen or so processors and
	experience almost linear speedup. We have also used the method for
	purposes of load balance in network simulations when some cells are
	so large that their individual computation time is much longer than
	the average processor computation time or when there are many more
	processors than cells. The method is available in the standard distribution
	of the NEURON simulation program.},
  doi = {10.1007/s10827-008-0087-5},
  institution = {Computer Science, Yale University, New Haven, CT, USA. michael.hines@yale.edu},
  keywords = {Animals; Computer Simulation; Models, Neurological; Nerve Net, physiology;
	Neural Networks (Computer); Neurons, physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {18379867},
  timestamp = {2013.02.01},
  url = {http://dx.doi.org/10.1007/s10827-008-0087-5}
}

@ARTICLE{Hinrikus2011,
  author = {Hiie Hinrikus and Maie Bachmann and Deniss Karai and Włodzimierz
	Klonowski and Jaanus Lass and Pavel Stepien and Robert Stepien and
	Viiu Tuulik},
  title = {Higuchi's fractal dimension for analysis of the effect of external
	periodic stressor on electrical oscillations in the brain.},
  journal = {Med. Biol. Eng. Comput.},
  year = {2011},
  volume = {49},
  pages = {585--591},
  number = {5},
  month = {May},
  abstract = {This study addresses application of Higuchi's fractal dimension (FD)
	as a measure to evaluate the effect of external periodic stressor
	on electrical oscillations in the brain. Modulated microwave radiation
	was applied as a weak periodic stressor with strongly inhomogeneous
	distribution inside the brain. Experiments were performed on a group
	of 14 volunteers. Ten cycles (1 min on, 1 min off) of 450-MHz microwave
	radiation modulated at 40 Hz were applied. Higuchi's FD was calculated
	in eight symmetric electroencephalographic (EEG) channels located
	in frontal, temporal, parietal, and occipital areas. FD values averaged
	over a group detected a small (1-2\%) but statistically significant
	increase with exposure in all EEG channels. FD increased for 12,
	decreased for one, and was constant for one subject. FD showed the
	most remarkable effect in temporal and parietal regions of the left
	hemisphere where the microwave field was maximal. Changes of FD in
	these regions of the right hemisphere were much higher than expected
	in accordance with the field distribution. Correlation of FD between
	different EEG channels was high and retained its value in exposed
	conditions. Spreading of disturbance between different brain areas
	is supposed to be crucial for the effect of exposure on the electrical
	oscillations in the brain.},
  comment = {ToRead},
  doi = {10.1007/s11517-011-0768-5},
  institution = {Department of Biomedical Engineering, Technomedicum, Tallinn University
	of Technology, Ehitajate Road 5, Tallinn, Estonia. hiie@cb.ttu.ee},
  keywords = {Biological Clocks, physiology; Brain, physiology/radiation effects;
	Electroencephalography, methods; Female; Fractals; Humans; Male;
	Microwaves; Signal Processing, Computer-Assisted; Young Adult},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {21465274},
  timestamp = {2013.04.09},
  url = {http://dx.doi.org/10.1007/s11517-011-0768-5}
}

@ARTICLE{Hlinka_2012,
  author = {Jaroslav Hlinka and Stephen Coombes},
  title = {Using computational models to relate structural and functional brain
	connectivity.},
  journal = {Eur. J. Neurosci.},
  year = {2012},
  volume = {36},
  pages = {2137--2145},
  number = {2},
  month = {Jul},
  abstract = {Modern imaging methods allow a non-invasive assessment of both structural
	and functional brain connectivity. This has lead to the identification
	of disease-related alterations affecting functional connectivity.
	The mechanism of how such alterations in functional connectivity
	arise in a structured network of interacting neural populations is
	as yet poorly understood. Here we use a modeling approach to explore
	the way in which this can arise and to highlight the important role
	that local population dynamics can have in shaping emergent spatial
	functional connectivity patterns. The local dynamics for a neural
	population is taken to be of the Wilson-Cowan type, whilst the structural
	connectivity patterns used, describing long-range anatomical connections,
	cover both realistic scenarios (from the CoComac database) and idealized
	ones that allow for more detailed theoretical study. We have calculated
	graph-theoretic measures of functional network topology from numerical
	simulations of model networks. The effect of the form of local dynamics
	on the observed network state is quantified by examining the correlation
	between structural and functional connectivity. We document a profound
	and systematic dependence of the simulated functional connectivity
	patterns on the parameters controlling the dynamics. Importantly,
	we show that a weakly coupled oscillator theory explaining these
	correlations and their variation across parameter space can be developed.
	This theoretical development provides a novel way to characterize
	the mechanisms for the breakdown of functional connectivity in diseases
	through changes in local dynamics.},
  doi = {10.1111/j.1460-9568.2012.08081.x},
  institution = {Institute of Computer Science, Academy of Sciences of the Czech Republic,
	Pod Vodarenskou vezi 271/2, 182 07 Prague 8, Czech Republic. hlinka@cs.cas.cz},
  keywords = {Brain, physiology; Computational Biology; Humans; Models, Neurological;
	Nerve Net, physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {22805059},
  timestamp = {2013.02.18},
  url = {http://dx.doi.org/10.1111/j.1460-9568.2012.08081.x}
}

@ARTICLE{Honey_2007,
  author = {Honey, C.J. and Kötter, R. and Breakspear, M. and Sporns, O.},
  title = {{Network structure of cerebral cortex shapes functional connectivity
	on multiple time scales}},
  journal = {Proc. Natl. Acad. Sci. U.S.A.},
  year = {2007},
  volume = {104},
  pages = {10240},
  number = {24},
  publisher = {National Acad Sciences}
}

@ARTICLE{Honey_2008,
  author = {Christopher J Honey and Olaf Sporns},
  title = {Dynamical consequences of lesions in cortical networks.},
  journal = {Hum. Brain Mapp.},
  year = {2008},
  volume = {29},
  pages = {802--809},
  number = {7},
  month = {Jul},
  abstract = {To understand the effects of a cortical lesion it is necessary to
	consider not only the loss of local neural function, but also the
	lesion-induced changes in the larger network of endogenous oscillatory
	interactions in the brain. To investigate how network embedding influences
	a region's functional role, and the consequences of its being damaged,
	we implement two models of oscillatory cortical interactions, both
	of which inherit their coupling architecture from the available anatomical
	connection data for macaque cerebral cortex. In the first model,
	node dynamics are governed by Kuramoto phase oscillator equations,
	and we investigate the sequence in which areas entrain one another
	in the transition to global synchrony. In the second model, node
	dynamics are governed by a more realistic neural mass model, and
	we assess long-run inter-regional interactions using a measure of
	directed information flow. Highly connected parietal and frontal
	areas are found to synchronize most rapidly, more so than equally
	highly connected visual and somatosensory areas, and this difference
	can be explained in terms of the network's clustered architecture.
	For both models, lesion effects extend beyond the immediate neighbors
	of the lesioned site, and the amplitude and dispersal of nonlocal
	effects are again influenced by cluster patterns in the network.
	Although the consequences of in vivo lesions will always depend on
	circuitry local to the damaged site, we conclude that lesions of
	parietal regions (especially areas 5 and 7a) and frontal regions
	(especially areas 46 and FEF) have the greatest potential to disrupt
	the integrative aspects of neocortical function.},
  doi = {10.1002/hbm.20579},
  institution = {Department of Psychological and Brain Sciences, Indiana University,
	Bloomington, Indiana 47405, USA.},
  keywords = {Animals; Cerebral Cortex, physiology; Macaca; Models, Neurological;
	Nerve Net, physiology; Neural Pathways, physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {18438885},
  timestamp = {2012.11.14},
  url = {http://dx.doi.org/10.1002/hbm.20579}
}

@ARTICLE{Honey_2009,
  author = {C. J. Honey and O. Sporns and L. Cammoun and X. Gigandet and J. P.
	Thiran and R. Meuli and P. Hagmann},
  title = {Predicting human resting-state functional connectivity from structural
	connectivity.},
  journal = {Proc. Natl. Acad. Sci. U.S.A.},
  year = {2009},
  volume = {106},
  pages = {2035--2040},
  number = {6},
  month = {Feb},
  abstract = {In the cerebral cortex, the activity levels of neuronal populations
	are continuously fluctuating. When neuronal activity, as measured
	using functional MRI (fMRI), is temporally coherent across 2 populations,
	those populations are said to be functionally connected. Functional
	connectivity has previously been shown to correlate with structural
	(anatomical) connectivity patterns at an aggregate level. In the
	present study we investigate, with the aid of computational modeling,
	whether systems-level properties of functional networks--including
	their spatial statistics and their persistence across time--can be
	accounted for by properties of the underlying anatomical network.
	We measured resting state functional connectivity (using fMRI) and
	structural connectivity (using diffusion spectrum imaging tractography)
	in the same individuals at high resolution. Structural connectivity
	then provided the couplings for a model of macroscopic cortical dynamics.
	In both model and data, we observed (i) that strong functional connections
	commonly exist between regions with no direct structural connection,
	rendering the inference of structural connectivity from functional
	connectivity impractical; (ii) that indirect connections and interregional
	distance accounted for some of the variance in functional connectivity
	that was unexplained by direct structural connectivity; and (iii)
	that resting-state functional connectivity exhibits variability within
	and across both scanning sessions and model runs. These empirical
	and modeling results demonstrate that although resting state functional
	connectivity is variable and is frequently present between regions
	without direct structural linkage, its strength, persistence, and
	spatial statistics are nevertheless constrained by the large-scale
	anatomical structure of the human cerebral cortex.},
  doi = {10.1073/pnas.0811168106},
  institution = {Department of Psychological and Brain Sciences, Indiana University,
	Bloomington, IN 47405, USA.},
  keywords = {Brain Mapping, methods; Brain, anatomy /&/ histology/physiology; Cerebral
	Cortex, physiology; Diffusion Magnetic Resonance Imaging; Humans;
	Magnetic Resonance Imaging; Models, Neurological; Neural Pathways,
	physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {0811168106},
  pmid = {19188601},
  timestamp = {2012.11.14},
  url = {http://dx.doi.org/10.1073/pnas.0811168106}
}

@ARTICLE{Honey_2010,
  author = {Christopher J Honey and Jean-Philippe Thivierge and Olaf Sporns},
  title = {Can structure predict function in the human brain?},
  journal = {Neuroimage},
  year = {2010},
  volume = {52},
  pages = {766--776},
  number = {3},
  month = {Sep},
  abstract = {Over the past decade, scientific interest in the properties of large-scale
	spontaneous neural dynamics has intensified. Concurrently, novel
	technologies have been developed for characterizing the connective
	anatomy of intra-regional circuits and inter-regional fiber pathways.
	It will soon be possible to build computational models that incorporate
	these newly detailed structural network measurements to make predictions
	of neural dynamics at multiple scales. Here, we review the practicality
	and the value of these efforts, while at the same time considering
	in which cases and to what extent structure does determine neural
	function. Studies of the healthy brain, of neural development, and
	of pathology all yield examples of direct correspondences between
	structural linkage and dynamical correlation. Theoretical arguments
	further support the notion that brain network topology and spatial
	embedding should strongly influence network dynamics. Although future
	models will need to be tested more quantitatively and against a wider
	range of empirical neurodynamic features, our present large-scale
	models can already predict the macroscopic pattern of dynamic correlation
	across the brain. We conclude that as neuroscience grapples with
	datasets of increasing completeness and complexity, and attempts
	to relate the structural and functional architectures discovered
	at different neural scales, the value of computational modeling will
	continue to grow.},
  doi = {10.1016/j.neuroimage.2010.01.071},
  institution = {Department of Psychology, Princeton University, Princeton, NJ 08540,
	USA.},
  keywords = {Brain, anatomy /&/ histology/physiology; Humans; Models, Neurological;
	Nerve Net; Neural Networks (Computer)},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S1053-8119(10)00093-5},
  pmid = {20116438},
  timestamp = {2012.11.14},
  url = {http://dx.doi.org/10.1016/j.neuroimage.2010.01.071}
}

@ARTICLE{Huang_1999d,
  author = {Huang, M. X. and Mosher, J. C. and Leahy, R. M.},
  title = {A sensor-weighted overlapping-sphere head model and exhaustive head
	model comparison for MEG.},
  journal = {Phys. Med. Biol.},
  year = {1999},
  volume = {44},
  pages = {423--440},
  number = {2},
  month = {Feb},
  abstract = {The spherical head model has been used in magnetoencephalography (MEG)
	as a simple forward model for calculating the external magnetic fields
	resulting from neural activity. For more realistic head shapes, the
	boundary element method (BEM) or similar numerical methods are used,
	but at greatly increased computational cost. We introduce a sensor-weighted
	overlapping-sphere (OS) head model for rapid calculation of more
	realistic head shapes. The volume currents associated with primary
	neural activity are used to fit spherical head models for each individual
	MEG sensor such that the head is more realistically modelled as a
	set of overlapping spheres, rather than a single sphere. To assist
	in the evaluation of this OS model with BEM and other head models,
	we also introduce a novel comparison technique that is based on a
	generalized eigenvalue decomposition and accounts for the presence
	of noise in the MEG data. With this technique we can examine the
	worst possible errors for thousands of dipole locations in a realistic
	brain volume. We test the traditional single-sphere model, three-shell
	and single-shell BEM, and the new OS model. The results show that
	the OS model has accuracy similar to the BEM but is orders of magnitude
	faster to compute.},
  institution = {Neuroimaging Center, New Mexico Regional Federal Medical Center,
	Albuquerque 87108, USA.},
  keywords = {Brain, anatomy /&/ histology/physiology; Head; Humans; Magnetoencephalography;
	Phantoms, Imaging},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paupau},
  pmid = {10070792},
  timestamp = {2013.02.17}
}

@ARTICLE{Hunter_2007,
  author = {Hunter, John D.},
  title = {Matplotlib: A 2D graphics environment},
  journal = {Computing in science \& engineering},
  year = {2007},
  volume = {9},
  pages = {90--95},
  number = {3},
  month = {May-Jun},
  abstract = {Matplotlib is a 2D graphics package used for Python for application
	development, interactive scripting, and publication-quality image
	generation across user interfaces and operating systems.},
  address = {10662 LOS VAQUEROS CIRCLE, PO BOX 3014, LOS ALAMITOS, CA 90720-1314
	USA},
  bdsk-url-1 = {http://gateway.isiknowledge.com/gateway/Gateway.cgi?GWVersion=2&SrcAuth=Alerting&SrcApp=Alerting&DestApp=WOS&DestLinkType=FullRecord;KeyUT=000245668100019},
  date-added = {2010-09-23 12:22:10 -0700},
  date-modified = {2010-09-23 12:22:10 -0700},
  isi = {000245668100019},
  isi-recid = {155389429},
  publisher = {IEEE COMPUTER SOC},
  times-cited = {21},
  type = {Editorial Material}
}

@ARTICLE{Hutt_2006,
  author = {Axel Hutt and Fatihcan M Atay},
  title = {Effects of distributed transmission speeds on propagating activity
	in neural populations.},
  journal = {Phys. Rev. E: Stat. Phys. Plasmas Fluids Relat. Interdisciplin. Top.},
  year = {2006},
  volume = {73},
  pages = {021906},
  number = {2 Pt 1},
  month = {Feb},
  abstract = {Motivated by experimental evidence, a distribution of axonal transmission
	speeds is introduced into a standard field model of neural populations.
	The resulting field dynamics is analytically studied by a systematic
	investigation of the stability and bifurcations of equilibrium solutions.
	Using a perturbation approach, the effect of distributed speeds on
	bifurcations of equilibria are determined for general connectivity
	and speed distributions. In addition, a nonlinear analysis of traveling
	fronts is given. It is shown that the variance of the speed distribution
	affects the frequency of bifurcating periodic solutions and the phase
	speed of traveling waves. Moreover, a new effect is discovered where
	the introduction of axonal speed distributions leads to the maximization
	of the traveling front speed.},
  institution = {Humboldt University at Berlin, 12489 Berlin, Germany. axel.hutt@physik.hu-berlin.de},
  keywords = {Action Potentials, physiology; Animals; Brain, physiology; Computer
	Simulation; Humans; Models, Neurological; Nerve Net, physiology;
	Neural Conduction, physiology; Neurons, physiology; Synaptic Transmission,
	physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {16605361},
  timestamp = {2013.04.29}
}

@ARTICLE{Ince_2010,
  author = {Robin A A Ince and Alberto Mazzoni and Rasmus S Petersen and Stefano
	Panzeri},
  title = {Open source tools for the information theoretic analysis of neural
	data.},
  journal = {Front. Neurosc.},
  year = {2010},
  volume = {4},
  pages = {--},
  abstract = {The recent and rapid development of open source software tools for
	the analysis of neurophysiological datasets consisting of simultaneous
	multiple recordings of spikes, field potentials and other neural
	signals holds the promise for a significant advance in the standardization,
	transparency, quality, reproducibility and variety of techniques
	used to analyze neurophysiological data and for the integration of
	information obtained at different spatial and temporal scales. In
	this review we focus on recent advances in open source toolboxes
	for the information theoretic analysis of neural responses. We also
	present examples of their use to investigate the role of spike timing
	precision, correlations across neurons, and field potential fluctuations
	in the encoding of sensory information. These information toolboxes,
	available both in MATLAB and Python programming environments, hold
	the potential to enlarge the domain of application of information
	theory to neuroscience and to lead to new discoveries about how neurons
	encode and transmit information.},
  doi = {10.3389/neuro.01.011.2010},
  institution = {Faculty of Life Sciences, University of Manchester Manchester, UK.},
  language = {eng},
  medline-pst = {epublish},
  owner = {paula},
  pmid = {20730105},
  timestamp = {2013.02.01},
  url = {http://dx.doi.org/10.3389/neuro.01.011.2010}
}

@ARTICLE{Ince_2009,
  author = {Robin A A Ince and Rasmus S Petersen and Daniel C Swan and Stefano
	Panzeri},
  title = {Python for information theoretic analysis of neural data.},
  journal = {Front. Neuroinform.},
  year = {2009},
  volume = {3},
  pages = {4},
  abstract = {Information theory, the mathematical theory of communication in the
	presence of noise, is playing an increasingly important role in modern
	quantitative neuroscience. It makes it possible to treat neural systems
	as stochastic communication channels and gain valuable, quantitative
	insights into their sensory coding function. These techniques provide
	results on how neurons encode stimuli in a way which is independent
	of any specific assumptions on which part of the neuronal response
	is signal and which is noise, and they can be usefully applied even
	to highly non-linear systems where traditional techniques fail. In
	this article, we describe our work and experiences using Python for
	information theoretic analysis. We outline some of the algorithmic,
	statistical and numerical challenges in the computation of information
	theoretic quantities from neural data. In particular, we consider
	the problems arising from limited sampling bias and from calculation
	of maximum entropy distributions in the presence of constraints representing
	the effects of different orders of interaction in the system. We
	explain how and why using Python has allowed us to significantly
	improve the speed and domain of applicability of the information
	theoretic algorithms, allowing analysis of data sets characterized
	by larger numbers of variables. We also discuss how our use of Python
	is facilitating integration with collaborative databases and centralised
	computational resources.},
  doi = {10.3389/neuro.11.004.2009},
  institution = {Faculty of Life Sciences, University of Manchester Manchester, UK.},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {19242557},
  timestamp = {2013.02.01},
  url = {http://dx.doi.org/10.3389/neuro.11.004.2009}
}

@ARTICLE{Iturria-Medina_2013,
  author = {Yasser Iturria-Medina},
  title = {Anatomical brain networks on the prediction of abnormal brain states.},
  journal = {Brain Connect},
  year = {2013},
  volume = {3},
  pages = {1--21},
  number = {1},
  abstract = {Graph-based brain anatomical network analysis models the brain as
	a graph whose nodes represent structural/functional regions, whereas
	the links between them represent nervous fiber connections. Initial
	studies of brain anatomical networks using this approach were devoted
	to describe the key organizational principles of the normal brain,
	while current trends seem to be more focused on detecting network
	alterations associated to specific brain disorders. Anatomical networks
	reconstructed using diffusion-weighed magnetic resonance-imaging
	techniques can be particularly useful in predicting abnormal brain
	states in which the white matter structure and, subsequently, the
	interconnections between gray matter regions are altered (e.g., due
	to the presence of diseases such as schizophrenia, stroke, multiple
	sclerosis, and dementia). This article offers an overview from early
	gross connectional anatomy explorations until more recent advances
	on anatomical brain network reconstruction approaches, with a specific
	focus on how the latter move toward the prediction of abnormal brain
	states. While anatomical graph-based predictor approaches are still
	at an early stage, they bear promising implications for individualized
	clinical diagnosis of neurological and psychiatric disorders, as
	well as for neurodevelopmental evaluations and subsequent assisted
	creation of educational strategies related to specific cognitive
	disorders.},
  doi = {10.1089/brain.2012.0122},
  institution = {Cuban Neuroscience Center, Havana, Cuba. Iturria.medina@gmail.com},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {23249224},
  timestamp = {2013.07.04},
  url = {http://dx.doi.org/10.1089/brain.2012.0122}
}

@ARTICLE{Iturria-Medina_2007,
  author = {Y. Iturria-Medina and E. J. Canales-Rodríguez and L. Melie-García
	and P. A. Valdés-Hernández and E. Martínez-Montes and Y. Alemán-Gómez
	and J. M. Sánchez-Bornot},
  title = {Characterizing brain anatomical connections using diffusion weighted
	MRI and graph theory.},
  journal = {Neuroimage},
  year = {2007},
  volume = {36},
  pages = {645--660},
  number = {3},
  month = {Jul},
  abstract = {A new methodology based on Diffusion Weighted Magnetic Resonance Imaging
	(DW-MRI) and Graph Theory is presented for characterizing the anatomical
	connections between brain gray matter areas. In a first step, brain
	voxels are modeled as nodes of a non-directed graph in which the
	weight of an arc linking two neighbor nodes is assumed to be proportional
	to the probability of being connected by nervous fibers. This probability
	is estimated by means of probabilistic tissue segmentation and intravoxel
	white matter orientational distribution function, obtained from anatomical
	MRI and DW-MRI, respectively. A new tractography algorithm for finding
	white matter routes is also introduced. This algorithm solves the
	most probable path problem between any two nodes, leading to the
	assessment of probabilistic brain anatomical connection maps. In
	a second step, for assessing anatomical connectivity between K gray
	matter structures, the previous graph is redefined as a K+1 partite
	graph by partitioning the initial nodes set in K non-overlapped gray
	matter subsets and one subset clustering the remaining nodes. Three
	different measures are proposed for quantifying anatomical connections
	between any pair of gray matter subsets: Anatomical Connection Strength
	(ACS), Anatomical Connection Density (ACD) and Anatomical Connection
	Probability (ACP). This methodology was applied to both artificial
	and actual human data. Results show that nervous fiber pathways between
	some regions of interest were reconstructed correctly. Additionally,
	mean connectivity maps of ACS, ACD and ACP between 71 gray matter
	structures for five healthy subjects are presented.},
  doi = {10.1016/j.neuroimage.2007.02.012},
  institution = {Neuroimaging Department, Cuban Neuroscience Center, Cubanacán, Playa,
	Havana, Cuba. iturria@cneuro.edu.cu},
  keywords = {Algorithms; Brain, anatomy /&/ histology; Computer Graphics; Diffusion
	Magnetic Resonance Imaging, methods/statistics /&/ numerical data;
	Humans; Image Processing, Computer-Assisted, statistics /&/ numerical
	data; Models, Anatomic; Models, Statistical; Nerve Fibers, physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S1053-8119(07)00105-X},
  pmid = {17466539},
  timestamp = {2013.07.04},
  url = {http://dx.doi.org/10.1016/j.neuroimage.2007.02.012}
}

@ARTICLE{Iturria-Medina2011,
  author = {Yasser Iturria-Medina and Alejandro Pérez Fernández and Pedro Valdés
	Hernández and Lorna García Pentón and Erick J Canales-Rodríguez and
	Lester Melie-Garcia and Agustin Lage Castellanos and Marlis Ontivero
	Ortega},
  title = {Automated discrimination of brain pathological state attending to
	complex structural brain network properties: the shiverer mutant
	mouse case.},
  journal = {PLoS One},
  year = {2011},
  volume = {6},
  pages = {e19071},
  number = {5},
  abstract = {Neuroimaging classification procedures between normal and pathological
	subjects are sparse and highly dependent of an expert's clinical
	criterion. Here, we aimed to investigate whether possible brain structural
	network differences in the shiverer mouse mutant, a relevant animal
	model of myelin related diseases, can reflect intrinsic individual
	brain properties that allow the automatic discrimination between
	the shiverer and normal subjects. Common structural networks properties
	between shiverer (C3Fe.SWV Mbp(shi)/Mbp(shi), n = 6) and background
	control (C3HeB.FeJ, n = 6) mice are estimated and compared by means
	of three diffusion weighted MRI (DW-MRI) fiber tractography algorithms
	and a graph framework. Firstly, we found that brain networks of control
	group are significantly more clustered, modularized, efficient and
	optimized than those of the shiverer group, which presented significantly
	increased characteristic path length. These results are in line with
	previous structural/functional complex brain networks analysis that
	have revealed topologic differences and brain network randomization
	associated to specific states of human brain pathology. In addition,
	by means of network measures spatial representations and discrimination
	analysis, we show that it is possible to classify with high accuracy
	to which group each subject belongs, providing also a probability
	value of being a normal or shiverer subject as an individual anatomical
	classifier. The obtained correct predictions (e.g., around 91.6-100\%)
	and clear spatial subdivisions between control and shiverer mice,
	suggest that there might exist specific network subspaces corresponding
	to specific brain disorders, supporting also the point of view that
	complex brain network analyses constitutes promising tools in the
	future creation of interpretable imaging biomarkers.},
  doi = {10.1371/journal.pone.0019071},
  institution = {Neuroimaging Department, Cuban Neuroscience Center, La Habana, Cuba.
	iturria.medina@gmail.com},
  keywords = {Animals; Automation; Brain, pathology/physiopathology; Cluster Analysis;
	Diffusion Magnetic Resonance Imaging; Mice; Mice, Neurologic Mutants;
	Nerve Net, physiopathology; Shivering, physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {PONE-D-11-01212},
  pmid = {21637753},
  timestamp = {2013.07.04},
  url = {http://dx.doi.org/10.1371/journal.pone.0019071}
}

@ARTICLE{Iturria-Medina2011a,
  author = {Yasser Iturria-Medina and Alejandro Pérez Fernández and David M Morris
	and Erick J Canales-Rodríguez and Hamied A Haroon and Lorna García
	Pentón and Mark Augath and Lídice Galán García and Nikos Logothetis
	and Geoffrey J M Parker and Lester Melie-García},
  title = {Brain hemispheric structural efficiency and interconnectivity rightward
	asymmetry in human and nonhuman primates.},
  journal = {Cereb Cortex},
  year = {2011},
  volume = {21},
  pages = {56--67},
  number = {1},
  month = {Jan},
  abstract = {Evidence for interregional structural asymmetries has been previously
	reported for brain anatomic regions supporting well-described functional
	lateralization. Here, we aimed to investigate whether the two brain
	hemispheres demonstrate dissimilar general structural attributes
	implying different principles on information flow management. Common
	left hemisphere/right hemisphere structural network properties are
	estimated and compared for right-handed healthy human subjects and
	a nonhuman primate, by means of 3 different diffusion-weighted magnetic
	resonance imaging fiber tractography algorithms and a graph theory
	framework. In both the human and the nonhuman primate, the data support
	the conclusion that, in terms of the graph framework, the right hemisphere
	is significantly more efficient and interconnected than the left
	hemisphere, whereas the left hemisphere presents more central or
	indispensable regions for the whole-brain structural network than
	the right hemisphere. From our point of view, in terms of functional
	principles, this pattern could be related with the fact that the
	left hemisphere has a leading role for highly demanding specific
	process, such as language and motor actions, which may require dedicated
	specialized networks, whereas the right hemisphere has a leading
	role for more general process, such as integration tasks, which may
	require a more general level of interconnection.},
  doi = {10.1093/cercor/bhq058},
  institution = {Neuroimaging Department, Cuban Neuroscience Center, CP 10 600, La
	Habana, Cuba. iturria.medina@gmail.com},
  keywords = {Adult; Algorithms; Animals; Brain Mapping, methods; Cerebrum, anatomy
	/&/ histology/physiology; Diffusion Tensor Imaging, methods; Dominance,
	Cerebral, physiology; Functional Laterality, physiology; Humans;
	Macaca mulatta; Magnetic Resonance Imaging, methods; Nerve Net, anatomy
	/&/ histology/physiology; Neural Pathways, anatomy /&/ histology/physiology;
	Neuropsychological Tests, standards; Species Specificity; Young Adult},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {bhq058},
  pmid = {20382642},
  timestamp = {2013.07.04},
  url = {http://dx.doi.org/10.1093/cercor/bhq058}
}

@ARTICLE{Iturria-Medina_2008,
  author = {Yasser Iturria-Medina and Roberto C Sotero and Erick J Canales-Rodríguez
	and Yasser Alemán-Gómez and Lester Melie-García},
  title = {Studying the human brain anatomical network via diffusion-weighted
	MRI and Graph Theory.},
  journal = {Neuroimage},
  year = {2008},
  volume = {40},
  pages = {1064--1076},
  number = {3},
  month = {Apr},
  abstract = {Our goal is to study the human brain anatomical network. For this,
	the anatomical connection probabilities (ACP) between 90 cortical
	and subcortical brain gray matter areas are estimated from diffusion-weighted
	Magnetic Resonance Imaging (DW-MRI) techniques. The ACP between any
	two areas gives the probability that those areas are connected at
	least by a single nervous fiber. Then, the brain is modeled as a
	non-directed weighted graph with continuous arc weights given by
	the ACP matrix. Based on this approach, complex networks properties
	such as small-world attributes, efficiency, degree distribution,
	vulnerability, betweenness centrality and motifs composition are
	studied. The analysis was carried out for 20 right-handed healthy
	subjects (mean age: 31.10, S.D.: 7.43). According to the results,
	all networks have small-world and broad-scale characteristics. Additionally,
	human brain anatomical networks present bigger local efficiency and
	smaller global efficiency than the corresponding random networks.
	In a vulnerability and betweenness centrality analysis, the most
	indispensable and critical anatomical areas were identified: putamens,
	precuneus, insulas, superior parietals and superior frontals. Interestingly,
	some areas have a negative vulnerability (e.g. superior temporal
	poles, pallidums, supramarginals and hechls), which suggest that
	even at the cost of losing in global anatomical efficiency, these
	structures were maintained through the evolutionary processes due
	to their important functions. Finally, symmetrical characteristic
	building blocks (motifs) of size 3 and 4 were calculated, obtaining
	that motifs of size 4 are the expanded version of motif of size 3.
	These results are in agreement with previous anatomical studies in
	the cat and macaque cerebral cortex.},
  doi = {10.1016/j.neuroimage.2007.10.060},
  institution = {Neuroimaging Department, Cuban Neuroscience Center, Avenue 25, Esq
	158, \#15202, PO Box 6412, Cubanacán, Playa, Havana, Cuba. iturria@cneuro.edu.cu},
  keywords = {Adult; Algorithms; Brain, anatomy /&/ histology; Diffusion Magnetic
	Resonance Imaging; Humans; Image Processing, Computer-Assisted; Male;
	Nerve Fibers, physiology; Nerve Net, anatomy /&/ histology; Neural
	Pathways, anatomy /&/ histology/physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S1053-8119(07)01001-4},
  pmid = {18272400},
  timestamp = {2013.07.04},
  url = {http://dx.doi.org/10.1016/j.neuroimage.2007.10.060}
}

@ARTICLE{Izhikevich_Edelman_2008,
  author = {Izhikevich, E.M. and Edelman, G.M.},
  title = {{Large-scale model of mammalian thalamocortical systems}},
  journal = {Proc. Natl. Acad. Sci. U.S.A.},
  year = {2008},
  volume = {105},
  pages = {3593},
  number = {9},
  publisher = {National Acad Sciences}
}

@ARTICLE{Jansen_1995,
  author = {Jansen, BH and Rit, VG},
  title = {Electroencephalogram and visual evoked potential generation in a
	mathematical model of coupled cortical columns},
  journal = {Biol. Cybern.},
  year = {1995},
  volume = {73},
  pages = {357-366},
  number = {4},
  month = {September},
  abstract = {This study deals with neurophysiologically based models simulating
	electrical brain activity (i.e., the electroencephalogram or EEG,
	and evoked potentials or EPs). A previously developed lumped-parameter
	model of a single cortical column was implemented using a more accurate
	computational procedure. Anatomically acceptable values for the various
	model parameters were determined, and a multi-dimensional exploration
	of the model parameter-space was conducted. It was found that the
	model could produce a large variety of EEG-like waveforms and rhythms.
	Coupling two models, with delays in the interconnections to simulate
	the synaptic connections within and between cortical areas, made
	it possible to replicate the spatial distribution of alpha and beta
	activity. EPs were simulated by presenting pulses to the input of
	the coupled models. In general, the responses were more realistic
	than those produced using a single model. Our simulations also suggest
	that the scalp-recorded EP is at least partially due to a phase reordering
	of the ongoing activity.},
  keywords = {model, stimulation},
  owner = {paula},
  timestamp = {2012.10.18}
}

@ARTICLE{Jansen_1993,
  author = {Jansen, B. and Zouridakis, G. and Brandt, M.},
  title = {A neurophysiologically-based mathematical model of flash visual evoked
	potentials.},
  journal = {Biol. Cybern.},
  year = {1993},
  volume = {68},
  pages = {275-283},
  number = {3},
  keywords = {model, evoked potential, stimulation},
  owner = {paupau},
  timestamp = {2012.10.21}
}

@ARTICLE{Jenkinson_2012,
  author = {Jenkinson, Mark and Beckmann, Christian F. and Behrens, Timothy E
	J. and Woolrich, Mark W. and Smith, Stephen M.},
  title = {FSL.},
  journal = {Neuroimage},
  year = {2012},
  volume = {62},
  pages = {782--790},
  number = {2},
  month = {Aug},
  abstract = {FSL (the FMRIB Software Library) is a comprehensive library of analysis
	tools for functional, structural and diffusion MRI brain imaging
	data, written mainly by members of the Analysis Group, FMRIB, Oxford.
	For this NeuroImage special issue on "20 years of fMRI" we have been
	asked to write about the history, developments and current status
	of FSL. We also include some descriptions of parts of FSL that are
	not well covered in the existing literature. We hope that some of
	this content might be of interest to users of FSL, and also maybe
	to new research groups considering creating, releasing and supporting
	new software packages for brain image analysis.},
  doi = {10.1016/j.neuroimage.2011.09.015},
  institution = {FMRIB Centre, Nuffield Department of Clinical Neurosciences, University
	of Oxford, UK.},
  keywords = {Brain Mapping, history/methods; Brain, anatomy /&/ histology/physiology;
	Diffusion Magnetic Resonance Imaging, history/methods; History, 20th
	Century; History, 21st Century; Humans; Image Processing, Computer-Assisted,
	history/methods; Software, history},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paupau},
  pii = {S1053-8119(11)01060-3},
  pmid = {21979382},
  timestamp = {2013.10.24},
  url = {http://dx.doi.org/10.1016/j.neuroimage.2011.09.015}
}

@ARTICLE{Jespersen_2000,
  author = {Jespersen and Sokolov and Blumen},
  title = {Relaxation properties of small-world networks},
  journal = {Phys Rev E Stat Phys Plasmas Fluids Relat Interdiscip Topics},
  year = {2000},
  volume = {62},
  pages = {4405--4408},
  number = {3 Pt B},
  month = {Sep},
  __markedentry = {[paupau:]},
  abstract = {Recently, Watts and Strogatz introduced the so-called small-world
	networks in order to describe systems that combine simultaneously
	properties of regular and random lattices. In this work we study
	diffusion processes defined on such structures by considering explicitly
	the probability for a random walker to be present at the origin.
	The results are intermediate between the corresponding ones for fractals
	and Cayley trees.},
  institution = {Institute of Physics and Astronomy, University of Arhus, DK-8000
	Arhus C, Denmark and Theoretische Polymerphysik, Universitat Freiburg,
	D-79104 Freiburg i.Br., Germany.},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paupau},
  pmid = {11088974},
  timestamp = {2013.10.27}
}

@ARTICLE{Jirsa_2009,
  author = {Jirsa, VK},
  title = {Neural field dynamics with local and global connectivity and time
	delay},
  journal = {Philos. Trans. R Soc. Lond. A.},
  year = {2009},
  volume = {367},
  pages = {1131-1143},
  number = {1891},
  owner = {paula},
  timestamp = {2012.10.18}
}

@ARTICLE{Jirsa_2004,
  author = {Jirsa, VK},
  title = {Connectivity and dynamics of neural information processing.},
  journal = {Neuroinformatics},
  year = {2004},
  volume = {2},
  pages = {183--204},
  number = {2},
  abstract = {In this article, we systematically review the current literature on
	neural connectivity and dynamics, or equivalently, structure and
	function. In particular, we discuss how changes in the connectivity
	of a neural network affect the spatiotemporal network dynamics qualitatively.
	The three major criteria of comparison are, first, the local dynamics
	at the network nodes which includes fixed point dynamics, oscillatory
	and chaotic dynamics; second, the presence of time delays via propagation
	along connecting pathways; and third, the properties of the connectivity
	matrix such as its statistics, symmetry, and translational invariance.
	Since the connection topology changes when anatomical scales are
	traversed, so will the corresponding network dynamics change. As
	a consequence different types of networks are encountered on different
	levels of neural organization.},
  doi = {10.1385/NI:2:2:183},
  institution = {Center for Complex Systems and Brain Sciences, Physics Department,
	Florida Atlantic University, Boca Raton 33431, USA. jirsa@ccs.fau.edu},
  keywords = {Animals; Brain, physiology; Humans; Models, Neurological; Neural Networks
	(Computer); Neural Pathways, physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {NI:2:2:183},
  pmid = {15319516},
  timestamp = {2013.02.28},
  url = {http://dx.doi.org/10.1385/NI:2:2:183}
}

@ARTICLE{Jirsa_1997,
  author = {Jirsa, VK and Haken, H.},
  title = {A derivation of a macroscopic field theory of the brain from the
	quasi-microscopic neural dynamics},
  journal = {Phys. D},
  year = {1997},
  volume = {99},
  pages = {503-526(24)},
  number = {4},
  month = {January},
  owner = {paula},
  timestamp = {2013.02.28}
}

@ARTICLE{Jirsa_1996,
  author = {Jirsa, VK and Haken, H},
  title = {Field theory of electromagnetic brain activity},
  journal = {Phys. Rev. Lett.},
  year = {1996},
  volume = {77},
  pages = {960-963},
  number = {5},
  month = {dynamics},
  owner = {paula},
  timestamp = {2012.10.18}
}

@ARTICLE{Jirsa_2002,
  author = {Jirsa, VK and Jantzen, KJ and Fuchs, A and Kelso, JA},
  title = {Spatiotemporal forward solution of the EEG and MEG using network
	modeling},
  journal = {IEEE Trans. Med. Imag.},
  year = {2002},
  volume = {21},
  pages = {493-504},
  number = {5},
  month = {May},
  keywords = {forward solution, EEG, MEG},
  owner = {paula},
  timestamp = {2012.10.18}
}

@ARTICLE{Jirsa_2000,
  author = {Jirsa, VK and J. A. Kelso},
  title = {Spatiotemporal pattern formation in neural systems with heterogeneous
	connection topologies.},
  journal = {Phys. Rev. E: Stat. Phys. Plasmas Fluids Relat. Interdisciplin. Top.},
  year = {2000},
  volume = {62},
  pages = {8462--8465},
  number = {6 Pt B},
  month = {Dec},
  abstract = {Biological systems like the human cortex show homogeneous connectivity,
	with additional strongly heterogeneous projections from one area
	to another. Here we report how such a dynamic system performs a macroscopically
	coherent pattern formation. The connection topology is used systematically
	as a control parameter to guide the neural system through a series
	of phase transitions. We discuss the example of a two-point connection,
	and its destabilization mechanism.},
  institution = {Center for Complex Systems and Brain Sciences, Florida Atlantic University,
	Boca Raton, Florida 33431, USA. jirsa@walt.ccs.fau.edu},
  keywords = {Biophysical Phenomena; Biophysics; Cerebral Cortex, growth /&/ development/physiology;
	Humans; Models, Neurological; Nerve Net, growth /&/ development/physiology;
	Neurons, physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {11138148},
  timestamp = {2013.02.18}
}

@ARTICLE{Jirsa_2010b,
  author = {Jirsa, VK and O. Sporns and M. Breakspear and G. Deco and A. R. McIntosh},
  title = {Towards the virtual brain: network modeling of the intact and the
	damaged brain.},
  journal = {Arch. Ital. Biol.},
  year = {2010},
  volume = {148},
  pages = {189--205},
  number = {3},
  month = {Sep},
  abstract = {Neurocomputational models of large-scale brain dynamics utilizing
	realistic connectivity matrices have advanced our understanding of
	the operational network principles in the brain. In particular, spontaneous
	or resting state activity has been studied on various scales of spatial
	and temporal organization including those that relate to physiological,
	encephalographic and hemodynamic data. In this article we focus on
	the brain from the perspective of a dynamic network and discuss the
	role of its network constituents in shaping brain dynamics. These
	constituents include the brain's structural connectivity, the population
	dynamics of its network nodes and the time delays involved in signal
	transmission. In addition, no discussion of brain dynamics would
	be complete without considering noise and stochastic effects. In
	fact, there is mounting evidence that the interaction between noise
	and dynamics plays an important functional role in shaping key brain
	processes. In particular, we discuss a unifying theoretical framework
	that explains how structured spatio-temporal resting state patterns
	emerge from noise driven explorations of unstable or stable oscillatory
	states. Embracing this perspective, we explore the consequences of
	network manipulations to understand some of the brain's dysfunctions,
	as well as network effects that offer new insights into routes towards
	therapy, recovery and brain repair. These collective insights will
	be at the core of a new computational environment, the Virtual Brain,
	which will allow flexible incorporation of empirical data constraining
	the brain models to integrate, unify and predict network responses
	to incipient pathological processes.},
  institution = {Theoretical Neuroscience Group, CNRS UMR 6233, Université de la Méditerranée,
	Institute of Movement Sciences, Faculté des Sciences du Sport, Marseille,
	France. viktor.jirsa@univmed.fr},
  keywords = {Animals; Brain Injuries, pathology/physiopathology; Brain Mapping;
	Brain, anatomy /&/ histology/physiology; Humans; Models, Neurological;
	Nerve Net, physiology; Neural Pathways, physiology; Nonlinear Dynamics;
	User-Computer Interface},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {21175008},
  timestamp = {2012.11.14}
}

@ARTICLE{Jirsa_2010,
  author = {Jirsa, VK and Stefanescu, RA},
  title = {Neural population modes capture biologically realistic large scale
	network dynamics},
  journal = {Bull. Math. Biol.},
  year = {2010},
  volume = {73},
  pages = {325-343},
  number = {2},
  owner = {paula},
  timestamp = {2012.10.18}
}

@ARTICLE{Kelly_2012,
  author = {Clare Kelly and Bharat B Biswal and R. Cameron Craddock and F. Xavier
	Castellanos and Michael P Milham},
  title = {Characterizing variation in the functional connectome: promise and
	pitfalls.},
  journal = {Trends Cogn Sci},
  year = {2012},
  volume = {16},
  pages = {181--188},
  number = {3},
  month = {Mar},
  abstract = {The functional MRI (fMRI) community has zealously embraced resting
	state or intrinsic functional connectivity approaches to mapping
	brain organization. Having demonstrated their utility for charting
	the large-scale functional architecture of the brain, the field is
	now leveraging task-independent methods for the investigation of
	phenotypic variation and the identification of biomarkers for clinical
	conditions. Enthusiasm aside, questions regarding the significance
	and validity of intrinsic brain phenomena remain. Here, we discuss
	these challenges and outline current developments that, in moving
	the field toward discovery science, permit a shift from cartography
	toward a mechanistic understanding of the neural bases of variation
	in cognition, emotion and behavior.},
  doi = {10.1016/j.tics.2012.02.001},
  institution = {Phyllis Green and Randolph Cowen Institute for Pediatric Neuroscience,
	New York University Child Study Center, New York, NY 10016, USA.},
  keywords = {Brain Mapping, methods/trends; Brain, physiology; Humans; Magnetic
	Resonance Imaging, methods/trends; Rest, physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S1364-6613(12)00033-2},
  pmid = {22341211},
  timestamp = {2013.08.20},
  url = {http://dx.doi.org/10.1016/j.tics.2012.02.001}
}

@BOOK{Kelso_1995,
  title = {Dynamic patterns: the self-organization of brain and behavior (Complex
	Adaptive Systems)},
  publisher = {MIT Press},
  year = {1995},
  author = {SJA Kelso},
  owner = {paula},
  timestamp = {2012.10.18}
}

@ARTICLE{Kerr_2013,
  author = {Cliff C Kerr and Sacha J Van Albada and Samuel A Neymotin and George
	L Chadderdon and P. A. Robinson and William W Lytton},
  title = {Cortical information flow in Parkinson's disease: a composite network/field
	model.},
  journal = {Front Comput Neurosci},
  year = {2013},
  volume = {7},
  pages = {39},
  abstract = {The basal ganglia play a crucial role in the execution of movements,
	as demonstrated by the severe motor deficits that accompany Parkinson's
	disease (PD). Since motor commands originate in the cortex, an important
	question is how the basal ganglia influence cortical information
	flow, and how this influence becomes pathological in PD. To explore
	this, we developed a composite neuronal network/neural field model.
	The network model consisted of 4950 spiking neurons, divided into
	15 excitatory and inhibitory cell populations in the thalamus and
	cortex. The field model consisted of the cortex, thalamus, striatum,
	subthalamic nucleus, and globus pallidus. Both models have been separately
	validated in previous work. Three field models were used: one with
	basal ganglia parameters based on data from healthy individuals,
	one based on data from individuals with PD, and one purely thalamocortical
	model. Spikes generated by these field models were then used to drive
	the network model. Compared to the network driven by the healthy
	model, the PD-driven network had lower firing rates, a shift in spectral
	power toward lower frequencies, and higher probability of bursting;
	each of these findings is consistent with empirical data on PD. In
	the healthy model, we found strong Granger causality between cortical
	layers in the beta and low gamma frequency bands, but this causality
	was largely absent in the PD model. In particular, the reduction
	in Granger causality from the main "input" layer of the cortex (layer
	4) to the main "output" layer (layer 5) was pronounced. This may
	account for symptoms of PD that seem to reflect deficits in information
	flow, such as bradykinesia. In general, these results demonstrate
	that the brain's large-scale oscillatory environment, represented
	here by the field model, strongly influences the information processing
	that occurs within its subnetworks. Hence, it may be preferable to
	drive spiking network models with physiologically realistic inputs
	rather than pure white noise.},
  doi = {10.3389/fncom.2013.00039},
  institution = {Department of Physiology and Pharmacology, State University of New
	York Downstate Medical Center Brooklyn, NY, USA ; School of Physics,
	University of Sydney NSW, Australia ; Brain Dynamics Centre, Westmead
	Millennium Institute Westmead, NSW, Australia.},
  language = {eng},
  medline-pst = {epublish},
  owner = {paula},
  pmid = {23630492},
  timestamp = {2013.08.19},
  url = {http://dx.doi.org/10.3389/fncom.2013.00039}
}

@ARTICLE{Kerr_2011,
  author = {C. C. Kerr and C. J. Rennie and P. A. Robinson},
  title = {Model-based analysis and quantification of age trends in auditory
	evoked potentials.},
  journal = {Clin. Neurophysiol.},
  year = {2011},
  volume = {122},
  pages = {134--147},
  number = {1},
  month = {Jan},
  abstract = {The physiological basis for the changes in auditory evoked potentials
	(AEPs) during development and aging is currently unknown. This study
	investigates age- and task-related changes via a mathematical model
	of neuronal activity, which allows a number of physiological changes
	to be inferred.A quantitative, physiology-based model of activity
	in cortical and thalamic neurons was used to analyze oddball AEPs
	recorded from 1498 healthy subjects aged 6-86 years.Differences between
	standard and target responses can be largely explained by differences
	in connection strengths between thalamic and cortical neurons. The
	time it takes signals to travel between the thalamus and cortex decreases
	during development and increases during aging. Strong age trends
	are also seen in intracortical and thalamocortical neuronal connection
	strengths.Changes in AEP latency can be attributed to changes in
	the thalamocortical signal propagation time. Large changes in the
	connection strengths between neuronal populations occur during development,
	resulting in increased thalamocortical inhibition and decreased thalamocortical
	excitation. Standard and target parameters are similar in children
	but diverge during adolescence, due to changes in thalamocortical
	loop activity.Model-based AEP analysis links age-related changes
	in brain electrophysiology to underlying changes in brain anatomy
	and physiology, and yields quantitative predictions of several currently
	unknown physiological and anatomical properties of the brain.},
  doi = {10.1016/j.clinph.2010.05.030},
  institution = {School of Physics, University of Sydney, New South Wales 2006, Australia.
	ckerr@physics.usyd.edu.au},
  keywords = {Acoustic Stimulation, methods; Adolescent; Adult; Aged; Aged, 80 and
	over; Aging, physiology; Auditory Perception, physiology; Brain,
	anatomy /&/ histology/growth /&/ development; Child; Electroencephalography,
	methods; Evoked Potentials, Auditory, physiology; Female; Humans;
	Male; Middle Aged; Models, Neurological; Young Adult},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S1388-2457(10)00497-9},
  pmid = {20594907},
  timestamp = {2013.02.18},
  url = {http://dx.doi.org/10.1016/j.clinph.2010.05.030}
}

@ARTICLE{Kiebel_2006,
  author = {Stefan J Kiebel and Olivier David and Karl J Friston},
  title = {Dynamic causal modelling of evoked responses in EEG/MEG with lead
	field parameterization.},
  journal = {Neuroimage},
  year = {2006},
  volume = {30},
  pages = {1273--1284},
  number = {4},
  month = {May},
  abstract = {Dynamical causal modeling (DCM) of evoked responses is a new approach
	to making inferences about connectivity changes in hierarchical networks
	measured with electro- and magnetoencephalography (EEG and MEG).
	In a previous paper, we illustrated this concept using a lead field
	that was specified with infinite prior precision. With this prior,
	the spatial expression of each source area, in the sensors, is fixed.
	In this paper, we show that using lead field parameters with finite
	precision enables the data to inform the network's spatial configuration
	and its expression at the sensors. This means that lead field and
	coupling parameters can be estimated simultaneously. Alternatively,
	one can also view DCM for evoked responses as a source reconstruction
	approach with temporal, physiologically informed constraints. We
	will illustrate this idea using, for each area, a 4-shell equivalent
	current dipole (ECD) model with three location and three orientation
	parameters. Using synthetic and real data, we show that this approach
	furnishes accurate and robust conditional estimates of coupling among
	sources and their orientations.},
  doi = {10.1016/j.neuroimage.2005.12.055},
  institution = {Wellcome Department of Imaging Neuroscience, Functional Imaging Laboratory,
	12 Queen Square, London WC1N 3BG, UK. skiebel@fil.ion.ucl.ac.uk},
  keywords = {Auditory Perception, physiology; Bayes Theorem; Brain Mapping; Cerebral
	Cortex, physiology; Dominance, Cerebral, physiology; Electroencephalography;
	Electromyography; Evoked Potentials, physiology; Finite Element Analysis;
	Humans; Nerve Net, physiology; Neural Networks (Computer); Neurons,
	physiology; Nonlinear Dynamics; Pattern Recognition, Visual, physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S1053-8119(05)02575-9},
  pmid = {16490364},
  timestamp = {2013.02.21},
  url = {http://dx.doi.org/10.1016/j.neuroimage.2005.12.055}
}

@ARTICLE{Kiebel_2004,
  author = {Stefan J Kiebel and Karl J Friston},
  title = {Statistical parametric mapping for event-related potentials (II):
	a hierarchical temporal model.},
  journal = {Neuroimage},
  year = {2004},
  volume = {22},
  pages = {503--520},
  number = {2},
  month = {Jun},
  abstract = {In this paper, we describe a temporal model for event-related potentials
	(ERP) in the context of statistical parametric mapping (SPM). In
	brief, we project channel data onto a two-dimensional scalp surface
	or into three-dimensional brain space using some appropriate inverse
	solution. We then treat the spatiotemporal data in a mass-univariate
	fashion. This implicitly factorises the model into spatial and temporal
	components. The key contribution of this paper is the use of observation
	models that afford an explicit distinction between observation error
	and variation in the expression of ERPs. This distinction is created
	by employing a two-level hierarchical model, in which the first level
	models the ERP effects within-subject and trial type, while the second
	models differences in ERP expression among trial types and subjects.
	By bringing the analysis of ERP data into a classical hierarchical
	(i.e., mixed effects) framework, many apparently disparate approaches
	(e.g., conventional P300 analyses and time-frequency analyses of
	stimulus-locked oscillations) can be reconciled within the same estimation
	and inference procedure. Inference proceeds in the normal way using
	t or F statistics to test for effects that are localised in peristimulus
	time or in some time-frequency window. The use of F statistics is
	an important generalisation of classical approaches, because it allows
	one to test for effects that lie in a multidimensional subspace (i.e.,
	of unknown but constrained form). We describe the analysis procedures,
	the underlying theory and compare its performance to established
	techniques.},
  doi = {10.1016/j.neuroimage.2004.02.013},
  institution = {Functional Imaging Laboratory, Institute of Neurology, Wellcome Department
	of Imaging Neuroscience, London WC1N 3BG, UK. skiebel@fil.ion.ucl.ac.uk},
  keywords = {Analysis of Variance; Brain Mapping, methods; Computer Simulation;
	Event-Related Potentials, P300, physiology; Evoked Potentials, physiology;
	Humans; Models, Neurological; Models, Statistical; Reproducibility
	of Results; Time Factors},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S1053811904001053},
  pmid = {15193579},
  timestamp = {2013.08.28},
  url = {http://dx.doi.org/10.1016/j.neuroimage.2004.02.013}
}

@ARTICLE{Kiebel2009,
  author = {Stefan J Kiebel and Marta I Garrido and Rosalyn Moran and Chun-Chuan
	Chen and Karl J Friston},
  title = {Dynamic causal modeling for EEG and MEG.},
  journal = {Hum. Brain Mapp.},
  year = {2009},
  volume = {30},
  pages = {1866--1876},
  number = {6},
  month = {Jun},
  abstract = {We present a review of dynamic causal modeling (DCM) for magneto-
	and electroencephalography (M/EEG) data. DCM is based on a spatiotemporal
	model, where the temporal component is formulated in terms of neurobiologically
	plausible dynamics. Following an intuitive description of the model,
	we discuss six recent studies, which use DCM to analyze M/EEG and
	local field potentials. These studies illustrate how DCM can be used
	to analyze evoked responses (average response in time), induced responses
	(average response in time-frequency), and steady-state responses
	(average response in frequency). Bayesian model comparison plays
	a critical role in these analyses, by allowing one to compare equally
	plausible models in terms of their model evidence. This approach
	might be very useful in M/EEG research; where correlations among
	spatial and neuronal model parameter estimates can cause uncertainty
	about which model best explains the data. Bayesian model comparison
	resolves these uncertainties in a principled and formal way. We suggest
	that DCM and Bayesian model comparison provides a useful way to test
	hypotheses about distributed processing in the brain, using electromagnetic
	data.},
  doi = {10.1002/hbm.20775},
  institution = {The Wellcome Trust Centre for Neuroimaging, University College London,
	12 Queen Square, London, United Kingdom. skiebel@fil.ion.ucl.ac.uk},
  keywords = {Algorithms; Bayes Theorem; Biofeedback, Psychology; Brain, physiology/physiopathology;
	Electroencephalography, methods; Evoked Potentials, physiology; Feedback;
	Humans; Magnetoencephalography, methods; Models, Neurological; Models,
	Statistical; Neural Networks (Computer); Neurobiology, methods; Parkinson
	Disease, physiopathology; Reproducibility of Results; Synaptic Transmission,
	physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {19360734},
  timestamp = {2013.04.11},
  url = {http://dx.doi.org/10.1002/hbm.20775}
}

@ARTICLE{Kiebel2007,
  author = {Stefan J Kiebel and Stefan Klöppel and Nikolaus Weiskopf and Karl
	J Friston},
  title = {Dynamic causal modeling: a generative model of slice timing in fMRI.},
  journal = {Neuroimage},
  year = {2007},
  volume = {34},
  pages = {1487--1496},
  number = {4},
  month = {Feb},
  abstract = {Dynamic causal modeling (DCM) of functional magnetic resonance imaging
	(fMRI) data allows one to make inferences about the architecture
	of distributed networks in the brain, in terms of effective connectivity.
	fMRI data are usually acquired using echo planar imaging (EPI). EPI
	sequences typically acquire slices at different times over a few
	seconds. DCM, in its original inception, was not informed about these
	slice timings and assumed that all slices were acquired simultaneously.
	It has been shown that DCM can cope with slice timing differences
	of up to 1 s. However, many fMRI studies employ a repetition time
	(TR) of 3 to 5 s, which precludes a straightforward DCM of these
	data. We show that this limitation can be overcome easily by including
	slice timing in the DCM. Using synthetic data we show that the extended
	DCM furnishes veridical posterior means, even if there are large
	slice-timing differences. Model comparisons show that, in general,
	the extended DCM out-performs the original model. We contrast the
	modeling of slice timing, in the context of DCM, with the less effective
	approach of 'slice-timing correction', prior to modeling. We apply
	our procedure to real data and show that slice timings are important
	parameters. We conclude that, generally, one should use DCM with
	slice timing.},
  doi = {10.1016/j.neuroimage.2006.10.026},
  institution = {The Wellcome Department of Imaging Neuroscience, Institute of Neurology,
	University College London, 12 Queen Square, London WC1N 3AR, UK.
	skiebel@fil.ion.ucl.ac.uk},
  keywords = {Humans; Magnetic Resonance Imaging, methods; Models, Neurological;
	Reproducibility of Results; Software; Time Factors},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S1053-8119(06)01091-3},
  pmid = {17161624},
  timestamp = {2013.04.11},
  url = {http://dx.doi.org/10.1016/j.neuroimage.2006.10.026}
}

@ARTICLE{Kilpatrick_2011,
  author = {Zachary P Kilpatrick and Bard Ermentrout},
  title = {Sparse gamma rhythms arising through clustering in adapting neuronal
	networks.},
  journal = {PLoS Comput Biol},
  year = {2011},
  volume = {7},
  pages = {e1002281},
  number = {11},
  month = {Nov},
  abstract = {Gamma rhythms (30-100 Hz) are an extensively studied synchronous brain
	state responsible for a number of sensory, memory, and motor processes.
	Experimental evidence suggests that fast-spiking interneurons are
	responsible for carrying the high frequency components of the rhythm,
	while regular-spiking pyramidal neurons fire sparsely. We propose
	that a combination of spike frequency adaptation and global inhibition
	may be responsible for this behavior. Excitatory neurons form several
	clusters that fire every few cycles of the fast oscillation. This
	is first shown in a detailed biophysical network model and then analyzed
	thoroughly in an idealized model. We exploit the fact that the timescale
	of adaptation is much slower than that of the other variables. Singular
	perturbation theory is used to derive an approximate periodic solution
	for a single spiking unit. This is then used to predict the relationship
	between the number of clusters arising spontaneously in the network
	as it relates to the adaptation time constant. We compare this to
	a complementary analysis that employs a weak coupling assumption
	to predict the first Fourier mode to destabilize from the incoherent
	state of an associated phase model as the external noise is reduced.
	Both approaches predict the same scaling of cluster number with respect
	to the adaptation time constant, which is corroborated in numerical
	simulations of the full system. Thus, we develop several testable
	predictions regarding the formation and characteristics of gamma
	rhythms with sparsely firing excitatory neurons.},
  doi = {10.1371/journal.pcbi.1002281},
  institution = {Department of Mathematics, University of Pittsburgh, Pittsburgh,
	Pennsylvania, USA. zpkilpat@pitt.edu},
  keywords = {Action Potentials; Brain Waves, physiology; Cluster Analysis; Computer
	Simulation; Cortical Synchronization, physiology; Fourier Analysis;
	Humans; Interneurons; Least-Squares Analysis; Models, Neurological;
	Nerve Net, physiology; Pyramidal Cells},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {PCOMPBIOL-D-11-00632},
  pmid = {22125486},
  timestamp = {2013.09.04},
  url = {http://dx.doi.org/10.1371/journal.pcbi.1002281}
}

@ARTICLE{Kim_2004,
  author = {Dae-Shik Kim and Itamar Ronen and Cheryl Olman and Seong-Gi Kim and
	Kamil Ugurbil and Louis J Toth},
  title = {Spatial relationship between neuronal activity and BOLD functional
	MRI.},
  journal = {Neuroimage},
  year = {2004},
  volume = {21},
  pages = {876--885},
  number = {3},
  month = {Mar},
  abstract = {Despite the ubiquitous use of functional magnetic resonance imaging
	(fMRI), the extent to which the magnitude and spatial scale of the
	fMRI signal correlates with neuronal activity is poorly understood.
	In this study, we directly compared single and multiunit neuronal
	activity with blood oxygenation level-dependent (BOLD) fMRI responses
	across a large area of the cat area 18. Our data suggest that at
	the scale of several millimeters, the BOLD contrast correlates linearly
	with the underlying neuronal activity. At the level of individual
	electrode recording sites, however, the correlation between the two
	signals varied substantially. We conclude from our study that T(2)*-based
	positive BOLD signals are a robust predictor for neuronal activity
	only at supra-millimeter spatial scales.},
  doi = {10.1016/j.neuroimage.2003.10.018},
  institution = {Center for Magnetic Resonance Research, University of Minnesota Medical
	School, Minneapolis, MN 55455, USA. dskim@bu.edu},
  keywords = {Animals; Brain, cytology/physiology; Cats; Cerebral Cortex, cytology/physiology;
	Cerebrovascular Circulation, physiology; Electrodes, Implanted; Magnetic
	Resonance Imaging; Neurons, physiology; Oxygen, blood; Photic Stimulation;
	Visual Cortex, cytology/physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S1053811903006694},
  pmid = {15006654},
  timestamp = {2013.08.29},
  url = {http://dx.doi.org/10.1016/j.neuroimage.2003.10.018}
}

@ARTICLE{Kim_2009,
  author = {J. W. Kim and J. A. Roberts and P. A. Robinson},
  title = {Dynamics of epileptic seizures: evolution, spreading, and suppression.},
  journal = {J Theor Biol},
  year = {2009},
  volume = {257},
  pages = {527--532},
  number = {4},
  month = {Apr},
  abstract = {Dynamical properties of epileptic seizures are investigated using
	a recent compact continuum model for electric activity of the brain.
	Large amplitude limit cycles resembling electroencephalograms during
	epilepsy emerge when the system loses linear stability. Seizures
	that are confined to an onset area, or spread synchronously to other
	areas via spatial coupling, are studied and argued to be associated
	with clinical partial and secondarily generalized seizures, respectively.
	Suppression of such seizures is also demonstrated, which implies
	potential for future clinical applications.},
  doi = {10.1016/j.jtbi.2008.12.009},
  institution = {School of Physics, The University of Sydney, Sydney, New South Wales
	2006, Australia. jwkim@physics.usyd.edu.au},
  keywords = {Cerebral Cortex, physiopathology; Electroencephalography; Epilepsy,
	physiopathology; Humans; Models, Neurological; Neurons, physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S0022-5193(08)00638-3},
  pmid = {19150365},
  timestamp = {2013.08.19},
  url = {http://dx.doi.org/10.1016/j.jtbi.2008.12.009}
}

@ARTICLE{Kitzbichler_2009,
  author = {Manfred G Kitzbichler and Marie L Smith and Søren R Christensen and
	Ed Bullmore},
  title = {Broadband criticality of human brain network synchronization.},
  journal = {PLoS Comput. Biol.},
  year = {2009},
  volume = {5},
  pages = {e1000314},
  number = {3},
  month = {Mar},
  abstract = {Self-organized criticality is an attractive model for human brain
	dynamics, but there has been little direct evidence for its existence
	in large-scale systems measured by neuroimaging. In general, critical
	systems are associated with fractal or power law scaling, long-range
	correlations in space and time, and rapid reconfiguration in response
	to external inputs. Here, we consider two measures of phase synchronization:
	the phase-lock interval, or duration of coupling between a pair of
	(neurophysiological) processes, and the lability of global synchronization
	of a (brain functional) network. Using computational simulations
	of two mechanistically distinct systems displaying complex dynamics,
	the Ising model and the Kuramoto model, we show that both synchronization
	metrics have power law probability distributions specifically when
	these systems are in a critical state. We then demonstrate power
	law scaling of both pairwise and global synchronization metrics in
	functional MRI and magnetoencephalographic data recorded from normal
	volunteers under resting conditions. These results strongly suggest
	that human brain functional systems exist in an endogenous state
	of dynamical criticality, characterized by a greater than random
	probability of both prolonged periods of phase-locking and occurrence
	of large rapid changes in the state of global synchronization, analogous
	to the neuronal "avalanches" previously described in cellular systems.
	Moreover, evidence for critical dynamics was identified consistently
	in neurophysiological systems operating at frequency intervals ranging
	from 0.05-0.11 to 62.5-125 Hz, confirming that criticality is a property
	of human brain functional network organization at all frequency intervals
	in the brain's physiological bandwidth.},
  doi = {10.1371/journal.pcbi.1000314},
  institution = { Clinical Neurosciences Institute, Department of Experimental Psychology,
	University of Cambridge, Cambridge, United Kingdom.},
  keywords = {Action Potentials, physiology; Animals; Biological Clocks, physiology;
	Brain, physiology; Computer Simulation; Cortical Synchronization;
	Humans; Models, Neurological; Nerve Net, physiology; Neurons, physiology;
	Synaptic Transmission, physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {19300473},
  timestamp = {2013.03.05},
  url = {http://dx.doi.org/10.1371/journal.pcbi.1000314}
}

@ARTICLE{PyCUDA,
  author = {Kl{\"o}ckner, Andreas and Pinto, Nicolas and Lee, Yunsup and Catanzaro,
	Bryan and Ivanov, Paul and Fasih, Ahmed},
  title = {PyCUDA and PyOpenCL: A scripting-based approach to GPU run-time code
	generation},
  journal = {Parallel Computing},
  year = {2012},
  volume = {38},
  pages = {157--174},
  number = {3},
  publisher = {Elsevier}
}

@ARTICLE{Kleiner_2012,
  author = {Melanie Kleiner and Markus Axer and David Grässell and Julia Reckfort
	and Uwe Pietrzyk and Katrin Amunts and Timo Dickscheid},
  title = {Classification of ambiguous nerve fiber orientations in 3D polarized
	light imaging.},
  journal = {Med Image Comput Comput Assist Interv},
  year = {2012},
  volume = {15},
  pages = {206--213},
  number = {Pt 1},
  abstract = {3D polarized light imaging (3D-PLI) has been shown to measure the
	orientation of nerve fibers in post mortem human brains at ultra
	high resolution. The 3D orientation in each voxel is obtained as
	a pair of angles, the direction angle and the inclination angle with
	unknown sign. The sign ambiguity is a major problem for the correct
	interpretation of fiber orientation. Measurements from a tiltable
	specimen stage, that are highly sensitive to noise, extract information,
	which allows drawing conclusions about the true inclination sign.
	In order to reduce noise, we propose a global classification of the
	inclination sign, which combines measurements with spatial coherence
	constraints. The problem is formulated as a second order Markov random
	field and solved efficiently with graph cuts. We evaluate our approach
	on synthetic and human brain data. The results of global optimization
	are compared to independent pixel classification with subsequent
	edge-preserving smoothing.},
  institution = {Institute of Neuroscience and Medicine (INM-1, INM-4), Research Center
	Jülich, Germany.},
  keywords = {Algorithms; Axons, pathology; Brain, pathology; Humans; Image Enhancement,
	methods; Image Processing, Computer-Assisted, methods; Imaging, Three-Dimensional,
	methods; Light; Markov Chains; Microscopy, Polarization, methods;
	Models, Statistical; Nerve Fibers, pathology; Reproducibility of
	Results; Software},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {23285553},
  timestamp = {2013.07.04}
}

@ARTICLE{Klem_1999,
  author = {G. H. Klem and H. O. Lüders and H. H. Jasper and C. Elger},
  title = {The ten-twenty electrode system of the International Federation.
	The International Federation of Clinical Neurophysiology.},
  journal = {Electroencephalogr. Clin. Neurophysiol. Suppl.},
  year = {1999},
  volume = {52},
  pages = {3--6},
  institution = {Cleveland Clinic Foundation, OH 44195, USA.},
  keywords = {Electrodes; Electroencephalography, instrumentation/methods; Humans},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {10590970},
  timestamp = {2013.02.11}
}

@BOOK{Kloeden_1995,
  title = {Numerical solution of stochastic differential equations},
  publisher = {Springer},
  year = {1995},
  author = {Klöden and Platen},
  owner = {paula},
  timestamp = {2012.10.25}
}

@ARTICLE{Klonowski2009,
  author = {Wlodzimierz Klonowski},
  title = {Everything you wanted to ask about EEG but were afraid to get the
	right answer.},
  journal = {Nonlinear. Biomed. Phys.},
  year = {2009},
  volume = {3},
  pages = {2},
  number = {1},
  abstract = {We answer several important questions concerning EEG. We also shortly
	discuss importance of nonlinear methods of contemporary physics in
	EEG analysis. Basic definitions and explanation of fundamental concepts
	may be found in my previous publications in NBP.It is a magnificent
	feeling to recognize the unity of complex phenomena which appear
	to be things quite apart from the direct visible truth.Albert Einstein.},
  comment = {ToRead},
  doi = {10.1186/1753-4631-3-2},
  institution = {Institute of Biocybernetics and Biomedical Engineering, Polish Academy
	of Sciences, Warsaw, Poland. wklon@ibib.waw.pl.},
  language = {eng},
  medline-pst = {epublish},
  owner = {paula},
  pii = {1753-4631-3-2},
  pmid = {19470156},
  timestamp = {2013.04.09},
  url = {http://dx.doi.org/10.1186/1753-4631-3-2}
}

@ARTICLE{Klonowski2007,
  author = {Wlodzimierz Klonowski},
  title = {From conformons to human brains: an informal overview of nonlinear
	dynamics and its applications in biomedicine.},
  journal = {Nonlinear. Biomed. Phys.},
  year = {2007},
  volume = {1},
  pages = {5},
  number = {1},
  abstract = {Methods of contemporary physics are increasingly important for biomedical
	research but, for a multitude of diverse reasons, most practitioners
	of biomedicine lack access to a comprehensive knowledge of these
	modern methodologies. This paper is an attempt to describe nonlinear
	dynamics and its methods in a way that could be read and understood
	by biomedical professionals who usually are not trained in advanced
	mathematics. After an overview of basic concepts and vocabulary of
	nonlinear dynamics, deterministic chaos, and fractals, application
	of nonlinear methods of biosignal analysis is discussed. In particular,
	five case studies are presented: 1. Monitoring the depth of anaesthesia
	and of sedation; 2. Bright Light Therapy and Seasonal Affective Disorder;
	3. Analysis of posturographic signals; 4. Evoked EEG and photo-stimulation;
	5. Influence of electromagnetic fields generated by cellular phones.},
  comment = {ToRead},
  doi = {10.1186/1753-4631-1-5},
  institution = {Institute of Biocybernetics and Biomedical Engineering Polish Academy
	of Sciences, Warsaw, Poland. wklon@ibib.waw.pl.},
  language = {eng},
  medline-pst = {epublish},
  owner = {paula},
  pii = {1753-4631-1-5},
  pmid = {17908344},
  timestamp = {2013.04.09},
  url = {http://dx.doi.org/10.1186/1753-4631-1-5}
}

@ARTICLE{Klonowski1999,
  author = {W. Klonowski and W. Jernajczyk and K. Niedzielska and A. Rydz and
	R. Stepień},
  title = {Quantitative measure of complexity of EEG signal dynamics.},
  journal = {Acta Neurobiol. Exp. (Warsz.)},
  year = {1999},
  volume = {59},
  pages = {315--321},
  number = {4},
  abstract = {Since electroencephalographic (EEG) signal may be considered chaotic,
	Nonlinear Dynamics and Deterministic Chaos Theory may supply effective
	quantitative descriptors of EEG dynamics and of underlying chaos
	in the brain. We have used Karhunen-Loeve decomposition of the covariance
	matrix of the EEG signal to analyse EEG signals of 4 healthy subjects,
	under drug-free condition and under the influence of Diazepam. We
	found that what we call KL-complexity of the signal differs profoundly
	for the signals registered in different EEG channels, from about
	5-8 for signals in frontal channels up to 40 and more in occipital
	ones. But no consistency in the influence of Diazepam administration
	on KL-complexity is observed. We also estimated the embedding dimension
	of the EEG signals of the same subjects, which turned to be between
	7 and 11, so endorsing the presumption about existence of low-dimensional
	chaotic attractor. We are sure that nonlinear time series analysis
	can be used to investigate the dynamics underlying the generation
	of EEG signal. This approach does not seem practical yet, but deserves
	further study.},
  comment = {ToRead},
  institution = {Institute of Biocybernetics and Biomedical Engineering, Polish Academy
	of Sciences, Warsaw, Poland. wklon@hrabia.ibib.waw.pl},
  keywords = {Adult; Brain Mapping; Brain, drug effects/physiology; Diazepam, pharmacology;
	Electroencephalography; Humans; Nonlinear Dynamics; Reference Values},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {10645636},
  timestamp = {2013.04.09}
}

@ARTICLE{Knock_2009,
  author = {Knock, SA and McIntosh, AR and Sporns, O and Kötter, R and Hagmann,
	P and Jirsa, VK},
  title = {The effects of physiologically plausible connectivity structure on
	local and global dynamics in large scale brain models.},
  journal = {J. Neurosci. Methods},
  year = {2009},
  volume = {183},
  pages = {86-94},
  number = {1},
  month = {September},
  abstract = {Functionally relevant large scale brain dynamics operates within the
	framework imposed by anatomical connectivity and time delays due
	to finite transmission speeds. To gain insight on the reliability
	and comparability of large scale brain network simulations, we investigate
	the effects of variations in the anatomical connectivity. Two different
	sets of detailed global connectivity structures are explored, the
	first extracted from the CoCoMac database and rescaled to the spatial
	extent of the human brain, the second derived from white-matter tractography
	applied to diffusion spectrum imaging (DSI) for a human subject.
	We use the combination of graph theoretical measures of the connection
	matrices and numerical simulations to explicate the importance of
	both connectivity strength and delays in shaping dynamic behaviour.
	Our results demonstrate that the brain dynamics derived from the
	CoCoMac database are more complex and biologically more realistic
	than the one based on the DSI database. We propose that the reason
	for this difference is the absence of directed weights in the DSI
	connectivity matrix.},
  keywords = {connectivity},
  owner = {paula},
  timestamp = {2012.10.18}
}

@ARTICLE{Ko_2008,
  author = {Tae-Wook Ko and G. Bard Ermentrout},
  title = {Bistability between synchrony and incoherence in limit-cycle oscillators
	with coupling strength inhomogeneity.},
  journal = {Phys Rev E Stat Nonlin Soft Matter Phys},
  year = {2008},
  volume = {78},
  pages = {026210},
  number = {2 Pt 2},
  month = {Aug},
  abstract = {The effect of coupling strength inhomogeneity on the synchronization
	of identical oscillators is investigated. Through simulations and
	analysis of phase-reduced models, it is shown that the mean value
	of coupling function and the degree of inhomogeneity in the total
	of coupling strength to the each oscillator cooperate to stabilize
	incoherent states. Under some circumstances, there can be bistability
	between coherent and incoherent states. Various cases of coupled
	Morris-Lecar oscillators are studied as examples of our results.},
  institution = {Department of Mathematics, University of Pittsburgh, Pittsburgh,
	Pennsylvania 15260, USA. taewook@pitt.edu},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {18850924},
  timestamp = {2013.09.04}
}

@ARTICLE{Ko_2008a,
  author = {Tae-Wook Ko and G. Bard Ermentrout},
  title = {Partially locked states in coupled oscillators due to inhomogeneous
	coupling.},
  journal = {Phys Rev E Stat Nonlin Soft Matter Phys},
  year = {2008},
  volume = {78},
  pages = {016203},
  number = {1 Pt 2},
  month = {Jul},
  abstract = {We investigate coupled identical phase oscillators with scale-free
	distribution of coupling strength. It is shown that partially locked
	states can occur due to the inhomogeneity in coupling and some properties
	of the coupling function. Various quantities of the partially locked
	states are computed through a self-consistency argument and the values
	show good agreement with simulation results.},
  institution = {Department of Mathematics, University of Pittsburgh, Pittsburgh,
	Pennsylvania 15260, USA. taewook@pitt.edu},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {18764031},
  timestamp = {2013.09.04}
}

@ARTICLE{Ko_2007,
  author = {Tae-Wook Ko and G. Bard Ermentrout},
  title = {Effects of axonal time delay on synchronization and wave formation
	in sparsely coupled neuronal oscillators.},
  journal = {Phys Rev E Stat Nonlin Soft Matter Phys},
  year = {2007},
  volume = {76},
  pages = {056206},
  number = {5 Pt 2},
  month = {Nov},
  abstract = {We investigate the effects of axonal time delay when the neuronal
	oscillators are coupled by sparse and random connections. Using phase-reduced
	models with general coupling functions, we show that a small fraction
	of connections with time delay can destabilize synchronous states
	and induce near-regular wave states. An order parameter is introduced
	to characterize those states. We analyze the systems using mean-field-type
	approximation.},
  institution = {Department of Mathematics, University of Pittsburgh, Pennsylvania
	15260, USA. taewook@pitt.edu},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {18233738},
  timestamp = {2013.09.04}
}

@ARTICLE{Koebbert_2000,
  author = {C. Köbbert and R. Apps and I. Bechmann and J. L. Lanciego and J.
	Mey and S. Thanos},
  title = {Current concepts in neuroanatomical tracing.},
  journal = {Prog Neurobiol},
  year = {2000},
  volume = {62},
  pages = {327--351},
  number = {4},
  month = {Nov},
  abstract = {The development of new axonal tract tracing and cell labelling methods
	has revolutionised neurobiology in the last 30 years. The aim of
	this review is to consider some of the key methods of neuroanatomical
	tracing that are currently in use and have proved invaluable in charting
	the complex interconnections of the central nervous system. The review
	begins with a short overview of the most frequently used tracers,
	including enzymes, peptides, biocytin, latex beads, plant lectins
	and the ever-increasing number of fluorescent dyes. This is followed
	by a more detailed consideration of both well established and more
	recently introduced neuroanatomical tracing methods. Technical aspects
	of the application, uptake mechanisms, intracellular transport of
	tracers, and the problems of subsequent signal detection, are also
	discussed. The methods that are presented and discussed in detail
	include: (1) anterograde and retrograde neuroanatomical labelling
	with fluorescent dyes in vivo, (2) labelling of post mortem tissue,
	(3) developmental studies, (4) transcellular tracing (phagocytosis-dependent
	staining of glial cells), (5) electrophysiological mapping combined
	with neuronal tract tracing, and (6) simultaneous detection of more
	than one axonal tracer. (7) Versatile protocols for three-colour
	labelling have been developed to study complex patterns of connections.
	It is envisaged that this review will be used to guide the readers
	in their selection of the most appropriate techniques to apply to
	their own particular area of interest.},
  institution = {Department of Experimental Ophthalmology, Medical School, University
	of Müenster, Germany.},
  keywords = {Animals; Coloring Agents; Fluorescent Dyes; Humans; Nervous System,
	anatomy /&/ histology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S0301-0082(00)00019-8},
  pmid = {10856608},
  timestamp = {2013.07.04}
}

@ARTICLE{Kopell_2000,
  author = {N. Kopell and G. B. Ermentrout and M. A. Whittington and R. D. Traub},
  title = {Gamma rhythms and beta rhythms have different synchronization properties.},
  journal = {Proc Natl Acad Sci U S A},
  year = {2000},
  volume = {97},
  pages = {1867--1872},
  number = {4},
  month = {Feb},
  abstract = {Experimental and modeling efforts suggest that rhythms in the CA1
	region of the hippocampus that are in the beta range (12-29 Hz) have
	a different dynamical structure than that of gamma (30-70 Hz). We
	use a simplified model to show that the different rhythms employ
	different dynamical mechanisms to synchronize, based on different
	ionic currents. The beta frequency is able to synchronize over long
	conduction delays (corresponding to signals traveling a significant
	distance in the brain) that apparently cannot be tolerated by gamma
	rhythms. The synchronization properties are consistent with data
	suggesting that gamma rhythms are used for relatively local computations
	whereas beta rhythms are used for higher level interactions involving
	more distant structures.},
  institution = {Department of Mathematics, Boston University, Boston MA 02215, USA.
	nk@bu.edu},
  keywords = {Animals; Cortical Synchronization; Electroencephalography; Hippocampus,
	physiology; Models, Neurological},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {97/4/1867},
  pmid = {10677548},
  timestamp = {2013.09.04}
}

@ELECTRONIC{cocomac,
  author = {Kötter, R},
  title = {http://cocomac.org/},
  url = {http://cocomac.org/},
  owner = {paupau},
  timestamp = {2012.10.22}
}

@ARTICLE{Koetter_2004,
  author = {Kötter,R},
  title = {Online retrieval, processing, and visualization of primate connectivity
	data from the CoCoMac database.},
  journal = {Neuroinformatics},
  year = {2004},
  volume = {2},
  pages = {127-144},
  number = {2},
  owner = {paula},
  timestamp = {2012.10.25}
}

@ARTICLE{Koetter_2005,
  author = {Kötter, R and Wanke, E},
  title = {Mapping brains without coordinates.},
  journal = {Philos. Trans. R. Soc. Lond. B. Biol. Sci.},
  year = {2005},
  volume = {360},
  pages = {751-766},
  number = {1456},
  owner = {paula},
  timestamp = {2012.11.07}
}

@ARTICLE{Kriegeskorte_2010,
  author = {Nikolaus Kriegeskorte and Rhodri Cusack and Peter Bandettini},
  title = {How does an fMRI voxel sample the neuronal activity pattern: compact-kernel
	or complex spatiotemporal filter?},
  journal = {Neuroimage},
  year = {2010},
  volume = {49},
  pages = {1965--1976},
  number = {3},
  month = {Feb},
  abstract = {Recent studies suggested that fMRI voxel patterns can convey information
	represented in columnar-scale neuronal population codes, even when
	spatial resolution is insufficient to directly image the patterns
	of columnar selectivity (Kamitani and Tong, 2005; Haynes and Rees,
	2005). Sensitivity to subvoxel-scale pattern information, or "fMRI
	hyperacuity," would greatly enhance the power of fMRI when combined
	with pattern information analysis techniques (Kriegeskorte and Bandettini,
	2007). An individual voxel might weakly reflect columnar-level information
	if the columns within its boundaries constituted a slightly unbalanced
	sample of columnar selectivities (Kamitani and Tong, 2005), providing
	a possible mechanism for fMRI hyperacuity. However, Op de Beeck (2009)
	suggests that a coarse-scale neuronal organization rather than fMRI
	hyperacuity may explain the presence of the information in the fMRI
	patterns. Here we argue (a) that the present evidence does not rule
	out fMRI hyperacuity, (b) that the mechanism originally suggested
	for fMRI hyperacuity (biased sampling by averaging within each voxel's
	boundaries; Kamitani and Tong, 2005) will only produce very weak
	sensitivity to fine-grained pattern information, and (c) that an
	alternative mechanism (voxel as complex spatiotemporal filter) is
	physiologically more accurate and promises stronger sensitivity to
	fine-grained pattern information: We know that each voxel samples
	the neuronal activity pattern through a unique fine-grained structure
	of venous vessels that supply its blood oxygen level-dependent signal.
	At the simplest level, the drainage domain of a venous vessel may
	sample the neuronal pattern with a selectivity bias (Gardner, 2009;
	Shmuel et al., 2009). Beyond biased drainage domains, we illustrate
	with a simple simulation how temporal properties of the hemodynamics
	(e.g., the speed of the blood in the capillary bed) can shape spatial
	properties of a voxel's filter (e.g., how finely structured it is).
	This suggests that a voxel, together with its signal-supplying vasculature,
	may best be thought of as a complex spatiotemporal filter. Such a
	filter may well have greater sensitivity to high spatial frequencies
	than the Gaussian or averaging-box kernels typically invoked to characterize
	voxel sampling (compact kernels, both of which would act like anti-aliasing
	filters that minimize such sensitivity). Importantly, the complex-spatiotemporal-filter
	hypothesis of fMRI hyperacuity can account for the observed robustness
	to slight shifts of the voxel grid caused by head motion: Because
	the fine-grained components of the filter are vascular, they will
	remain in a constant relationship to the neuronal patterns sampled
	as the voxel grid is slightly shifted.},
  doi = {10.1016/j.neuroimage.2009.09.059},
  institution = {Section on Functional Imaging Methods, Laboratory of Brain and Cognition,
	National Institute of Mental Health, National Institutes of Health,
	Bethesda, MD, USA. nikolaus.kriegeskorte@mrc-cbu.cam.ac.uk},
  keywords = {Animals; Brain Mapping, methods; Brain, physiology; Humans; Image
	Interpretation, Computer-Assisted, methods; Magnetic Resonance Imaging;
	Models, Neurological; Neurons, physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S1053-8119(09)01058-1},
  pmid = {19800408},
  timestamp = {2013.08.19},
  url = {http://dx.doi.org/10.1016/j.neuroimage.2009.09.059}
}

@ARTICLE{Kriegeskorte_2001,
  author = {N. Kriegeskorte and R. Goebel},
  title = {An efficient algorithm for topologically correct segmentation of
	the cortical sheet in anatomical mr volumes.},
  journal = {Neuroimage},
  year = {2001},
  volume = {14},
  pages = {329--346},
  number = {2},
  month = {Aug},
  abstract = {Polygon-mesh representations of the cortices of individual subjects
	are of anatomical interest, aid visualization of functional imaging
	data and provide important constraints for their statistical analysis.
	Due to noise and partial volume sampling, however, conventional segmentation
	methods rarely yield a voxel object whose outer boundary represents
	the folded cortical sheet without topological errors. These errors,
	called handles, have particularly deleterious effects when the polygon
	mesh constructed from the segmented voxel representation is inflated
	or flattened. So far handles had to be removed by cumbersome manual
	editing, or the computationally more expensive method of reconstruction
	by morphing had to be used, incorporating the a priori constraint
	of simple topology into the polygon-mesh model. Here we describe
	a linear time complexity algorithm that automatically detects and
	removes handles in presegmentations of the cortex obtained by conventional
	methods. The algorithm's modifications reflect the true structure
	of the cortical sheet. The core component of our method is a region
	growing process that starts deep inside the object, is prioritized
	by the distance-to-surface of the voxels considered for inclusion
	and is selftouching-sensitive, i.e., voxels whose inclusion would
	add a handle are never included. The result is a binary voxel object
	identical to the initial object except for "cuts" located in the
	thinnest part of each handle. By applying the same method to the
	inverse object, an alternative set of solutions is determined, correcting
	the errors by addition instead of deletion of voxels. For each handle
	separately, the solution more consistent with the intensities of
	the original anatomical MR scan is chosen. The accuracy of the resulting
	polygon-mesh reconstructions has been validated by visual inspection,
	by quantitative comparison to an expert's manual corrections, and
	by crossvalidation between reconstructions from different scans of
	the same subject's cortex.},
  doi = {10.1006/nimg.2001.0831},
  institution = {Faculty of Psychology, Department of Cognitive Neuroscience, Universiteit
	Maastricht, Universiteitssingel 40, Maastricht, 6229 ET, The Netherlands.},
  keywords = {Algorithms; Artifacts; Brain Mapping; Cerebral Cortex, anatomy /&/
	histology/physiology; Dominance, Cerebral, physiology; Humans; Image
	Processing, Computer-Assisted; Imaging, Three-Dimensional; Magnetic
	Resonance Imaging; Numerical Analysis, Computer-Assisted; Reproducibility
	of Results},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S1053-8119(01)90831-6},
  pmid = {11467907},
  timestamp = {2013.08.19},
  url = {http://dx.doi.org/10.1006/nimg.2001.0831}
}

@ARTICLE{Kriegeskorte_2006,
  author = {Nikolaus Kriegeskorte and Rainer Goebel and Peter Bandettini},
  title = {Information-based functional brain mapping.},
  journal = {Proc Natl Acad Sci U S A},
  year = {2006},
  volume = {103},
  pages = {3863--3868},
  number = {10},
  month = {Mar},
  abstract = {The development of high-resolution neuroimaging and multielectrode
	electrophysiological recording provides neuroscientists with huge
	amounts of multivariate data. The complexity of the data creates
	a need for statistical summary, but the local averaging standardly
	applied to this end may obscure the effects of greatest neuroscientific
	interest. In neuroimaging, for example, brain mapping analysis has
	focused on the discovery of activation, i.e., of extended brain regions
	whose average activity changes across experimental conditions. Here
	we propose to ask a more general question of the data: Where in the
	brain does the activity pattern contain information about the experimental
	condition? To address this question, we propose scanning the imaged
	volume with a "searchlight," whose contents are analyzed multivariately
	at each location in the brain.},
  doi = {10.1073/pnas.0600244103},
  institution = {Section on Functional Imaging Methods, Laboratory of Brain and Cognition,
	National Institute of Mental Health, Building 10, Room 1D80B, 10
	Center Drive MSC 1148, Bethesda, MD 20892-1148, USA. niko@nih.gov},
  keywords = {Adolescent; Adult; Brain Mapping, methods; Computer Simulation; Data
	Interpretation, Statistical; Female; Humans; Magnetic Resonance Imaging,
	methods/statistics /&/ numerical data; Male; Models, Neurological;
	Multivariate Analysis},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {0600244103},
  pmid = {16537458},
  timestamp = {2013.08.19},
  url = {http://dx.doi.org/10.1073/pnas.0600244103}
}

@ARTICLE{Kriegeskorte_2009,
  author = {Nikolaus Kriegeskorte and W. Kyle Simmons and Patrick S F Bellgowan
	and Chris I Baker},
  title = {Circular analysis in systems neuroscience: the dangers of double
	dipping.},
  journal = {Nat Neurosci},
  year = {2009},
  volume = {12},
  pages = {535--540},
  number = {5},
  month = {May},
  abstract = {A neuroscientific experiment typically generates a large amount of
	data, of which only a small fraction is analyzed in detail and presented
	in a publication. However, selection among noisy measurements can
	render circular an otherwise appropriate analysis and invalidate
	results. Here we argue that systems neuroscience needs to adjust
	some widespread practices to avoid the circularity that can arise
	from selection. In particular, 'double dipping', the use of the same
	dataset for selection and selective analysis, will give distorted
	descriptive statistics and invalid statistical inference whenever
	the results statistics are not inherently independent of the selection
	criteria under the null hypothesis. To demonstrate the problem, we
	apply widely used analyses to noise data known to not contain the
	experimental effects in question. Spurious effects can appear in
	the context of both univariate activation analysis and multivariate
	pattern-information analysis. We suggest a policy for avoiding circularity.},
  doi = {10.1038/nn.2303},
  institution = {Laboratory of Brain and Cognition, US National Institute of Mental
	Health, Bethesda, Maryland, USA. nikokriegeskorte@gmail.com},
  keywords = {Animals; Artifacts; Data Collection, methods/standards; Data Interpretation,
	Statistical; Humans; Image Processing, Computer-Assisted, methods/standards;
	Magnetic Resonance Imaging, methods/standards; Neurosciences, methods;
	Reproducibility of Results; Selection Bias; Systems Biology, methods},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {nn.2303},
  pmid = {19396166},
  timestamp = {2013.08.19},
  url = {http://dx.doi.org/10.1038/nn.2303}
}

@INBOOK{Kuramoto_1975,
  chapter = {52},
  pages = {420},
  title = {Self-entralnment of a population of coupled non-llnear oscillators},
  publisher = {Springer},
  year = {1975},
  author = {Kuramoto, Y.},
  number = {39},
  series = {Lectures On Physics: International Symposium on Mathematical Problems
	in Theoretical Physics},
  month = {January},
  owner = {paupau},
  timestamp = {2013.10.27}
}

@inproceedings{Kuramoto1975,
  title={Self-entrainment of a population of coupled non-linear oscillators},
  author={Kuramoto, Yoshiki},
  booktitle={International symposium on mathematical problems in theoretical physics},
  pages={420--422},
  year={1975},
  organization={Springer}
}

@ARTICLE{Lake_2011,
  author = {Douglas E Lake and J. Randall Moorman},
  title = {Accurate estimation of entropy in very short physiological time series:
	the problem of atrial fibrillation detection in implanted ventricular
	devices.},
  journal = {Am. J. Physiol. Heart Circ. Physiol.},
  year = {2011},
  volume = {300},
  pages = {H319--H325},
  number = {1},
  month = {Jan},
  abstract = {Entropy estimation is useful but difficult in short time series. For
	example, automated detection of atrial fibrillation (AF) in very
	short heart beat interval time series would be useful in patients
	with cardiac implantable electronic devices that record only from
	the ventricle. Such devices require efficient algorithms, and the
	clinical situation demands accuracy. Toward these ends, we optimized
	the sample entropy measure, which reports the probability that short
	templates will match with others within the series. We developed
	general methods for the rational selection of the template length
	m and the tolerance matching r. The major innovation was to allow
	r to vary so that sufficient matches are found for confident entropy
	estimation, with conversion of the final probability to a density
	by dividing by the matching region volume, 2r(m). The optimized sample
	entropy estimate and the mean heart beat interval each contributed
	to accurate detection of AF in as few as 12 heartbeats. The final
	algorithm, called the coefficient of sample entropy (COSEn), was
	developed using the canonical MIT-BIH database and validated in a
	new and much larger set of consecutive Holter monitor recordings
	from the University of Virginia. In patients over the age of 40 yr
	old, COSEn has high degrees of accuracy in distinguishing AF from
	normal sinus rhythm in 12-beat calculations performed hourly. The
	most common errors are atrial or ventricular ectopy, which increase
	entropy despite sinus rhythm, and atrial flutter, which can have
	low or high entropy states depending on dynamics of atrioventricular
	conduction.},
  doi = {10.1152/ajpheart.00561.2010},
  institution = {Cardiovascular Division, Department of Internal Medicine, and Cardiovascular
	Research Center, University of Virginia Health System, Charlottesville,
	Virginia, USA. dlake@virginia.edu},
  keywords = {Algorithms; Atrial Fibrillation, diagnosis/physiopathology; Atrial
	Flutter, diagnosis/physiopathology; Databases, Factual; Electrocardiography,
	Ambulatory, methods; Entropy; Heart Ventricles, physiopathology;
	Humans; Logistic Models; ROC Curve},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {ajpheart.00561.2010},
  pmid = {21037227},
  timestamp = {2013.02.11},
  url = {http://dx.doi.org/10.1152/ajpheart.00561.2010}
}

@ARTICLE{Larter_1999,
  author = {Larter, R and Speelman, B and Worth, RM},
  title = {A coupled ordinary differential equation lattice model for the simulation
	of epileptic seizures},
  journal = {Chaos},
  year = {1999},
  volume = {9},
  pages = {795-805},
  number = {3},
  abstract = {A coupled ordinary differential equation lattice model for the CA3
	region of the hippocampus (a common location of the epileptic focus)
	is developed. This model consists of a hexagonal lattice of nodes,
	each describing a subnetwork consisting of a group of prototypical
	excitatory pyramidal cells and a group of prototypical inhibitory
	interneurons connected via on/off excitatory and inhibitory synapses.
	The nodes communicate using simple rules to simulate the diffusion
	of extracellular potassium. Both the integration time over which
	a node’s trajectory is integrated before the diffusional event is
	allowed to occur and the level of inhibition in each node were found
	to be important parameters. Shorter integration times lead to total
	synchronization of the lattice (similar to synchronous neural activity
	occurring during a seizure) whereas longer times cause more random
	spatiotemporal behavior. Moderately diminished levels of inhibition
	lead to simple nodal oscillatory behavior. It is postulated that
	both the lack of inhibition and an alteration in conduction time
	may be necessary for the development of a behaviorally manifest seizure.},
  keywords = {model},
  owner = {paula},
  timestamp = {2012.10.18}
}

@ARTICLE{Lee_2006,
  author = {Lee, J.K. and Lee, J.M. and Kim, J.S. and Kim, I.Y. and Evans, A.C.
	and Kim, S.I.},
  title = {{A novel quantitative cross-validation of different cortical surface
	reconstruction algorithms using MRI phantom}},
  journal = {Neuroimage},
  year = {2006},
  volume = {31},
  pages = {572--584},
  number = {2},
  issn = {1053-8119},
  publisher = {Elsevier}
}

@ARTICLE{Lee2006,
  author = {Lee, Lucy and Friston, Karl and Horwitz, Barry},
  title = {Large-scale neural models and dynamic causal modelling.},
  journal = {Neuroimage},
  year = {2006},
  volume = {30},
  pages = {1243--1254},
  number = {4},
  month = {May},
  abstract = {Dynamic causal modelling (DCM) is a method for estimating and making
	inferences about the coupling among small numbers of brain areas,
	and the influence of experimental manipulations on that coupling
	[Friston, K.J., Harrison, L., Penny, W., 2003 Dynamic causal modelling.
	Neuroimage 19, 1273-1302]. Large-scale neural modelling aims to construct
	neurobiologically grounded computational models with emergent behaviours
	that inform our understanding of neuronal systems. One such model
	has been used to simulate region-specific BOLD time-series [Horwitz,
	B., Friston, K.J., Taylor, J.G., 2000. Neural modeling and functional
	brain imaging: an overview. Neural Netw. 13, 829-846]. DCM was used
	to make inferences about effective connectivity using data generated
	by a model implementing a visual delayed match-to-sample task [Tagamets,
	M.A., Horwitz, B., 1998. Integrating electrophysiological and anatomical
	experimental data to create a large-scale model that simulates a
	delayed match-to-sample human brain imaging study. Cereb. Cortex
	8, 310-320]. The aim was to explore the validity of inferences made
	using DCM about the connectivity structure and task-dependent modulatory
	effects, in a system with a known connectivity structure. We also
	examined the effects of misspecifying regions of interest. Models
	with hierarchical connectivity and reciprocal connections were examined
	using DCM and Bayesian Model Comparison [Penny, W.D., Stephan, K.E.,
	Mechelli, A., Friston, K.J., 2004. Comparing dynamic causal models.
	Neuroimage 22, 1157-1172]. This approach revealed strong evidence
	for those models with correctly specified anatomical connectivity.
	Furthermore, Bayesian model comparison favoured those models when
	bilinear effects corresponded to their implementation in the neural
	model. These findings generalised to an extended model with two additional
	areas and reentrant circuits. The conditional uncertainty of coupling
	parameter estimates increased in proportion to the number of incorrectly
	specified regions. These results highlight the role of neural models
	in establishing the validity of estimation and inference schemes.
	Specifically, Bayesian model comparison confirms the validity of
	DCM in relation to a well-characterised and comprehensive neuronal
	model.},
  doi = {10.1016/j.neuroimage.2005.11.007},
  institution = {Wellcome Department of Imaging Neuroscience, 12 Queen Square, London
	WC1N 3BG, UK.},
  keywords = {Bayes Theorem; Brain Mapping, methods; Cerebral Cortex, physiology;
	Discrimination Learning, physiology; Hemodynamics, physiology; Humans;
	Image Processing, Computer-Assisted; Magnetic Resonance Imaging;
	Mathematical Computing; Nerve Net, physiology; Neural Inhibition,
	physiology; Neural Networks (Computer); Neurons, physiology; Oxygen,
	blood; Pattern Recognition, Visual, physiology; Synaptic Transmission,
	physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paupau},
  pii = {S1053-8119(05)02459-6},
  pmid = {16387513},
  timestamp = {2013.08.21},
  url = {http://dx.doi.org/10.1016/j.neuroimage.2005.11.007}
}

@INBOOK{Liley_2012_inbook,
  chapter = {Co-operative populations of neurons: mean field models of mesoscopic
	brain activity.},
  pages = {317–364},
  title = {Computational Systems Neurobiology},
  publisher = {Springer},
  year = {2012},
  editor = {N. Le Novère},
  author = {Liley, DTJ and Foster, BL and Bojak, I},
  owner = {paupau},
  timestamp = {2013.04.09}
}

@ARTICLE{Liley_1999,
  author = {D. T. Liley and D. M. Alexander and J. J. Wright and M. D. Aldous},
  title = {Alpha rhythm emerges from large-scale networks of realistically coupled
	multicompartmental model cortical neurons.},
  journal = {Network},
  year = {1999},
  volume = {10},
  pages = {79--92},
  number = {1},
  month = {Feb},
  abstract = {Conical pyramidal and stellate neurons were simulated using the GENESIS
	simulation package. Model neurons were leaky integrate-and-fire and
	consisted of from four to nine passive compartments. Neurophysiological
	measurements, based on single-cell recordings and patch-clamp experiments,
	provided estimations for the simulation of cortical neurons: transmitter-activated
	conductances, passive membrane time constants and axonal delays.
	Network connectivity was generated using a previously described probabilistic
	scheme based on known cortical histology, in which the probability
	of connections forming between one neuron and another fell off monotonically
	with increasing inter-cellular separation. Simulations of up to 6400
	cortical neurons, approaching the scale of an individual cortical
	column, confirmed previous findings with smaller networks. Limit-cycle
	behaviour emerged in the network, in the frequency in the range of
	the mammalian alpha and beta rhythms (8-20 Hz). Contrary to expectation,
	near-linear relationships were found between the mean soma membrane
	potential and and neuronal firing probability. Some of the implications
	for cortical information processing, in particular the dynamical
	interactions between the neuronal and larger scales, are discussed.},
  institution = {School of Biophysical Sciences and Electrical Engineering, Swinburne
	University of Technology, Hawthorn, Vic, Australia.},
  keywords = {Alpha Rhythm; Animals; Cerebral Cortex, physiology; Computer Simulation;
	Mammals; Models, Neurological; Nerve Net; Neural Networks (Computer);
	Neurons, physiology; Pyramidal Cells, physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {10372763},
  timestamp = {2013.08.19}
}

@ARTICLE{Liley_2005,
  author = {D. T J Liley and I. Bojak},
  title = {Understanding the transition to seizure by modeling the epileptiform
	activity of general anesthetic agents.},
  journal = {J. Clin. Neurophysiol.},
  year = {2005},
  volume = {22},
  pages = {300--313},
  number = {5},
  month = {Oct},
  abstract = {A central difficulty in modeling epileptogenesis using biologically
	plausible computational and mathematical models is not the production
	of activity characteristic of a seizure, but rather producing it
	in response to specific and quantifiable physiologic change or pathologic
	abnormality. This is particularly problematic when it is considered
	that the pathophysiological genesis of most epilepsies is largely
	unknown. However, several volatile general anesthetic agents, whose
	principle targets of action are quantifiably well characterized,
	are also known to be proconvulsant. The authors describe recent approaches
	to theoretically describing the electroencephalographic effects of
	volatile general anesthetic agents that may be able to provide important
	insights into the physiologic mechanisms that underpin seizure initiation.},
  institution = {Centre for Intelligent Systems and Complex Processes, LSS, Swinburne
	University of Technology, Hawthorn, Australia. dliley@swin.edu.au},
  keywords = {Anesthetics, pharmacology; Animals; Electroencephalography, drug effects;
	Humans; Models, Theoretical; Neural Networks (Computer); Seizures,
	physiopathology; Time Factors},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {00004691-200510000-00003},
  pmid = {16357635},
  timestamp = {2013.02.18}
}

@ARTICLE{Liley_2002,
  author = {Liley, David T J. and Cadusch, Peter J. and Dafilis, Mathew P.},
  title = {A spatially continuous mean field theory of electrocortical activity.},
  journal = {Network},
  year = {2002},
  volume = {13},
  pages = {67--113},
  number = {1},
  month = {Feb},
  abstract = {A set of nonlinear continuum field equations is presented which describes
	the dynamics of neural activity in cortex. These take into account
	the most pertinent anatomical and physiological features found in
	cortex with all parameter values obtainable from independent experiment.
	Derivation of a white noise fluctuation spectrum from a linearized
	set of equations shows the presence of strong resonances that correspond
	to electroencephalographically observed 0.3-4 Hz (mammalian delta),
	4-8 Hz (mammalian theta), 8-13 Hz (mammalian alpha) and >13 Hz (mammalian
	beta) activity. Numerical solutions of a full set of one-dimensional
	nonlinear equations include properties analogous to cortical evoked
	potentials, travelling waves at experimentally observed velocities,
	threshold type spike activity and limit cycle, chaotic and noise
	driven oscillations at the frequency of the mammalian alpha rhythm.
	All these types of behaviour are generated with parameters that are
	within ranges reported experimentally. The strong dependence of the
	phenomena observed on inhibitory-inhibitory interactions is demonstrated.
	These results suggest that the classically described alpha may be
	instantiated in a number of qualitatively distinct dynamical regimes,
	all of which depend on the integrity of inhibitory-inhibitory population
	interactions.},
  institution = {School of Biophysical Sciences and Electrical Engineering, Swinburne
	University of Technology, Hawthorn, Victoria, Australia. dliley@swin.edu.au},
  keywords = {Algorithms; Cerebral Cortex, physiology; Electroencephalography; Electrophysiology;
	Kinetics; Linear Models; Membrane Potentials, physiology; Models,
	Neurological; Neural Conduction, physiology; Neurotransmitter Agents,
	physiology; Nonlinear Dynamics; Synaptic Transmission, physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paupau},
  pmid = {11878285},
  timestamp = {2013.08.24}
}

@ARTICLE{Liley_2013,
  author = {Liley, David T J. and Walsh, Matthew},
  title = {The Mesoscopic Modeling of Burst Suppression during Anesthesia.},
  journal = {Front Comput Neurosci},
  year = {2013},
  volume = {7},
  pages = {46},
  abstract = {The burst-suppression pattern is well recognized as a distinct feature
	of the mammalian electroencephalogram (EEG) waveform. Consisting
	of alternating periods of high amplitude oscillatory and isoelectric
	activity, it can be induced in health by deep anesthesia as well
	as being evoked by a range of pathophysiological processes that include
	coma and anoxia. While the electroencephalographic phenomenon and
	clinical implications of burst suppression have been studied extensively,
	the physiological mechanisms underlying its emergence remain unresolved
	and obscure. Because electroencephalographic bursting phenomenologically
	resembles the bursting observed in single neurons, it would be reasonable
	to assume that the theoretical insights developed to understand bursting
	at the cellular ("microscopic") level would enable insights into
	the dynamical genesis of bursting at the level of the whole brain
	("macroscopic"). In general action potential bursting is the result
	of the interplay of two time scales: a fast time scale responsible
	for spiking, and a slow time scale that modulates such activity.
	We therefore hypothesize that such fast-slow systems dynamically
	underpin electroencephalographic bursting. Here we show that a well-known
	mean field dynamical model of the electroencephalogram, the Liley
	model, while unable to produce burst suppression unmodified, is able
	to give rise to a wide variety of burst-like activity by the addition
	of one or more slow systems modulating model parameters speculated
	to be major "targets" for anesthetic action. The development of a
	physiologically plausible theoretical framework to account for burst
	suppression will lead to a more complete physiological understanding
	of the EEG and the mechanisms that serve to modify ongoing brain
	activity necessary for purposeful behavior and consciousness.},
  doi = {10.3389/fncom.2013.00046},
  institution = {Brain and Psychological Sciences Research Centre, Faculty of Life
	and Social Sciences, Swinburne University of Technology Hawthorn,
	VIC, Australia.},
  language = {eng},
  medline-pst = {epublish},
  owner = {paupau},
  pmid = {23641211},
  timestamp = {2013.08.24},
  url = {http://dx.doi.org/10.3389/fncom.2013.00046}
}

@ARTICLE{Litvak_2011,
  author = {Vladimir Litvak and Jérémie Mattout and Stefan Kiebel and Christophe
	Phillips and Richard Henson and James Kilner and Gareth Barnes and
	Robert Oostenveld and Jean Daunizeau and Guillaume Flandin and Will
	Penny and Karl Friston},
  title = {EEG and MEG data analysis in SPM8.},
  journal = {Comput Intell Neurosci},
  year = {2011},
  volume = {2011},
  pages = {852961},
  abstract = {SPM is a free and open source software written in MATLAB (The MathWorks,
	Inc.). In addition to standard M/EEG preprocessing, we presently
	offer three main analysis tools: (i) statistical analysis of scalp-maps,
	time-frequency images, and volumetric 3D source reconstruction images
	based on the general linear model, with correction for multiple comparisons
	using random field theory; (ii) Bayesian M/EEG source reconstruction,
	including support for group studies, simultaneous EEG and MEG, and
	fMRI priors; (iii) dynamic causal modelling (DCM), an approach combining
	neural modelling with data analysis for which there are several variants
	dealing with evoked responses, steady state responses (power spectra
	and cross-spectra), induced responses, and phase coupling. SPM8 is
	integrated with the FieldTrip toolbox , making it possible for users
	to combine a variety of standard analysis methods with new schemes
	implemented in SPM and build custom analysis tools using powerful
	graphical user interface (GUI) and batching tools.},
  doi = {10.1155/2011/852961},
  institution = {The Wellcome Trust Centre for Neuroimaging, UCL Institute of Neurology,
	Queen Square, London, UK. v.litvak@ion.ucl.ac.uk},
  keywords = {Bayes Theorem; Brain Mapping; Brain, anatomy /&/ histology/physiology;
	Computer Simulation; Diagnostic Imaging; Electroencephalography,
	methods; Humans; Image Processing, Computer-Assisted, methods; Magnetoencephalography,
	methods; Models, Neurological; Software; Time Factors},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {21437221},
  timestamp = {2013.08.28},
  url = {http://dx.doi.org/10.1155/2011/852961}
}

@ARTICLE{Lledo_2006,
  author = {Lledo, Pierre-Marie and Alonso, Mariana and Grubb, Matthew S.},
  title = {Adult neurogenesis and functional plasticity in neuronal circuits.},
  journal = {Nat Rev Neurosci},
  year = {2006},
  volume = {7},
  pages = {179--193},
  number = {3},
  month = {Mar},
  abstract = {The adult brain is a plastic place. To ensure that the mature nervous
	system's control of behaviour is flexible in the face of a varying
	environment, morphological and physiological changes are possible
	at many levels, including that of the entire cell. In two areas of
	the adult brain - the olfactory bulb and the dentate gyrus - new
	neurons are generated throughout life and form an integral part of
	the normal functional circuitry. This process is not fixed, but highly
	modulated, revealing a plastic mechanism by which the brain's performance
	can be optimized for a given environment. The functional benefits
	of this whole-cell plasticity, however, remain a matter for debate.},
  doi = {10.1038/nrn1867},
  institution = {Laboratory of Perception and Memory, Institut Pasteur, Centre National
	de la Recherche Scientifique Unit de Recherche Associée 2182, 25,
	rue du Docteur Roux, 75724 Paris cedex 15, France. pmlledo@pasteur.fr},
  keywords = {Animals; Cell Differentiation, physiology; Cell Proliferation; Dentate
	Gyrus, cytology; Humans; Models, Neurological; Nerve Net, cytology/physiology;
	Neuronal Plasticity, physiology; Neurons, physiology; Olfactory Bulb,
	cytology; Stem Cells, physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paupau},
  pii = {nrn1867},
  pmid = {16495940},
  timestamp = {2013.08.22},
  url = {http://dx.doi.org/10.1038/nrn1867}
}

@ARTICLE{Logothetis_2003,
  author = {Nikos K Logothetis},
  title = {MR imaging in the non-human primate: studies of function and of dynamic
	connectivity.},
  journal = {Curr Opin Neurobiol},
  year = {2003},
  volume = {13},
  pages = {630--642},
  number = {5},
  month = {Oct},
  abstract = {Since its early development in the late 1940s, nuclear magnetic resonance
	has become a powerful tool for applications ranging from chemical
	analysis or the study of the structure of solids to biomedical investigations.
	In the early 1990s the potential of this technique for functional
	brain mapping was demonstrated, causing unprecedented excitement
	in both basic and clinical neuroscience. It was shown that by using
	the appropriate pulse sequences the so-called functional magnetic
	resonance imaging (fMRI) technique can be made sensitive to local
	magnetic susceptibility alterations produced by changes in the concentration
	of deoxyhemoglobin in venous blood vessels. This blood-oxygenation-level-dependent
	(BOLD) contrast mechanism was successfully implemented in awake human
	subjects, in small animals, and recently in the non-human primate--the
	experimental animal of choice for the study of cognitive behavior.
	Simultaneous imaging and electrode recordings promise new insights
	into the mechanisms by which large-scale networks in the brain contribute
	to the local neural activity recorded at a given cortical site. Moreover,
	the use of MRI-visible tracers and of electrical microstimulation
	applied during imaging proves to be ideal for the study of connectivity
	in the living animal.},
  institution = {Max Planck Institute for Biological Cybernetics, Department of Physiology
	of Cognitive Processes, Spemannstr 38, 72076 Tübingen, Germany. nikos.logothetis@tuebingen.mpg.de},
  keywords = {Animals; Brain, physiology; Magnetic Resonance Imaging, methods; Nerve
	Net, physiology; Primates, physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S0959438803001466},
  pmid = {14630229},
  timestamp = {2013.08.19}
}

@ARTICLE{Logothetis_2003a,
  author = {Nikos K Logothetis},
  title = {The underpinnings of the BOLD functional magnetic resonance imaging
	signal.},
  journal = {J Neurosci},
  year = {2003},
  volume = {23},
  pages = {3963--3971},
  number = {10},
  month = {May},
  institution = {Max Planck Institute for Biological Cybernetics, 72076 Tuebingen,
	Germany. nikos.logothetis@tuebingen.mpg.de},
  keywords = {Animals; Brain, blood supply/physiology; Carbon Dioxide, blood; Cerebrovascular
	Circulation, physiology; Echo-Planar Imaging, methods; Humans; Magnetic
	Resonance Imaging, methods; Magnetic Resonance Spectroscopy, methods;
	Oxygen, blood},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {23/10/3963},
  pmid = {12764080},
  timestamp = {2013.08.19}
}

@ARTICLE{Logothetis_2002,
  author = {Nikos K Logothetis},
  title = {The neural basis of the blood-oxygen-level-dependent functional magnetic
	resonance imaging signal.},
  journal = {Philos Trans R Soc Lond B Biol Sci},
  year = {2002},
  volume = {357},
  pages = {1003--1037},
  number = {1424},
  month = {Aug},
  abstract = {Magnetic resonance imaging (MRI) has rapidly become an important tool
	in clinical medicine and biological research. Its functional variant
	(functional magnetic resonance imaging; fMRI) is currently the most
	widely used method for brain mapping and studying the neural basis
	of human cognition. While the method is widespread, there is insufficient
	knowledge of the physiological basis of the fMRI signal to interpret
	the data confidently with respect to neural activity. This paper
	reviews the basic principles of MRI and fMRI, and subsequently discusses
	in some detail the relationship between the blood-oxygen-level-dependent
	(BOLD) fMRI signal and the neural activity elicited during sensory
	stimulation. To examine this relationship, we conducted the first
	simultaneous intracortical recordings of neural signals and BOLD
	responses. Depending on the temporal characteristics of the stimulus,
	a moderate to strong correlation was found between the neural activity
	measured with microelectrodes and the BOLD signal averaged over a
	small area around the microelectrode tips. However, the BOLD signal
	had significantly higher variability than the neural activity, indicating
	that human fMRI combined with traditional statistical methods underestimates
	the reliability of the neuronal activity. To understand the relative
	contribution of several types of neuronal signals to the haemodynamic
	response, we compared local field potentials (LFPs), single- and
	multi-unit activity (MUA) with high spatio-temporal fMRI responses
	recorded simultaneously in monkey visual cortex. At recording sites
	characterized by transient responses, only the LFP signal was significantly
	correlated with the haemodynamic response. Furthermore, the LFPs
	had the largest magnitude signal and linear systems analysis showed
	that the LFPs were better than the MUAs at predicting the fMRI responses.
	These findings, together with an analysis of the neural signals,
	indicate that the BOLD signal primarily measures the input and processing
	of neuronal information within a region and not the output signal
	transmitted to other brain regions.},
  doi = {10.1098/rstb.2002.1114},
  institution = {Max Planck Institute for Biological Cybernetics, Spemannstrasse 38,
	72076 Tübingen, Germany. nikos.logothetis@tuebingen.mpg.de},
  keywords = {Animals; Brain Mapping, methods; Brain, cytology/physiology; Haplorhini,
	physiology; Magnetic Resonance Imaging, methods; Neurons, physiology;
	Oxygen Consumption; Oxygen, blood; Perception, physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {12217171},
  timestamp = {2013.08.19},
  url = {http://dx.doi.org/10.1098/rstb.2002.1114}
}

@ARTICLE{Logothetis_1999,
  author = {N. K. Logothetis and H. Guggenberger and S. Peled and J. Pauls},
  title = {Functional imaging of the monkey brain.},
  journal = {Nat Neurosci},
  year = {1999},
  volume = {2},
  pages = {555--562},
  number = {6},
  month = {Jun},
  abstract = {Functional magnetic resonance imaging (fMRI) has become an essential
	tool for studying human brain function. Here we describe the application
	of this technique to anesthetized monkeys. We present spatially resolved
	functional images of the monkey cortex based on blood oxygenation
	level dependent (BOLD) contrast. Checkerboard patterns or pictures
	of primates were used to study stimulus-induced activation of the
	visual cortex, in a 4.7-Tesla magnetic field, using optimized multi-slice,
	gradient-recalled, echo-planar imaging (EPI) sequences to image the
	entire brain. Under our anesthesia protocol, visual stimulation yielded
	robust, reproducible, focal activation of the lateral geniculate
	nucleus (LGN), the primary visual area (V1) and a number of extrastriate
	visual areas, including areas in the superior temporal sulcus. Similar
	responses were obtained in alert, behaving monkeys performing a discrimination
	task.},
  doi = {10.1038/9210},
  institution = {Max Planck Institute for Biological Cybernetics, Spemannstr. 38,
	72076 Tübingen, Germany. nikos.logothetis@tuebingen.mpg.de},
  keywords = {Animals; Brain, blood supply/physiology; Discrimination (Psychology),
	physiology; Geniculate Bodies, physiology; Macaca mulatta, physiology;
	Magnetic Resonance Imaging; Oxygen, blood; Photic Stimulation, methods;
	Time Factors; Visual Cortex, physiology; Visual Pathways, physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {10448221},
  timestamp = {2013.08.19},
  url = {http://dx.doi.org/10.1038/9210}
}

@ARTICLE{Logothetis_2009,
  author = {Nikos K Logothetis and Yusuke Murayama and Mark Augath and Theodor
	Steffen and Joachim Werner and Axel Oeltermann},
  title = {How not to study spontaneous activity.},
  journal = {Neuroimage},
  year = {2009},
  volume = {45},
  pages = {1080--1089},
  number = {4},
  month = {May},
  abstract = {Brains are restless. We have long known of the existence of a great
	deal of uninterrupted brain activity that maintains the body in a
	stable state--from an evolutionary standpoint one of the brain's
	most ancient tasks. But intrinsic, ongoing activity is not limited
	to subcortical, life-maintaining structures; cortex, too, is remarkably
	active even in the absence of a sensory stimulus or a specific behavioral
	task. This is evident both in its enormous energy consumption at
	rest and in the large, spontaneous but coherent fluctuations of neural
	activity that spread across different areas. Not surprisingly, a
	growing number of electrophysiological and functional magnetic resonance
	imaging (fMRI) studies are appearing that report on various aspects
	of the brain's spontaneous activity or "default mode" of operation.
	One recent study reports results from simultaneously combined electrophysiological
	and fMRI measurements in the monkey visual cortex (Shmuel, A., Leopold,
	D.A., 2008. Neuronal correlates of spontaneous fluctuations in fMRI
	signals in monkey visual cortex: implications for functional connectivity
	at rest. Hum. Brain Mapp. 29, 751-761). The authors claim to be able
	to demonstrate correlations between slow fluctuations in blood-oxygen-level-dependent
	(BOLD) signals and concurrent fluctuations in the underlying, locally
	measured neuronal activity. They even go on to speculate that the
	fluctuations display wave-like spatiotemporal patterns across cortex.
	In the present report, however, we re-analyze the data presented
	in that study and demonstrate that the measurements were not actually
	taken during rest. Visual cortex was subject to almost imperceptible
	but physiologically clearly detectable flicker induced by the visual
	stimulator. An examination of the power spectral density of the neural
	responses and the neurovascular impulse response function shows that
	such imperceptible flicker strongly suppresses the slow oscillations
	and changes the degree of covariance between neural and vascular
	signals. In addition, a careful analysis of the spatiotemporal patterns
	demonstrates that no slow waves of activity exist in visual cortex;
	instead, the presented wave data reflect differences in signal-to-noise
	ratio at various cortical sites due to local differences in vascularization.
	In this report, assuming that the term "spontaneous activity" refers
	to intrinsic physiological processes at the absence of sensory inputs
	or motor outputs, we discuss the need for careful selection of experimental
	protocols and of examining the degree to which the activation of
	sensory areas might influence the cortical or subcortical processes
	in other brain regions.},
  doi = {10.1016/j.neuroimage.2009.01.010},
  keywords = {Animals; Artifacts; Brain Mapping, methods; Evoked Potentials, physiology;
	Haplorhini; Magnetic Resonance Imaging, methods; Photic Stimulation,
	methods; Visual Cortex, physiology; Visual Perception, physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S1053-8119(09)00023-8},
  pmid = {19344685},
  timestamp = {2013.08.19},
  url = {http://dx.doi.org/10.1016/j.neuroimage.2009.01.010}
}

@ARTICLE{Logothetis_2001,
  author = {N. K. Logothetis and J. Pauls and M. Augath and T. Trinath and A.
	Oeltermann},
  title = {Neurophysiological investigation of the basis of the fMRI signal.},
  journal = {Nature},
  year = {2001},
  volume = {412},
  pages = {150--157},
  number = {6843},
  month = {Jul},
  abstract = {Functional magnetic resonance imaging (fMRI) is widely used to study
	the operational organization of the human brain, but the exact relationship
	between the measured fMRI signal and the underlying neural activity
	is unclear. Here we present simultaneous intracortical recordings
	of neural signals and fMRI responses. We compared local field potentials
	(LFPs), single- and multi-unit spiking activity with highly spatio-temporally
	resolved blood-oxygen-level-dependent (BOLD) fMRI responses from
	the visual cortex of monkeys. The largest magnitude changes were
	observed in LFPs, which at recording sites characterized by transient
	responses were the only signal that significantly correlated with
	the haemodynamic response. Linear systems analysis on a trial-by-trial
	basis showed that the impulse response of the neurovascular system
	is both animal- and site-specific, and that LFPs yield a better estimate
	of BOLD responses than the multi-unit responses. These findings suggest
	that the BOLD contrast mechanism reflects the input and intracortical
	processing of a given area rather than its spiking output.},
  doi = {10.1038/35084005},
  institution = {Max Planck Institute for Biological Cybernetics, Tuebingen, Germany.
	nikos.logothetis@tuebingen.mpg.de},
  keywords = {Action Potentials; Animals; Contrast Sensitivity; Electrodes; Electrophysiology;
	Hemodynamics; Macaca mulatta; Magnetic Resonance Imaging; Neurons,
	physiology; Oxygen, blood; Photic Stimulation; Signal Processing,
	Computer-Assisted; Synaptic Transmission; Visual Cortex, physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {35084005},
  pmid = {11449264},
  timestamp = {2013.04.17},
  url = {http://dx.doi.org/10.1038/35084005}
}

@ARTICLE{Logothetis_2004,
  author = {Nikos K Logothetis and Brian A Wandell},
  title = {Interpreting the BOLD signal.},
  journal = {Annu Rev Physiol},
  year = {2004},
  volume = {66},
  pages = {735--769},
  abstract = {The development of functional magnetic resonance imaging (fMRI) has
	brought together a broad community of scientists interested in measuring
	the neural basis of the human mind. Because fMRI signals are an indirect
	measure of neural activity, interpreting these signals to make deductions
	about the nervous system requires some understanding of the signaling
	mechanisms. We describe our current understanding of the causal relationships
	between neural activity and the blood-oxygen-level-dependent (BOLD)
	signal, and we review how these analyses have challenged some basic
	assumptions that have guided neuroscience. We conclude with a discussion
	of how to use the BOLD signal to make inferences about the neural
	signal.},
  doi = {10.1146/annurev.physiol.66.082602.092845},
  institution = {Max-Planck Institut fur Biologische Kybernetik, Tubingen, Germany.},
  keywords = {Animals; Brain Mapping; Brain, physiology; Cerebrovascular Circulation;
	Electrophysiology; Humans; Magnetic Resonance Imaging; Models, Neurological;
	Oxygen, blood},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {14977420},
  timestamp = {2013.08.19},
  url = {http://dx.doi.org/10.1146/annurev.physiol.66.082602.092845}
}

@ARTICLE{Loh_2012,
  author = {Loh, K. B. and Ramli, N. and Tan, L. K. and Roziah, M. and Rahmat,
	K. and Ariffin, H.},
  title = {Quantification of diffusion tensor imaging in normal white matter
	maturation of early childhood using an automated processing pipeline.},
  journal = {Eur. Radiol.},
  year = {2012},
  volume = {22},
  pages = {1413--1426},
  number = {7},
  month = {Jul},
  abstract = {The degree and status of white matter myelination can be sensitively
	monitored using diffusion tensor imaging (DTI). This study looks
	at the measurement of fractional anistropy (FA) and mean diffusivity
	(MD) using an automated ROI with an existing DTI atlas.Anatomical
	MRI and structural DTI were performed cross-sectionally on 26 normal
	children (newborn to 48 months old), using 1.5-T MRI. The automated
	processing pipeline was implemented to convert diffusion-weighted
	images into the NIfTI format. DTI-TK software was used to register
	the processed images to the ICBM DTI-81 atlas, while AFNI software
	was used for automated atlas-based volumes of interest (VOIs) and
	statistical value extraction.DTI exhibited consistent grey-white
	matter contrast. Triphasic temporal variation of the FA and MD values
	was noted, with FA increasing and MD decreasing rapidly early in
	the first 12 months. The second phase lasted 12-24 months during
	which the rate of FA and MD changes was reduced. After 24 months,
	the FA and MD values plateaued.DTI is a superior technique to conventional
	MR imaging in depicting WM maturation. The use of the automated processing
	pipeline provides a reliable environment for quantitative analysis
	of high-throughput DTI data.Diffusion tensor imaging outperforms
	conventional MRI in depicting white matter maturation. • DTI will
	become an important clinical tool for diagnosing paediatric neurological
	diseases. • DTI appears especially helpful for developmental abnormalities,
	tumours and white matter disease. • An automated processing pipeline
	assists quantitative analysis of high throughput DTI data.},
  doi = {10.1007/s00330-012-2396-3},
  institution = {Department of Biomedical Imaging, University Malaya Research Imaging
	Centre (UMRIC), Faculty of Medicine, University of Malaya, 50603,
	Kuala Lumpur, Malaysia.},
  keywords = {Aging, pathology/physiology; Algorithms; Brain, anatomy /&/ histology/growth
	/&/ development; Child; Child, Preschool; Diffusion Magnetic Resonance
	Imaging, methods; Female; Humans; Image Enhancement, methods; Image
	Interpretation, Computer-Assisted, methods; Infant; Infant, Newborn;
	Male; Nerve Fibers, Myelinated, physiology/ultrastructure; Pattern
	Recognition, Automated, methods; Reproducibility of Results; Sensitivity
	and Specificity},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paupau},
  pmid = {22434420},
  timestamp = {2013.02.25},
  url = {http://dx.doi.org/10.1007/s00330-012-2396-3}
}

@ARTICLE{LopesdaSilva_2008,
  author = {Lopes da Silva, F. H.,},
  title = {The impact of EEG/MEG signal processing and modeling in the diagnostic
	and management of epilepsy.},
  journal = {IEEE Rev. Biomed. Eng.},
  year = {2008},
  volume = {1},
  pages = {143--156},
  abstract = {This overview covers recent advances in the field of EEG/MEG signal
	processing and modeling in epilepsy regarding both interictal and
	ictal phenomena. In the first part, the main methods used in the
	analysis of interictal EEG/MEG epileptiform spikes are presented
	and discussed. Source and volume conductor models are passed in review,
	namely the equivalent dipole source concept, the requirements for
	adequate time and spatial sampling, the question of how to validate
	source solutions, particularly by comparing solutions obtained using
	scalp and intracranial EEG signals, EEG & MEG data, or EEG simultaneously
	recorded with fMRI (BOLD signals). In the second part, methods used
	for the characterization of seizures are considered, namely dipolar
	modeling of spikes at seizure onset, decomposition of seizure EEG
	signals into sets of orthogonal spatio-temporal components, and also
	methods (linear and nonlinear) of estimating seizure propagation.
	In the third part, the crucial issue of how the transition between
	interictal and seizure activity takes place is examined. In particular
	the vicissitudes of the efforts along the road to seizure prediction
	are shortly reviewed. It is argued that this question can be reduced
	to the problem of estimating the excitability state of neuronal populations
	in the course of time as a seizure approaches. The value of active
	probing methods in contrast with passive analytical methods is emphasized.
	In the fourth part modeling aspects are considered in the light of
	two special kinds of epilepsies, absences characterized by spike-and-wave
	discharges and mesial temporal lobe epilepsy. These two types correspond
	to different scenarios regarding the transition to epileptic seizures,
	namely the former is a case of a jump transition and the latter is
	a typical case of gradual transition. In conclusion, the necessity
	of developing comprehensive computational models of epileptic seizures
	is emphasized.},
  doi = {10.1109/RBME.2008.2008246},
  institution = {Center of Neurosciences, Swammerdam Institute for Life Sciences,
	University of Amsterdam, 1098 SM Amsterdam, The Netherlands. F.H.LopesdaSilva@uva.nl},
  keywords = {Animals; Electroencephalography, methods; Epilepsy, physiopathology/radiography/therapy;
	Humans; Magnetic Resonance Imaging, methods; Models, Neurological;
	Signal Processing, Computer-Assisted; Therapy, Computer-Assisted,
	methods},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {22274902},
  timestamp = {2013.02.11},
  url = {http://dx.doi.org/10.1109/RBME.2008.2008246}
}

@ARTICLE{LopesdaSilva_2006,
  author = {Lopes da Silva, F. H.,},
  title = {Event-related neural activities: what about phase?},
  journal = {Prog. Brain Res.},
  year = {2006},
  volume = {159},
  pages = {3--17},
  doi = {10.1016/S0079-6123(06)59001-6},
  keywords = {Animals; Cortical Synchronization; Electroencephalography; Evoked
	Potentials, physiology; Humans; Neurons, physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S0079-6123(06)59001-6},
  pmid = {17071220},
  timestamp = {2013.02.11},
  url = {http://dx.doi.org/10.1016/S0079-6123(06)59001-6}
}

@ARTICLE{LopesdaSilva_2004,
  author = {Lopes da Silva, F. H.,},
  title = {Functional localization of brain sources using EEG and/or MEG data:
	volume conductor and source models.},
  journal = {Magn. Reson. Imaging},
  year = {2004},
  volume = {22},
  pages = {1533--1538},
  number = {10},
  month = {Dec},
  abstract = {In this overview we examine the basic principles of properties of
	electroencephalogram and magnetoencephalogram and the corresponding
	models of sources and of the volume conductor. In particular we show
	how the dipolar model is anchored in neurophysiological findings
	and how the different conductivities of the brain and the tissue
	surrounding it can be estimated. Using these basic models as tools
	we show how the functional localization of the neural sources of
	rhythmic activities (alpha and mu rhythms and sleep spindles) and
	of epileptiform activities can be estimated and integrated with structural
	data of the brain obtained with MRI.},
  doi = {10.1016/j.mri.2004.10.010},
  institution = {Center Neurosciences, Swammerdam Institute for Life Sciences, University
	of Amsterdam, 1098SM Amsterdam, Netherlands. silva@science.uva.nl},
  keywords = {Brain, physiology; Electroencephalography, methods; Humans; Magnetic
	Resonance Imaging, methods; Magnetoencephalography, methods; Models,
	Neurological; Neural Conduction, physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S0730-725X(04)00305-4},
  pmid = {15707802},
  timestamp = {2013.02.11},
  url = {http://dx.doi.org/10.1016/j.mri.2004.10.010}
}

@ARTICLE{LopesdaSilva_2003,
  author = {Lopes da Silva, F. H.,},
  title = {Visual dreams in the congenitally blind?},
  journal = {Trends Cogn. Sci. (Regul. Ed.)},
  year = {2003},
  volume = {7},
  pages = {328--330},
  number = {8},
  month = {Aug},
  abstract = {An EEG study of sleep in congenitally blind persons revealed a significant
	correlation between the visual activity reported during dreaming
	and the decrease of alpha strength recorded from the central and
	occipital regions of the scalp. This provides the first objective
	evidence that subjects who have never had visual experiences can
	have dreams with virtual images that are probably mediated by the
	activation of the cortical areas responsible for visual representations.},
  institution = {Neurobiology Section, Swammerdam Institute for Life Sciences, University
	of Amsterdam, The Netherlands},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S1364661303001554},
  pmid = {12907221},
  timestamp = {2013.02.11}
}

@ARTICLE{LopesdaSilva_2003a,
  author = {Lopes da Silva, F. H., and Wouter Blanes and Stiliyan N Kalitzin
	and Jaime Parra and Piotr Suffczynski and Demetrios N Velis},
  title = {Dynamical diseases of brain systems: different routes to epileptic
	seizures.},
  journal = {IEEE Trans. Biomed. Eng.},
  year = {2003},
  volume = {50},
  pages = {540--548},
  number = {5},
  month = {May},
  abstract = {In this overview, we consider epilepsies as dynamical diseases of
	brain systems since they are manifestations of the property of neuronal
	networks to display multistable dynamics. To illustrate this concept
	we may assume that at least two states of the epileptic brain are
	possible: the interictal state characterized by a normal, apparently
	random, steady-state electroencephalography (EEG) ongoing activity,
	and the ictal state, that is characterized by paroxysmal occurrence
	of synchronous oscillations and is generally called, in neurology,
	a seizure. The transition between these two states can either occur:
	1) as a continuous sequence of phases, like in some cases of mesial
	temporal lobe epilepsy (MTLE); or 2) as a sudden leap, like in most
	cases of absence seizures. In the mathematical terminology of nonlinear
	systems, we can say that in the first case the system's attractor
	gradually deforms from an interictal to an ictal attractor. The causes
	for such a deformation can be either endogenous or external. In this
	type of ictal transition, the seizure possibly may be anticipated
	in its early, preclinical phases. In the second case, where a sharp
	critical transition takes place, we can assume that the system has
	at least two simultaneous interictal and ictal attractors all the
	time. To which attractor the trajectories converge, depends on the
	initial conditions and the system's parameters. An essential question
	in this scenario is how the transition between the normal ongoing
	and the seizure activity takes place. Such a transition can occur
	either due to the influence of external or endogenous factors or
	due to a random perturbation and, thus, it will be unpredictable.
	These dynamical changes may not be detectable from the analysis of
	the ongoing EEG, but they may be observable only by measuring the
	system's response to externally administered stimuli. In the special
	cases of reflex epilepsy, the leap between the normal ongoing attractor
	and the ictal attractor is caused by a well-defined external perturbation.
	Examples from these different scenarios are presented and discussed.},
  doi = {10.1109/TBME.2003.810703},
  institution = {Dutch Epilepsy Clinics Foundation, Meer en Bosch, 2103 SW, Heemstede,
	The Netherlands.},
  keywords = {Brain, physiopathology; Electroencephalography, methods; Epilepsy,
	physiopathology; Humans; Magnetoencephalography, methods; Models,
	Neurological; Nerve Net, physiopathology; Neurons; Nonlinear Dynamics;
	Seizures, physiopathology; Signal Processing, Computer-Assisted},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {12769430},
  timestamp = {2013.02.11},
  url = {http://dx.doi.org/10.1109/TBME.2003.810703}
}

@ARTICLE{LopesdaSilva_2003b,
  author = {Lopes da Silva, F. H., and Wouter Blanes and Stiliyan N Kalitzin
	and Jaime Parra and Piotr Suffczynski and Demetrios N Velis},
  title = {Epilepsies as dynamical diseases of brain systems: basic models of
	the transition between normal and epileptic activity.},
  journal = {Epilepsia},
  year = {2003},
  volume = {44 Suppl 12},
  pages = {72--83},
  abstract = {The occurrence of abnormal dynamics in a physiological system can
	become manifest as a sudden qualitative change in the behavior of
	characteristic physiologic variables. We assume that this is what
	happens in the brain with regard to epilepsy. We consider that neuronal
	networks involved in epilepsy possess multistable dynamics (i.e.,
	they may display several dynamic states). To illustrate this concept,
	we may assume, for simplicity, that at least two states are possible:
	an interictal one characterized by a normal, apparently random, steady-state
	of ongoing activity, and another one that is characterized by the
	paroxysmal occurrence of a synchronous oscillations (seizure).By
	using the terminology of the mathematics of nonlinear systems, we
	can say that such a bistable system has two attractors, to which
	the trajectories describing the system's output converge, depending
	on initial conditions and on the system's parameters. In phase-space,
	the basins of attraction corresponding to the two states are separated
	by what is called a "separatrix." We propose, schematically, that
	the transition between the normal ongoing and the seizure activity
	can take place according to three basic models: Model I: In certain
	epileptic brains (e.g., in absence seizures of idiopathic primary
	generalized epilepsies), the distance between "normal steady-state"
	and "paroxysmal" attractors is very small in contrast to that of
	a normal brain (possibly due to genetic and/or developmental factors).
	In the former, discrete random fluctuations of some variables can
	be sufficient for the occurrence of a transition to the paroxysmal
	state. In this case, such seizures are not predictable. Model II
	and model III: In other kinds of epileptic brains (e.g., limbic cortex
	epilepsies), the distance between "normal steady-state" and "paroxysmal"
	attractors is, in general, rather large, such that random fluctuations,
	of themselves, are commonly not capable of triggering a seizure.
	However, in these brains, neuronal networks have abnormal features
	characterized by unstable parameters that are very vulnerable to
	the influence of endogenous (model II) and/or exogenous (model III)
	factors. In these cases, these critical parameters may gradually
	change with time, in such a way that the attractor can deform either
	gradually or suddenly, with the consequence that the distance between
	the basin of attraction of the normal state and the separatrix tends
	to zero. This can lead, eventually, to a transition to a seizure.The
	changes of the system's dynamics preceding a seizure in these models
	either may be detectable in the EEG and thus the route to the seizure
	may be predictable, or may be unobservable by using only measurements
	of the dynamical state. It is thinkable, however, that in some cases,
	changes in the excitability state of the underlying networks may
	be uncovered by using appropriate stimuli configurations before changes
	in the dynamics of the ongoing EEG activity are evident. A typical
	example of model III that we discuss here is photosensitive epilepsy.We
	present an overview of these basic models, based on neurophysiologic
	recordings combined with signal analysis and on simulations performed
	by using computational models of neuronal networks. We pay especial
	attention to recent model studies and to novel experimental results
	obtained while analyzing EEG features preceding limbic seizures and
	during intermittent photic stimulation that precedes the transition
	to paroxysmal epileptic activity.},
  institution = {SEIN, Special Centre for Epilepsy in the Netherlands, Meer en Bosch,
	Heemstede, The Netherlands.},
  keywords = {Brain Stem, physiopathology; Brain, physiopathology; Disease Progression;
	Electroencephalography; Epilepsy, diagnosis/physiopathology; Humans;
	Kindling, Neurologic, physiology; Limbic System, physiopathology;
	Nerve Net, physiology; Neural Inhibition, physiology; Neurons, Afferent,
	physiology; Prosencephalon, physiopathology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {12005},
  pmid = {14641563},
  timestamp = {2013.02.11}
}

@ARTICLE{LopesdaSilva_2011,
  author = {Lopes da Silva, F. H., and Graham F A Harding},
  title = {Transition to seizure in photosensitive epilepsy.},
  journal = {Epilepsy Res.},
  year = {2011},
  volume = {97},
  pages = {278--282},
  number = {3},
  month = {Dec},
  abstract = {Photosensitive epilepsy (PSE) offers a highly reproducible model to
	investigate whether changes in neuronal activity preceding the transition
	to an epileptic photoparoxysmal response (PPR) may be detected. We
	investigated this possibility in patients with idiopathic PSE using
	MEG, as well as normal controls and non-photosensitive epileptic
	patients of the same age group. Spectral analysis of the MEG signals
	recorded during intermittent light stimulation revealed relevant
	information in the phase spectrum. To quantify this effect, we introduced
	a second order response feature of the stimulus-triggered visual
	response preceding the PPR: the phase clustering index, which measures
	how close the phases of successive periods are grouped for each frequency
	component for all periods of the stimuli applied. We found that an
	enhancement of phase synchrony in the gamma-band (30-120Hz), harmonically
	related to the frequency of stimulation, preceded the stimulation
	trials that evolved into PPRs, and differed significantly from that
	encountered in trials not followed by PPR or in control subjects.
	Thus this index can be considered a valuable index of the pro-ictal
	transition to seizures in photosensitive epilepsy.},
  doi = {10.1016/j.eplepsyres.2011.10.022},
  institution = { University of Amsterdam, Kamer C3-269, Science Park 904, 1098 XH
	Amsterdam, The Netherlands. F.H.LopesdaSilva@uva.nl},
  keywords = {Brain Waves; Brain, physiopathology; Electroencephalography; Epilepsy,
	Reflex, complications; Humans; Magnetoencephalography; Photic Stimulation,
	adverse effects; Seizures, etiology; Signal Processing, Computer-Assisted},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S0920-1211(11)00330-5},
  pmid = {22071550},
  timestamp = {2013.02.11},
  url = {http://dx.doi.org/10.1016/j.eplepsyres.2011.10.022}
}

@ARTICLE{LopesdaSilva_1974,
  author = {Lopes da Silva, F. H. and Hoeks, A. and Smits, H. and Zetterberg,
	L. H.},
  title = {Model of brain rhythmic activity},
  journal = {Biol. Cybern.},
  year = {1974},
  volume = {15},
  pages = {27-37},
  doi = {10.1007/BF00270757},
  issn = {0340-1200},
  issue = {1},
  keyword = {Computer Science},
  publisher = {Springer Berlin / Heidelberg}
}

@ARTICLE{LynnTimlake_1968,
  author = {Lynn, M.S. and Timlake, W.P.},
  title = {{The use of multiple deflations in the numerical solution of singular
	systems of equations, with applications to potential theory}},
  journal = {SIAM J. Numer. Anal.},
  year = {1968},
  volume = {5},
  pages = {303--322},
  number = {2},
  issn = {0036-1429}
}

@ARTICLE{Mannella_2002,
  author = {Mannella, R},
  title = {Integration of Stochastic Differential Equations on a Computer},
  journal = {Internat. J. Modern Phys. C},
  year = {2002},
  volume = {13},
  pages = {1177-1194},
  number = {9},
  owner = {paula},
  timestamp = {2012.10.25}
}

@ARTICLE{Mannella_1989,
  author = {Mannella, R and Palleschi, V},
  title = {Fast and precise algorithm for computer simulation of stochastic
	differential equations},
  journal = {Phys. Rev. A},
  year = {1989},
  volume = {40},
  pages = {3381-},
  owner = {paula},
  timestamp = {2012.10.25}
}

@ARTICLE{Marinazzo_2012,
  author = {Daniele Marinazzo and Guorong Wu and Mario Pellicoro and Leonardo
	Angelini and Sebastiano Stramaglia},
  title = {Information flow in networks and the law of diminishing marginal
	returns: evidence from modeling and human electroencephalographic
	recordings.},
  journal = {PLoS One},
  year = {2012},
  volume = {7},
  pages = {e45026},
  number = {9},
  abstract = {We analyze simple dynamical network models which describe the limited
	capacity of nodes to process the input information. For a proper
	range of their parameters, the information flow pattern in these
	models is characterized by exponential distribution of the incoming
	information and a fat-tailed distribution of the outgoing information,
	as a signature of the law of diminishing marginal returns. We apply
	this analysis to effective connectivity networks from human EEG signals,
	obtained by Granger Causality, which has recently been given an interpretation
	in the framework of information theory. From the distributions of
	the incoming versus the outgoing values of the information flow it
	is evident that the incoming information is exponentially distributed
	whilst the outgoing information shows a fat tail. This suggests that
	overall brain effective connectivity networks may also be considered
	in the light of the law of diminishing marginal returns. Interestingly,
	this pattern is reproduced locally but with a clear modulation: a
	topographic analysis has also been made considering the distribution
	of incoming and outgoing values at each electrode, suggesting a functional
	role for this phenomenon.},
  doi = {10.1371/journal.pone.0045026},
  institution = {Department of Data Analysis, Ghent University, Belgium. daniele.marinazzo@ugent.be},
  keywords = {Electroencephalography; Humans; Information Theory; Models, Neurological;
	Nerve Net, physiology; Probability},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {PONE-D-12-15309},
  pmid = {23028745},
  timestamp = {2013.08.30},
  url = {http://dx.doi.org/10.1371/journal.pone.0045026}
}

@ARTICLE{Markounikau_2010,
  author = {Markounikau, Valentin and Igel, Christian and Grinvald, Amiram and
	Jancke, Dirk},
  title = {A dynamic neural field model of mesoscopic cortical activity captured
	with voltage-sensitive dye imaging.},
  journal = {PLoS Comput Biol},
  year = {2010},
  volume = {6},
  pages = {e1000919},
  number = {9},
  abstract = {A neural field model is presented that captures the essential non-linear
	characteristics of activity dynamics across several millimeters of
	visual cortex in response to local flashed and moving stimuli. We
	account for physiological data obtained by voltage-sensitive dye
	(VSD) imaging which reports mesoscopic population activity at high
	spatio-temporal resolution. Stimulation included a single flashed
	square, a single flashed bar, the line-motion paradigm--for which
	psychophysical studies showed that flashing a square briefly before
	a bar produces sensation of illusory motion within the bar--and moving
	squares controls. We consider a two-layer neural field (NF) model
	describing an excitatory and an inhibitory layer of neurons as a
	coupled system of non-linear integro-differential equations. Under
	the assumption that the aggregated activity of both layers is reflected
	by VSD imaging, our phenomenological model quantitatively accounts
	for the observed spatio-temporal activity patterns. Moreover, the
	model generalizes to novel similar stimuli as it matches activity
	evoked by moving squares of different speeds. Our results indicate
	that feedback from higher brain areas is not required to produce
	motion patterns in the case of the illusory line-motion paradigm.
	Physiological interpretation of the model suggests that a considerable
	fraction of the VSD signal may be due to inhibitory activity, supporting
	the notion that balanced intra-layer cortical interactions between
	inhibitory and excitatory populations play a major role in shaping
	dynamic stimulus representations in the early visual cortex.},
  doi = {10.1371/journal.pcbi.1000919},
  institution = {Institut für Neuroinformatik, Ruhr-Universität Bochum, Bochum, Germany.
	valiantsin.markounikau@ruhr-uni-bochum.de},
  keywords = {Animals; Cats; Computational Biology, methods; Evoked Potentials,
	Visual, physiology; Feedback, Physiological; Models, Neurological;
	Nonlinear Dynamics; Visual Cortex, physiology; Voltage-Sensitive
	Dye Imaging, methods},
  language = {eng},
  medline-pst = {epublish},
  owner = {paupau},
  pmid = {20838578},
  timestamp = {2013.05.01},
  url = {http://dx.doi.org/10.1371/journal.pcbi.1000919}
}

@ARTICLE{Markram_2006,
  author = {Henry Markram},
  title = {The blue brain project.},
  journal = {Nat. Rev. Neurosci.},
  year = {2006},
  volume = {7},
  pages = {153--160},
  number = {2},
  month = {Feb},
  abstract = {IBM's Blue Gene supercomputer allows a quantum leap in the level of
	detail at which the brain can be modelled. I argue that the time
	is right to begin assimilating the wealth of data that has been accumulated
	over the past century and start building biologically accurate models
	of the brain from first principles to aid our understanding of brain
	function and dysfunction.},
  doi = {10.1038/nrn1848},
  institution = {Laboratory of Neural Microcircuitry, Brain Mind Institute, Ecole
	Polytechnique Fédérale de Lausanne, Lausanne 1015, Switzerland. henry.markram@epfl.ch},
  keywords = {Animals; Brain; Humans; Models, Neurological; Neural Networks (Computer);
	Quantum Theory},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {nrn1848},
  pmid = {16429124},
  timestamp = {2012.12.27},
  url = {http://dx.doi.org/10.1038/nrn1848}
}

@ARTICLE{Martens_2009,
  author = {Martens, E. A. and Barreto, E. and Strogatz, S. H. and Ott, E. and
	So, P. and Antonsen, T. M.},
  title = {Exact results for the Kuramoto model with a bimodal frequency distribution.},
  journal = {Phys Rev E Stat Nonlin Soft Matter Phys},
  year = {2009},
  volume = {79},
  pages = {026204},
  number = {2 Pt 2},
  month = {Feb},
  abstract = {We analyze a large system of globally coupled phase oscillators whose
	natural frequencies are bimodally distributed. The dynamics of this
	system has been the subject of long-standing interest. In 1984 Kuramoto
	proposed several conjectures about its behavior; ten years later,
	Crawford obtained the first analytical results by means of a local
	center manifold calculation. Nevertheless, many questions have remained
	open, especially about the possibility of global bifurcations. Here
	we derive the system's stability diagram for the special case where
	the bimodal distribution consists of two equally weighted Lorentzians.
	Using an ansatz recently discovered by Ott and Antonsen, we show
	that in this case the infinite-dimensional problem reduces exactly
	to a flow in four dimensions. Depending on the parameters and initial
	conditions, the long-term dynamics evolves to one of three states:
	incoherence, where all the oscillators are desynchronized; partial
	synchrony, where a macroscopic group of phase-locked oscillators
	coexists with a sea of desynchronized ones; and a standing wave state,
	where two counter-rotating groups of phase-locked oscillators emerge.
	Analytical results are presented for the bifurcation boundaries between
	these states. Similar results are also obtained for the case in which
	the bimodal distribution is given by the sum of two Gaussians.},
  institution = { Applied Mechanics, Cornell University, Ithaca, New York 14853, USA.},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paupau},
  pmid = {19391817},
  timestamp = {2013.10.27}
}

@BOOK{MATLAB,
  title = {version 8.1.0 (R2013a)},
  publisher = {The MathWorks Inc.},
  year = {2013},
  author = {MATLAB},
  address = {Natick, Massachusetts}
}

@ARTICLE{Mattioni_2012,
  author = {Michele Mattioni and Uri Cohen and Nicolas Le Novère},
  title = {Neuronvisio: A Graphical User Interface with 3D Capabilities for
	NEURON.},
  journal = {Front. Neuroinform.},
  year = {2012},
  volume = {6},
  pages = {20},
  abstract = {The NEURON simulation environment is a commonly used tool to perform
	electrical simulation of neurons and neuronal networks. The NEURON
	User Interface, based on the now discontinued InterViews library,
	provides some limited facilities to explore models and to plot their
	simulation results. Other limitations include the inability to generate
	a three-dimensional visualization, no standard mean to save the results
	of simulations, or to store the model geometry within the results.
	Neuronvisio (http://neuronvisio.org) aims to address these deficiencies
	through a set of well designed python APIs and provides an improved
	UI, allowing users to explore and interact with the model. Neuronvisio
	also facilitates access to previously published models, allowing
	users to browse, download, and locally run NEURON models stored in
	ModelDB. Neuronvisio uses the matplotlib library to plot simulation
	results and uses the HDF standard format to store simulation results.
	Neuronvisio can be viewed as an extension of NEURON, facilitating
	typical user workflows such as model browsing, selection, download,
	compilation, and simulation. The 3D viewer simplifies the exploration
	of complex model structure, while matplotlib permits the plotting
	of high-quality graphs. The newly introduced ability of saving numerical
	results allows users to perform additional analysis on their previous
	simulations.},
  doi = {10.3389/fninf.2012.00020},
  institution = {European Molecular Biology Laboratory-European Bioinformatics Institute,
	Wellcome Trust Genome Campus Cambridge, UK.},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {22685429},
  timestamp = {2013.02.01},
  url = {http://dx.doi.org/10.3389/fninf.2012.00020}
}

@ARTICLE{McCarthy_2008,
  author = {Michelle M McCarthy and Emery N Brown and Nancy Kopell},
  title = {Potential network mechanisms mediating electroencephalographic beta
	rhythm changes during propofol-induced paradoxical excitation.},
  journal = {J Neurosci},
  year = {2008},
  volume = {28},
  pages = {13488--13504},
  number = {50},
  month = {Dec},
  abstract = {Propofol, like most general anesthetic drugs, can induce both behavioral
	and electroencephalographic (EEG) manifestations of excitation, rather
	than sedation, at low doses. Neuronal excitation is unexpected in
	the presence of this GABA(A)-potentiating drug. We construct a series
	of network models to understand this paradox. Individual neurons
	have ion channel conductances with Hodgkin-Huxley-type formulations.
	Propofol increases the maximal conductance and time constant of decay
	of the synaptic GABA(A) current. Networks range in size from 2 to
	230 neurons. Population output is measured as a function of pyramidal
	cell activity, with the electroencephalogram approximated by the
	sum of population AMPA activity between pyramidal cells. These model
	networks suggest propofol-induced paradoxical excitation may result
	from a membrane level interaction between the GABA(A) current and
	an intrinsic membrane slow potassium current (M-current). This membrane
	level interaction has consequences at the level of multicellular
	networks enabling a switch from baseline interneuron synchrony to
	propofol-induced interneuron antisynchrony. Large network models
	reproduce the clinical EEG changes characteristic of propofol-induced
	paradoxical excitation. The EEG changes coincide with the emergence
	of antisynchronous interneuron clusters in the model networks. Our
	findings suggest interneuron antisynchrony as a potential network
	mechanism underlying the generation of propofol-induced paradoxical
	excitation. As correlates of behavioral phenomenology, these networks
	may refine our understanding of the specific behavioral states associated
	with general anesthesia.},
  doi = {10.1523/JNEUROSCI.3536-08.2008},
  institution = {Department of Mathematics and Statistics, Boston University, Boston,
	Massachusetts 02215, USA. mmccart@bu.edu},
  keywords = {Algorithms; Anesthetics, Intravenous, administration /&/ dosage; Dose-Response
	Relationship, Drug; Electroencephalography; Models, Neurological;
	Models, Theoretical; Neural Networks (Computer); Neurons, drug effects/physiology;
	Propofol, administration /&/ dosage},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {28/50/13488},
  pmid = {19074022},
  timestamp = {2013.08.29},
  url = {http://dx.doi.org/10.1523/JNEUROSCI.3536-08.2008}
}

@ARTICLE{McEvoy2011,
  author = {Linda K McEvoy and Dominic Holland and Donald J Hagler and Christine
	Fennema-Notestine and James B Brewer and Anders M Dale and Alzheimer's
	Disease Neuroimaging Initiative},
  title = {Mild cognitive impairment: baseline and longitudinal structural MR
	imaging measures improve predictive prognosis.},
  journal = {Radiology},
  year = {2011},
  volume = {259},
  pages = {834--843},
  number = {3},
  month = {Jun},
  abstract = {To assess whether single-time-point and longitudinal volumetric magnetic
	resonance (MR) imaging measures provide predictive prognostic information
	in patients with amnestic mild cognitive impairment (MCI).This study
	was conducted with institutional review board approval and in compliance
	with HIPAA regulations. Written informed consent was obtained from
	all participants or the participants' legal guardians. Cross-validated
	discriminant analyses of MR imaging measures were performed to differentiate
	164 Alzheimer disease (AD) cases from 203 healthy control cases.
	Separate analyses were performed by using data from MR images obtained
	at one time point or by combining single-time-point measures with
	1-year change measures. Resulting discriminant functions were applied
	to 317 MCI cases to derive individual patient risk scores. Risk of
	conversion to AD was estimated as a continuous function of risk score
	percentile. Kaplan-Meier survival curves were computed for risk score
	quartiles. Odds ratios (ORs) for the conversion to AD were computed
	between the highest and lowest quartile scores.Individualized risk
	estimates from baseline MR examinations indicated that the 1-year
	risk of conversion to AD ranged from 3\% to 40\% (average group risk,
	17\%; OR, 7.2 for highest vs lowest score quartiles). Including measures
	of 1-year change in global and regional volumes significantly improved
	risk estimates (P = 001), with the risk of conversion to AD in the
	subsequent year ranging from 3\% to 69\% (average group risk, 27\%;
	OR, 12.0 for highest vs lowest score quartiles).Relative to the risk
	of conversion to AD conferred by the clinical diagnosis of MCI alone,
	MR imaging measures yield substantially more informative patient-specific
	risk estimates. Such predictive prognostic information will be critical
	if disease-modifying therapies become available.http://radiology.rsna.org/lookup/suppl/doi:10.1148/radiol.11101975/-/DC1.},
  doi = {10.1148/radiol.11101975},
  institution = {Department of Radiology, University of California, San Diego, 9500
	Gilman Dr, La Jolla, CA 92093, USA. lkmcevoy@ucsd.edu},
  keywords = {Aged; Aged, 80 and over; Alzheimer Disease, complications/diagnosis/pathology;
	Case-Control Studies; Chi-Square Distribution; Cognition Disorders,
	diagnosis/etiology/pathology; Discriminant Analysis; Female; Humans;
	Magnetic Resonance Imaging, methods; Male; Middle Aged; Prognosis;
	Prospective Studies; ROC Curve; Sensitivity and Specificity; Survival
	Analysis},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {radiol.11101975},
  pmid = {21471273},
  timestamp = {2013.07.04},
  url = {http://dx.doi.org/10.1148/radiol.11101975}
}

@ARTICLE{McIntosh_2010,
  author = {McIntosh, AR and Kovacevic, N and Lippe, S and Garrett, D and Grady,
	C and Jirsa, VK},
  title = {The Development of a Noisy Brain},
  journal = {Arch. Ital. Biol.},
  year = {2010},
  volume = {148},
  pages = {323--337},
  number = {3},
  owner = {paula},
  timestamp = {2012.10.18}
}

@INCOLLECTION{Meyer_2002,
  author = {Mark Meyer and Mathieu Desbrun and Peter Schr{\"o}der and Alan H.
	Barr},
  title = {Discrete Differential-Geometry Operators for Triangulated 2-Manifolds},
  booktitle = {{V}isualization and {M}athematics III},
  publisher = {Springer-Verlag},
  year = {2003},
  editor = {Hans-Christian Hege and Konrad Polthier},
  pages = {35--57},
  address = {Heidelberg}
}

@ARTICLE{Miezin_2000,
  author = {F. M. Miezin and L. Maccotta and J. M. Ollinger and S. E. Petersen
	and R. L. Buckner},
  title = {Characterizing the hemodynamic response: effects of presentation
	rate, sampling procedure, and the possibility of ordering brain activity
	based on relative timing.},
  journal = {Neuroimage},
  year = {2000},
  volume = {11},
  pages = {735--759},
  number = {6 Pt 1},
  month = {Jun},
  abstract = {Rapid-presentation event-related functional MRI (ER-fMRI) allows neuroimaging
	methods based on hemodynamics to employ behavioral task paradigms
	typical of cognitive settings. However, the sluggishness of the hemodynamic
	response and its variance provide constraints on how ER-fMRI can
	be applied. In a series of two studies, estimates of the hemodynamic
	response in or near the primary visual and motor cortices were compared
	across various paradigms and sampling procedures to determine the
	limits of ER-fMRI procedures and, more generally, to describe the
	behavior of the hemodynamic response. The temporal profile of the
	hemodynamic response was estimated across overlapping events by solving
	a set of linear equations within the general linear model. No assumptions
	about the shape were made in solving the equations. Following estimation
	of the temporal profile, the amplitude and timing were modeled using
	a gamma function. Results indicated that (1) within a region, for
	a given subject, estimation of the hemodynamic response is extremely
	stable for both amplitude (r(2) = 0.98) and time to peak (r(2) =
	0.95), from one series of measurements to the next, and slightly
	less stable for estimation of time to onset (r(2) = 0.60). (2) As
	the trial presentation rate changed (from those spaced 20 s apart
	to temporally overlapping trials), the hemodynamic response amplitude
	showed a small, but significant, decrease. Trial onsets spaced (on
	average) 5 s apart showed a 17-25\% reduction in amplitude compared
	to those spaced 20 s apart. Power analysis indicated that the increased
	number of trials at fast rates outweighs this decrease in amplitude
	if statistically reliable response detection is the goal. (3) Knowledge
	of the amplitude and timing of the hemodynamic response in one region
	failed to predict those properties in another region, even for within-subject
	comparisons. (4) Across subjects, the amplitude of the response showed
	no significant correlation with timing of the response, for either
	time-to-onset or time-to-peak estimates. (5) The within-region stability
	of the response was sufficient to allow offsets in the timing of
	the response to be detected that were under a second, placing event-related
	fMRI methods in a position to answer questions about the change in
	relative timing between regions.},
  doi = {10.1006/nimg.2000.0568},
  institution = {Department of Psychology, Washington University, St. Louis, Missouri,
	63130, USA.},
  keywords = {Adolescent; Adult; Brain, physiology; Cerebrovascular Circulation,
	physiology; Hemodynamics, physiology; Humans; Magnetic Resonance
	Imaging, methods; Male; Models, Cardiovascular; Models, Neurological;
	Motor Cortex, blood supply; Specimen Handling, methods; Time Factors;
	Visual Cortex, blood supply},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S1053-8119(00)90568-8},
  pmid = {10860799},
  timestamp = {2013.08.19},
  url = {http://dx.doi.org/10.1006/nimg.2000.0568}
}

@ARTICLE{Millman_2010,
  author = {Daniel Millman and Stefan Mihalas and Alfredo Kirkwood and Ernst
	Niebur},
  title = {Self-organized criticality occurs in non-conservative neuronal networks
	during Up states.},
  journal = {Nat. Phys.},
  year = {2010},
  volume = {6},
  pages = {801--805},
  number = {10},
  month = {Oct},
  abstract = {During sleep, under anesthesia and in vitro, cortical neurons in sensory,
	motor, association and executive areas fluctuate between Up and Down
	states (UDS) characterized by distinct membrane potentials and spike
	rates [1, 2, 3, 4, 5]. Another phenomenon observed in preparations
	similar to those that exhibit UDS, such as anesthetized rats [6],
	brain slices and cultures devoid of sensory input [7], as well as
	awake monkey cortex [8] is self-organized criticality (SOC). This
	is characterized by activity "avalanches" whose size distributions
	obey a power law with critical exponent of about [Formula: see text]
	and branching parameter near unity. Recent work has demonstrated
	SOC in conservative neuronal network models [9, 10], however critical
	behavior breaks down when biologically realistic non-conservatism
	is introduced [9]. We here report robust SOC behavior in networks
	of non-conservative leaky integrate-and-fire neurons with short-term
	synaptic depression. We show analytically and numerically that these
	networks typically have 2 stable activity levels corresponding to
	Up and Down states, that the networks switch spontaneously between
	them, and that Up states are critical and Down states are subcritical.},
  doi = {10.1038/nphys1757},
  institution = {Zanvyl Krieger Mind/Brain Institute, Johns Hopkins University, Baltimore,
	Maryland 21218, USA.},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {21804861},
  timestamp = {2013.03.05},
  url = {http://dx.doi.org/10.1038/nphys1757}
}

@ARTICLE{Mirollo_2012,
  author = {Mirollo, Renato E.},
  title = {The asymptotic behavior of the order parameter for the infinite-N
	Kuramoto model.},
  journal = {Chaos},
  year = {2012},
  volume = {22},
  pages = {043118},
  number = {4},
  month = {Dec},
  abstract = {The Kuramoto model, first proposed in 1975, consists of a population
	of sinusoidally coupled oscillators with random natural frequencies.
	It has served as an idealized model for coupled oscillator systems
	in physics, chemistry, and biology. This paper addresses a long-standing
	problem about the infinite-N Kuramoto model, which is to describe
	the asymptotic behavior of the order parameter for this system. For
	coupling below a critical level, Kuramoto predicted that the order
	parameter would decay to 0. We use Fourier transform methods to prove
	that for general initial conditions, this decay is not exponential;
	in fact, exponential decay to 0 can only occur if the initial condition
	satisfies a fairly strong regularity condition that we describe.
	Our theorem is a partial converse to the recent results of Ott and
	Antonsen, who proved that for a special class of initial conditions,
	the order parameter does converge exponentially to its limiting value.
	Consequently, our result shows that the Ott-Antonsen ansatz does
	not completely capture all the possible asymptotic behavior in the
	full Kuramoto system.},
  doi = {10.1063/1.4766596},
  institution = {Boston College, Chestnut Hill, Massachusetts 02467-3806, USA. mirollo@bc.edu},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paupau},
  pmid = {23278053},
  timestamp = {2013.10.27},
  url = {http://dx.doi.org/10.1063/1.4766596}
}

@ARTICLE{Mitchell1987,
  author = {Mitchell, Joseph SB and Mount, David M and Papadimitriou, Christos
	H},
  title = {The discrete geodesic problem},
  journal = {SIAM Journal on Computing},
  year = {1987},
  volume = {16},
  pages = {647--668},
  number = {4},
  publisher = {SIAM}
}

@ARTICLE{Molaee_Ardekani_2007,
  author = {B. Molaee-Ardekani and L. Senhadji and M. B. Shamsollahi and B. Vosoughi-Vahdat
	and E. Wodey},
  title = {Brain activity modeling in general anesthesia: enhancing local mean-field
	models using a slow adaptive firing rate.},
  journal = {Phys. Rev. E: Stat., Nonlinear, Soft Matter Phys.},
  year = {2007},
  volume = {76},
  pages = {041911},
  number = {4 Pt 1},
  month = {Oct},
  abstract = {In this paper, an enhanced local mean-field model that is suitable
	for simulating the electroencephalogram (EEG) in different depths
	of anesthesia is presented. The main building elements of the model
	(e.g., excitatory and inhibitory populations) are taken from Steyn-Ross
	[M. L. Steyn-Ross, Phys. Rev. E 64, 011917 (2001), D. A. Steyn-Ross,
	Phys. Rev. E 64, 011918 (2001)] and Bojak and Liley [I. Bojak and
	D. T. Liley, Phys. Rev. E 71, 041902 (2005)] mean-field models and
	a new slow ionic mechanism is included in the main model. Generally,
	in mean-field models, some sigmoid-shape functions determine firing
	rates of neural populations according to their mean membrane potentials.
	In the enhanced model, the sigmoid function corresponding to excitatory
	population is redefined to be also a function of the slow ionic mechanism.
	This modification adapts the firing rate of neural populations to
	slow ionic activities of the brain. When an anesthetic drug is administered,
	the slow mechanism may induce neural cells to alternate between two
	levels of activity referred to as up and down states. Basically,
	the frequency of up-down switching is in the delta band (0-4 Hz)
	and this is the main reason behind high amplitude, low frequency
	fluctuations of EEG signals in anesthesia. Our analyses show that
	the enhanced model may have different working states driven by anesthetic
	drug concentration. The model is settled in the up state in the waking
	period, it may switch to up and down states in moderate anesthesia
	while in deep anesthesia it remains in the down state.},
  institution = {INSERM, U 642, Rennes F-35000, France. molaee-ardekani@ieee.org},
  keywords = {Algorithms; Anesthesia, General; Biophysics, methods; Brain, physiology;
	Dose-Response Relationship, Drug; Electroencephalography, methods;
	Equipment Design; Humans; Ions; Isoflurane, analogs /&/ derivatives/pharmacology;
	Membrane Potentials; Models, Statistical; Models, Theoretical; Nerve
	Net; Neurons, metabolism},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {17995030},
  timestamp = {2013.02.18}
}

@ARTICLE{Mori_2002,
  author = {Mori, S. and van Zijl, P.},
  title = {{Fiber tracking: principles and strategies--a technical review}},
  journal = {NMR Biomed.},
  year = {2002},
  volume = {15},
  pages = {468--480},
  number = {7-8},
  issn = {1099-1492},
  publisher = {Wiley Online Library}
}

@ARTICLE{Morris_1981,
  author = {Morris, C and Lecar, H},
  title = {Voltage oscillations in the Barnacle giant muscle fibre},
  journal = {Biophys. J.},
  year = {1981},
  volume = {35},
  pages = {193-213},
  number = {1},
  month = {July},
  keywords = {model},
  owner = {paula},
  timestamp = {2012.10.18}
}

@ARTICLE{Mosher_1999,
  author = {Mosher, JC and Leahy, R and Lewis, P},
  title = {EEG and MEG: forward solutions for inverse methods},
  journal = {IEEE Trans. Biomed. Eng.},
  year = {1999},
  volume = {46},
  pages = {245– 259},
  owner = {paula},
  timestamp = {2012.10.26}
}

@ARTICLE{Nagumo_1962,
  author = {J Nagumo},
  title = {An Active Pulse Transmission Line Simulating Nerve Axon},
  journal = {Proc. IRE.},
  year = {1962},
  volume = {50},
  pages = {2061- 2070},
  number = {10},
  month = {October},
  keywords = {model},
  owner = {paula},
  timestamp = {2012.10.18}
}

@ARTICLE{Nakagawa_2013,
  author = {Tristan T Nakagawa and Viktor K Jirsa and Andreas Spiegler and Anthony
	R McIntosh and Gustavo Deco},
  title = {Bottom up modeling of the connectome: Linking structure and function
	in the resting brain and their changes in aging.},
  journal = {Neuroimage},
  year = {2013},
  volume = {--},
  pages = {--},
  month = {Apr},
  abstract = {With the increasing availability of advanced imaging technologies,
	we are entering a new era of neuroscience. Detailed descriptions
	of the complex brain network enable us to map out a structural connectome,
	characterize it with graph theoretical methods, and compare it to
	the functional networks with increasing detail. To link these two
	aspects and understand how dynamics and structure interact to form
	functional brain networks in task and in the resting state, we use
	theoretical models. The advantage of using theoretical models is
	that by recreating functional connectivity and time series explicitly
	from structure and pre-defined dynamics, we can extract critical
	mechanisms by linking structure and function in ways not directly
	accessible in the real brain. Recently, resting-state models with
	varying local dynamics have reproduced empirical functional connectivity
	patterns, and given support to the view that the brain works at a
	critical point at the edge of a bifurcation of the system. Here,
	we present an overview of a modeling approach of the resting brain
	network and give an application of a neural mass model in the study
	of complexity changes in aging.},
  doi = {10.1016/j.neuroimage.2013.04.055},
  institution = {Center for Brain and Cognition, Computational Neuroscience Group,
	Department of Information and Communication Technologies, Universitat
	Pompeu Fabra, Barcelona 08018, Spain. Electronic address: tristan.nakagawa@upf.edu.},
  language = {eng},
  medline-pst = {aheadofprint},
  owner = {paula},
  pii = {S1053-8119(13)00402-3},
  pmid = {23629050},
  timestamp = {2013.06.07},
  url = {http://dx.doi.org/10.1016/j.neuroimage.2013.04.055}
}

@ARTICLE{Neylon_2012,
  author = {Cameron Neylon and Jan Aerts and C. Titus Brown and Simon J Coles
	and Les Hatton and Daniel Lemire and K. Jarrod Millman and Peter
	Murray-Rust and Fernando Perez and Neil Saunders and Nigam Shah and
	Arfon Smith and Gaël Varoquaux and Egon Willighagen},
  title = {Changing computational research. The challenges ahead.},
  journal = {Source. Code. Biol. Med.},
  year = {2012},
  volume = {7},
  pages = {2},
  number = {1},
  doi = {10.1186/1751-0473-7-2},
  institution = {Science and Technology Facilities Council, Didcot, Harwell Oxford,
	UK. cameron.neylon@stfc.ac.uk.},
  language = {eng},
  medline-pst = {epublish},
  owner = {paula},
  pii = {1751-0473-7-2},
  pmid = {22640749},
  timestamp = {2013.02.21},
  url = {http://dx.doi.org/10.1186/1751-0473-7-2}
}

@ARTICLE{Nolte2003,
  author = {Nolte, Guido},
  title = {The magnetic lead field theorem in the quasi-static approximation
	and its use for magnetoencephalography forward calculation in realistic
	volume conductors.},
  journal = {Phys Med Biol},
  year = {2003},
  volume = {48},
  pages = {3637--3652},
  number = {22},
  month = {Nov},
  abstract = {The equation for the magnetic lead field for a given magnetoencephalography
	(MEG) channel is well known for arbitrary frequencies omega but is
	not directly applicable to MEG in the quasi-static approximation.
	In this paper we derive an equation for omega = 0 starting from the
	very definition of the lead field instead of using Helmholtz's reciprocity
	theorems. The results are (a) the transpose of the conductivity times
	the lead field is divergence-free, and (b) the lead field differs
	from the one in any other volume conductor by a gradient of a scalar
	function. Consequently, for a piecewise homogeneous and isotropic
	volume conductor, the lead field is always tangential at the outermost
	surface. Based on this theoretical result, we formulated a simple
	and fast method for the MEG forward calculation for one shell of
	arbitrary shape: we correct the corresponding lead field for a spherical
	volume conductor by a superposition of basis functions, gradients
	of harmonic functions constructed here from spherical harmonics,
	with coefficients fitted to the boundary conditions. The algorithm
	was tested for a prolate spheroid of realistic shape for which the
	analytical solution is known. For high order in the expansion, we
	found the solutions to be essentially exact and for reasonable accuracies
	much fewer multiplications are needed than in typical implementations
	of the boundary element methods. The generalization to more shells
	is straightforward.},
  institution = {Human Motor Control Section, NINDS, NIH, Bethesda, MD, USA. nolteg@ninds.nih.gov},
  keywords = {Algorithms; Electromagnetic Fields; Magnetoencephalography; Mathematics},
  language = {eng},
  medline-pst = {ppublish},
  pmid = {14680264},
  timestamp = {2013.09.24}
}

@ARTICLE{Nolte_2004a,
  author = {Guido Nolte and Ou Bai and Lewis Wheaton and Zoltan Mari and Sherry
	Vorbach and Mark Hallett},
  title = {Identifying true brain interaction from EEG data using the imaginary
	part of coherency.},
  journal = {Clin. Neurophysiol.},
  year = {2004},
  volume = {115},
  pages = {2292--2307},
  number = {10},
  month = {Oct},
  abstract = {The main obstacle in interpreting EEG/MEG data in terms of brain connectivity
	is the fact that because of volume conduction, the activity of a
	single brain source can be observed in many channels. Here, we present
	an approach which is insensitive to false connectivity arising from
	volume conduction.We show that the (complex) coherency of non-interacting
	sources is necessarily real and, hence, the imaginary part of coherency
	provides an excellent candidate to study brain interactions. Although
	the usual magnitude and phase of coherency contain the same information
	as the real and imaginary parts, we argue that the Cartesian representation
	is far superior for studying brain interactions. The method is demonstrated
	for EEG measurements of voluntary finger movement.We found: (a) from
	5 s before to movement onset a relatively weak interaction around
	20 Hz between left and right motor areas where the contralateral
	side leads the ipsilateral side; and (b) approximately 2-4 s after
	movement, a stronger interaction also at 20 Hz in the opposite direction.It
	is possible to reliably detect brain interaction during movement
	from EEG data.The method allows unambiguous detection of brain interaction
	from rhythmic EEG/MEG data.},
  doi = {10.1016/j.clinph.2004.04.029},
  institution = {Human Motor Control Section, NINDS, NIH, 10 Center Drive MSC 1428,
	Bldg 10, Room 5N226, Bethesda, MD 20892-1428, USA. nolteg@ninds.nih.gov},
  keywords = {Algorithms; Alpha Rhythm; Beta Rhythm; Brain, physiology; Data Interpretation,
	Statistical; Electroencephalography, statistics /&/ numerical data;
	Functional Laterality, physiology; Magnetoencephalography, statistics
	/&/ numerical data; Models, Neurological},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S1388245704001993},
  pmid = {15351371},
  timestamp = {2013.02.12},
  url = {http://dx.doi.org/10.1016/j.clinph.2004.04.029}
}

@ARTICLE{Nunez_1974,
  author = {PL Nunez},
  title = {The brain wave equation: A model for the EEG},
  journal = {Math. Biosci.},
  year = {1974},
  volume = {21},
  pages = {279-297},
  number = {3-4},
  month = {December},
  abstract = {Both spontaneous and evoked potentials measured on the surface of
	the head are believed due to postsynaptic potentials in vertically
	oriented neurons in the cortex. Potential differences between surface
	locations at any given time are due to the instantaneous difference
	in synaptic activity between the corresponding vertical regions.
	Because of the high correlation of activity between regions separated
	by distances large compared to the radius of influence of single
	neurons, communication between these locations must be by means of
	action potentials. In order to quantify the dynamics of interaction
	of 1010 cortical neurons, use is made of the concept of a neural
	mass. The neural mass consists of sufficiently large number of neurons
	so as to exhibit certain average properties which are independent
	of its exact inner circuitry. An integral wave equation is derived
	to describe the spatial-temporal variation of cortical potential.
	Solutions are obtained indicating that electrical oscillations, which
	are independent of the location and time history of subcortical input,
	can persist in the cortex. The nature of these oscillations depends
	on the relative abundance of excitatory and inhibitory connections
	between neural masses and on the physiological state of the brain.
	The latter is partially determined by velocity distribution functions
	for action potential propagation. A dispersion relation for brain
	waves is shown to exist for certain ranges of the connection parameters.
	In some limiting cases, weakly damped waves occur with ω=ck, where
	c refers to a characteristic velocity for the distribution functions.
	Preliminary experiments indicate qualitative agreement with this
	result.},
  keywords = {EEG},
  owner = {paula},
  timestamp = {2012.10.18}
}

@ARTICLE{Nunez_1981a,
  author = {P. L. Nunez},
  title = {A study of origins of the time dependencies of scalp EEG: ii--experimental
	support of theory.},
  journal = {IEEE Trans. Biomed. Eng.},
  year = {1981},
  volume = {28},
  pages = {281--288},
  number = {3},
  month = {Mar},
  doi = {10.1109/TBME.1981.324701},
  keywords = {Alpha Rhythm; Cortical Synchronization; Electroencephalography; Humans;
	Mathematics; Models, Theoretical; Scalp, innervation; Time Factors},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {7228074},
  timestamp = {2013.02.18},
  url = {http://dx.doi.org/10.1109/TBME.1981.324701}
}

@ARTICLE{OConnor_2004,
  author = {S. C. O'Connor and P. A. Robinson},
  title = {Spatially uniform and nonuniform analyses of electroencephalographic
	dynamics,with application to the topography of the alpha rhythm.},
  journal = {Phys Rev E Stat Nonlin Soft Matter Phys},
  year = {2004},
  volume = {70},
  pages = {011911},
  number = {1 Pt 1},
  month = {Jul},
  abstract = {Corticothalamic dynamics are investigated using a model in which spatial
	nonuniformities are incorporated via the coupling of spatial eigenmodes.
	Comparison of spectra generated using the nonuniform analysis with
	those generated using a uniform one demonstrates that, for most frequencies,
	local activity is only weakly dependent on activity elsewhere in
	the cortex; however, dispersion of low-wave-number activity ensures
	that distant dynamics influence local dynamics at low frequencies
	(below approximately 2 Hz ), and at the alpha frequency (approximately
	10 Hz ), where propagating signals are inherently weakly damped,
	and wavelengths are large. When certain model parameters have similar
	spatial profiles, as is expected from physiology, the low-frequency
	discrepancies tend to cancel, and the uniform analysis with local
	parameter values is an adequate approximation to the full nonuniform
	one across the whole spectrum, at least for large-scale nonuniformities.
	After comparing the uniform and nonuniform analyses, we consider
	one possible application of the nonuniform analysis: studying the
	phenomenon of occipital alpha dominance, whereby the alpha frequency
	and power are greater at the back of the head (occipitally) than
	at the front. In order to infer realistic nonuniformities in the
	model parameters, the uniform version of the model is first fitted
	to data recorded from 98 normal subjects in a waking, eyes-closed
	state. This yields a set of parameters at each of five electrode
	sites along the midline. The inferred parameter nonuniformities are
	consistent with anatomical and physiological constraints. Introducing
	these spatial profiles into the full nonuniform model then quantitatively
	reproduces observed site-dependent variations in the alpha power
	and frequency. The results confirm that the frequency shift is mainly
	due to a decrease in the corticothalamic propagation delay, but indicate
	that the delay nonuniformity cannot account for the observed occipital
	increase in alpha power; the occipital alpha dominance is due to
	decreased cortical gains and increased thalamic gains in occipital
	regions compared to frontal ones.},
  institution = {School of Physics, University of Sydney, Sydney, New South Wales
	2006, Australia.},
  keywords = {Alpha Rhythm, methods; Brain Mapping, methods; Brain, physiology;
	Computer Simulation; Diagnosis, Computer-Assisted, methods; Electroencephalography,
	methods; Humans; Models, Neurological; Nonlinear Dynamics; Occipital
	Lobe, physiology; Synaptic Transmission, physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {15324092},
  timestamp = {2013.08.19}
}

@ARTICLE{OConnor_2002,
  author = {S. C. O'Connor and P. A. Robinson and A. K I Chiang},
  title = {Wave-number spectrum of electroencephalographic signals.},
  journal = {Phys Rev E Stat Nonlin Soft Matter Phys},
  year = {2002},
  volume = {66},
  pages = {061905},
  number = {6 Pt 1},
  month = {Dec},
  abstract = {A recently developed, physiologically based continuum model of corticothalamic
	electrodynamics is used to derive the theoretical form of the electroencephalographic
	wave-number spectrum and its projection onto a one-dimensional recording
	array. The projected spectrum is found to consist of a plateau followed
	by regions of power-law decrease with various exponents, which are
	dependent on both model parameters and temporal frequency. The theoretical
	spectrum is compared with experimental results obtained in other
	studies, showing good agreement. The model provides a framework for
	understanding the nature of the spatial power spectrum by linking
	the underlying physiology with the large-scale dynamics of the brain.},
  institution = {Theoretical Physics Group, School of Physics, University of Sydney,
	New South Wales 2006, Australia.},
  keywords = {Algorithms; Animals; Biophysical Phenomena; Biophysics; Brain, pathology/physiology;
	Electroencephalography; Humans; Image Enhancement; Models, Biological;
	Models, Statistical; Sleep; Time Factors},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {12513316},
  timestamp = {2013.08.19}
}

@ARTICLE{Obata_2004,
  author = {Takayuki Obata and Thomas T Liu and Karla L Miller and Wen Ming Luh
	and Eric C Wong and Lawrence R Frank and Richard B Buxton},
  title = {Discrepancies between BOLD and flow dynamics in primary and supplementary
	motor areas: application of the balloon model to the interpretation
	of BOLD transients.},
  journal = {Neuroimage},
  year = {2004},
  volume = {21},
  pages = {144--153},
  number = {1},
  month = {Jan},
  abstract = {The blood-oxygen-level-dependent (BOLD) signal measured in the brain
	with functional magnetic resonance imaging (fMRI) during an activation
	experiment often exhibits pronounced transients at the beginning
	and end of the stimulus. Such transients could be a reflection of
	transients in the underlying neural activity, or they could result
	from transients in cerebral blood flow (CBF), cerebral metabolic
	rate of oxygen (CMRO2), or cerebral blood volume (CBV). These transients
	were investigated using an arterial spin labeling (ASL) method that
	allows simultaneous measurements of BOLD and CBF responses. Responses
	to a finger-tapping task (40-s stimulus, 80-s rest) were measured
	in primary motor area (M1) and supplementary motor area (SMA) in
	five healthy volunteers. In SMA, the average BOLD response was pronounced
	near the beginning and end of the stimulus, while in M1, the BOLD
	response was nearly flat. However, CBF responses in the two regions
	were rather similar, and did not exhibit the same transient features
	as the BOLD response in SMA. Because this suggests a hemodynamic
	rather than a neural origin for the transients of the BOLD response
	in SMA, we used a generalization of the balloon model to test the
	degree of hemodynamic transients required to produce the measured
	curves. Both data sets could be approximated with modest differences
	in the shapes of the CMRO2 and CBV responses. This study illustrates
	the utility and the limitations of using theoretical models combined
	with ASL techniques to understand the dynamics of the BOLD response.},
  institution = {Department of Radiology, University of California at San Diego, 92039-0677,
	La Jolla, CA, USA. t_obata@nirs.go.jp},
  keywords = {Adult; Blood Volume, physiology; Brain Mapping; Energy Metabolism,
	physiology; Hemoglobins, metabolism; Humans; Image Enhancement, methods;
	Image Processing, Computer-Assisted; Magnetic Resonance Imaging,
	methods; Models, Neurological; Models, Theoretical; Motor Activity,
	physiology; Motor Cortex, blood supply/physiology; Oxygen Consumption,
	physiology; Oxygen, blood; Reference Values; Regional Blood Flow,
	physiology; Reproducibility of Results; Spin Labels},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S1053811903005494},
  pmid = {14741651},
  timestamp = {2013.08.19}
}

@BOOK{book_Ogata_2010,
  title = {Modern Control Engineering},
  publisher = {Prentice Hall - Pearson},
  year = {2010},
  editor = {Katsuhiko Ogata},
  author = {Katsuhiko Ogata},
  owner = {paula},
  timestamp = {2013.08.20}
}

@ARTICLE{Ogawa_1998,
  author = {S. Ogawa and R. S. Menon and S. G. Kim and K. Ugurbil},
  title = {On the characteristics of functional magnetic resonance imaging of
	the brain.},
  journal = {Annu. Rev. Biophys. Biomol. Struct.},
  year = {1998},
  volume = {27},
  pages = {447--474},
  abstract = {In this review we discuss various recent topics that characterize
	functional magnetic resonance imaging (fMRI). These topics include
	a brief description of MRI image acquisition, how to cope with noise
	or signal fluctuation, the basis of fMRI signal changes, and the
	relation of MRI signal to neuronal events. Several observations of
	fMRI that show good correlation to the neurofunction are referred
	to. Temporal characteristics of fMRI signals and examples of how
	the feature of real time measurement is utilized are then described.
	The question of spatial resolution of fMRI, which must be dictated
	by the vascular structure serving the functional system, is discussed
	based on various fMRI observations. Finally, the advantage of fMRI
	mapping is shown in a few examples. Reviewing the vast number of
	recent fMRI application that have now been reported is beyond the
	scope of this article.},
  doi = {10.1146/annurev.biophys.27.1.447},
  institution = {Bell Laboratories, Lucent Technologies, Murray Hill, New Jersey 07974,
	USA. so@physics.bell-labs.com},
  keywords = {Animals; Biophysics, methods; Brain Mapping, methods; Brain, anatomy
	/&/ histology/metabolism/physiology; Cerebrovascular Circulation;
	Humans; Magnetic Resonance Imaging, methods; Neurons, physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {9646874},
  timestamp = {2013.04.17},
  url = {http://dx.doi.org/10.1146/annurev.biophys.27.1.447}
}

@ARTICLE{Ogawa_1993,
  author = {S. Ogawa and R. S. Menon and D. W. Tank and S. G. Kim and H. Merkle
	and J. M. Ellermann and K. Ugurbil},
  title = {Functional brain mapping by blood oxygenation level-dependent contrast
	magnetic resonance imaging. A comparison of signal characteristics
	with a biophysical model.},
  journal = {Biophys. J.},
  year = {1993},
  volume = {64},
  pages = {803--812},
  number = {3},
  month = {Mar},
  abstract = {It recently has been demonstrated that magnetic resonance imaging
	can be used to map changes in brain hemodynamics produced by human
	mental operations. One method under development relies on blood oxygenation
	level-dependent (BOLD) contrast: a change in the signal strength
	of brain water protons produced by the paramagnetic effects of venous
	blood deoxyhemoglobin. Here we discuss the basic quantitative features
	of the observed BOLD-based signal changes, including the signal amplitude
	and its magnetic field dependence and dynamic effects such as a pronounced
	oscillatory pattern that is induced in the signal from primary visual
	cortex during photic stimulation experiments. The observed features
	are compared with the results of Monte Carlo simulations of water
	proton intravoxel phase dispersion produced by local field gradients
	generated by paramagnetic deoxyhemoglobin in nearby venous blood
	vessels. The simulations suggest that the effect of water molecule
	diffusion is strong for the case of blood capillaries, but, for larger
	venous blood vessels, water diffusion is not an important determinant
	of deoxyhemoglobin-induced signal dephasing. We provide an expression
	for the apparent in-plane relaxation rate constant (R2*) in terms
	of the main magnetic field strength, the degree of the oxygenation
	of the venous blood, the venous blood volume fraction in the tissue,
	and the size of the blood vessel.},
  doi = {10.1016/S0006-3495(93)81441-3},
  institution = {T Bell Laboratories, Murray Hill, New Jersey 07974.},
  keywords = {Biophysical Phenomena; Biophysics; Body Water, metabolism; Brain,
	physiology; Cerebrovascular Circulation; Humans; Magnetic Resonance
	Imaging, methods/statistics /&/ numerical data; Models, Neurological;
	Monte Carlo Method; Oxygen, blood; Protons; Visual Cortex, blood
	supply/physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S0006-3495(93)81441-3},
  pmid = {8386018},
  timestamp = {2013.04.17},
  url = {http://dx.doi.org/10.1016/S0006-3495(93)81441-3}
}

@ARTICLE{Oliphant_2007,
  author = {Oliphant, Travis E.},
  title = {Python for Scientific Computing},
  journal = {Computing in science \& engineering},
  year = {2007},
  volume = {9},
  pages = {10--20},
  number = {3},
  month = may,
  acmid = {1251830},
  address = {Piscataway, NJ, USA},
  doi = {10.1109/MCSE.2007.58},
  issn = {1521-9615},
  issue_date = {May 2007},
  keywords = {Python, Python, computer languages, scientific programming, scientific
	computing, computer languages, scientific computing, scientific programming},
  numpages = {11},
  publisher = {IEEE Educational Activities Department},
  url = {http://dx.doi.org/10.1109/MCSE.2007.58}
}

@MANUAL{Oliphant_2006,
  title = {Guide to NumPy},
  author = {Oliphant, T. E.},
  organization = {Enthought, Inc.},
  year = {2006},
  keywords = {numpy, python},
  owner = {paula},
  timestamp = {2012.12.26},
  url = {http://www.tramys.us}
}

@ARTICLE{Oostenveld_2011,
  author = {Robert Oostenveld and Pascal Fries and Eric Maris and Jan-Mathijs
	Schoffelen},
  title = {FieldTrip: Open source software for advanced analysis of MEG, EEG,
	and invasive electrophysiological data.},
  journal = {Comput Intell Neurosci},
  year = {2011},
  volume = {2011},
  pages = {156869},
  abstract = {This paper describes FieldTrip, an open source software package that
	we developed for the analysis of MEG, EEG, and other electrophysiological
	data. The software is implemented as a MATLAB toolbox and includes
	a complete set of consistent and user-friendly high-level functions
	that allow experimental neuroscientists to analyze experimental data.
	It includes algorithms for simple and advanced analysis, such as
	time-frequency analysis using multitapers, source reconstruction
	using dipoles, distributed sources and beamformers, connectivity
	analysis, and nonparametric statistical permutation tests at the
	channel and source level. The implementation as toolbox allows the
	user to perform elaborate and structured analyses of large data sets
	using the MATLAB command line and batch scripting. Furthermore, users
	and developers can easily extend the functionality and implement
	new algorithms. The modular design facilitates the reuse in other
	software packages.},
  doi = {10.1155/2011/156869},
  institution = {Donders Institute for Brain, Cognition and Behaviour, Centre for
	Cognitive Neuroimaging, Radboud University Nijmegen, The Netherlands.
	r.oostenveld@donders.ru.nl},
  keywords = {Electroencephalography; Electrophysiological Phenomena, physiology;
	Humans; Magnetoencephalography; Numerical Analysis, Computer-Assisted;
	Software, trends; User-Computer Interface},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {21253357},
  timestamp = {2013.08.28},
  url = {http://dx.doi.org/10.1155/2011/156869}
}

@ARTICLE{PerezGranger_2007,
  author = {P\'erez, Fernando and Granger, Brian E.},
  title = {{IP}ython: a {S}ystem for {I}nteractive {S}cientific {C}omputing},
  journal = {{C}omput. {S}ci. {E}ng.},
  year = {2007},
  volume = {9},
  pages = {21-29},
  number = {3},
  month = may,
  url = {http://ipython.org}
}

@ARTICLE{Pajevic_2009,
  author = {Sinisa Pajevic and Dietmar Plenz},
  title = {Efficient network reconstruction from dynamical cascades identifies
	small-world topology of neuronal avalanches.},
  journal = {PLoS Comput. Biol.},
  year = {2009},
  volume = {5},
  pages = {e1000271},
  number = {1},
  month = {Jan},
  abstract = {Cascading activity is commonly found in complex systems with directed
	interactions such as metabolic networks, neuronal networks, or disease
	spreading in social networks. Substantial insight into a system's
	organization can be obtained by reconstructing the underlying functional
	network architecture from the observed activity cascades. Here we
	focus on Bayesian approaches and reduce their computational demands
	by introducing the Iterative Bayesian (IB) and Posterior Weighted
	Averaging (PWA) methods. We introduce a special case of PWA, cast
	in nonparametric form, which we call the normalized count (NC) algorithm.
	NC efficiently reconstructs random and small-world functional network
	topologies and architectures from subcritical, critical, and supercritical
	cascading dynamics and yields significant improvements over commonly
	used correlation methods. With experimental data, NC identified a
	functional and structural small-world topology and its corresponding
	traffic in cortical networks with neuronal avalanche dynamics.},
  doi = {10.1371/journal.pcbi.1000271},
  institution = {Division of Computational Bioscience, Mathematical and Statistical
	Computing Laboratory, Center for Information Technology, National
	Institutes of Health, Bethesda, Maryland, United States of America.},
  keywords = {Algorithms; Animals; Bayes Theorem; Cerebral Cortex, physiology; Computational
	Biology, methods; Models, Neurological; Models, Statistical; Nerve
	Net, physiology; Neurons, physiology; Rats; Statistics, Nonparametric},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {19180180},
  timestamp = {2013.03.05},
  url = {http://dx.doi.org/10.1371/journal.pcbi.1000271}
}

@ARTICLE{Pajula_2012,
  author = {Juha Pajula and Jukka-Pekka Kauppi and Jussi Tohka},
  title = {Inter-subject correlation in fMRI: method validation against stimulus-model
	based analysis.},
  journal = {PLoS One},
  year = {2012},
  volume = {7},
  pages = {e41196},
  number = {8},
  abstract = {Within functional magnetic resonance imaging (fMRI), the use of the
	traditional general linear model (GLM) based analysis methods is
	often restricted to strictly controlled research setups requiring
	a parametric activation model. Instead, Inter-Subject Correlation
	(ISC) method is based on voxel-wise correlation between the time
	series of the subjects, which makes it completely non-parametric
	and thus suitable for naturalistic stimulus paradigms such as movie
	watching. In this study, we compared an ISC based analysis results
	with those of a GLM based in five distinct controlled research setups.
	We used International Consortium for Brain Mapping functional reference
	battery (FRB) fMRI data available from the Laboratory of Neuro Imaging
	image data archive. The selected data included measurements from
	37 right-handed subjects, who all had performed the same five tasks
	from FRB. The GLM was expected to locate activations accurately in
	FRB data and thus provide good grounds for investigating relationship
	between ISC and stimulus induced fMRI activation. The statistical
	maps of ISC and GLM were compared with two measures. The first measure
	was the Pearson's correlation between the non-thresholded ISC test-statistics
	and absolute values of the GLM Z-statistics. The average correlation
	value over five tasks was 0.74. The second was the Dice index between
	the activation regions of the methods. The average Dice value over
	the tasks and three threshold levels was 0.73. The results of this
	study indicated how the data driven ISC analysis found the same foci
	as the model-based GLM analysis. The agreement of the results is
	highly interesting, because ISC is applicable in situations where
	GLM is not suitable, for example, when analyzing data from a naturalistic
	stimuli experiment.},
  doi = {10.1371/journal.pone.0041196},
  institution = {Department of Signal Processing, Tampere University of Technology,
	Tampere, Finland. juha.pajula@tut.fi},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {PONE-D-12-04734},
  pmid = {22924089},
  timestamp = {2013.01.18},
  url = {http://dx.doi.org/10.1371/journal.pone.0041196}
}

@ARTICLE{Palm_2010,
  author = {Christoph Palm and Markus Axer and David Gräßel and Jürgen Dammers
	and Johannes Lindemeyer and Karl Zilles and Uwe Pietrzyk and Katrin
	Amunts},
  title = {Towards ultra-high resolution fibre tract mapping of the human brain
	- registration of polarised light images and reorientation of fibre
	vectors.},
  journal = {Front Hum Neurosci},
  year = {2010},
  volume = {4},
  pages = {9},
  abstract = {Polarised light imaging (PLI) utilises the birefringence of the myelin
	sheaths in order to visualise the orientation of nerve fibres in
	microtome sections of adult human post-mortem brains at ultra-high
	spatial resolution. The preparation of post-mortem brains for PLI
	involves fixation, freezing and cutting into 100-mum-thick sections.
	Hence, geometrical distortions of histological sections are inevitable
	and have to be removed for 3D reconstruction and subsequent fibre
	tracking. We here present a processing pipeline for 3D reconstruction
	of these sections using PLI derived multimodal images of post-mortem
	brains. Blockface images of the brains were obtained during cutting;
	they serve as reference data for alignment and elimination of distortion
	artefacts. In addition to the spatial image transformation, fibre
	orientation vectors were reoriented using the transformation fields,
	which consider both affine and subsequent non-linear registration.
	The application of this registration and reorientation approach results
	in a smooth fibre vector field, which reflects brain morphology.
	PLI combined with 3D reconstruction and fibre tracking is a powerful
	tool for human brain mapping. It can also serve as an independent
	method for evaluating in vivo fibre tractography.},
  doi = {10.3389/neuro.09.009.2010},
  institution = {Institute of Neuroscience and Medicine (INM-1, INM-2, INM-4), Research
	Centre Jülich and Jülich-Aachen Research Alliance (JARA-Brain) Aachen,
	Germany.},
  language = {eng},
  medline-pst = {epublish},
  owner = {paula},
  pmid = {20461231},
  timestamp = {2013.07.04},
  url = {http://dx.doi.org/10.3389/neuro.09.009.2010}
}

@ARTICLE{Patel_2010,
  author = {Patel, Vishal and Dinov, Ivo D. and {Van Horn}, John D. and Thompson,
	Paul M. and Toga, Arthur W.},
  title = {LONI MiND: metadata in NIfTI for DWI.},
  journal = {Neuroimage},
  year = {2010},
  volume = {51},
  pages = {665--676},
  number = {2},
  month = {Jun},
  abstract = {A wide range of computational methods have been developed for reconstructing
	white matter geometry from a set of diffusion-weighted images (DWIs),
	and many clinical studies rely on publicly-available implementations
	of these methods for analyzing DWI datasets. Unfortunately, the poor
	interoperability between DWI analysis tools often effectively restricts
	users to the algorithms provided by a single software suite, which
	may be suboptimal relative to those in other packages, or outdated
	given recent developments in the field. A major barrier to data portability
	and the interoperability between DWI analysis tools is the lack of
	a standard format for representing and communicating essential DWI-related
	metadata at various stages of post-processing. In this report, we
	address this issue by developing a framework for storing metadata
	in NIfTI for DWI (MiND). We utilize the standard NIfTI format extension
	mechanism to store essential DWI metadata in an extended header for
	multiple commonly-encountered DWI data structures. We demonstrate
	the utility of this approach by implementing a full suite of tools
	for DWI analysis workflows which communicate solely through the MiND
	mechanism. We also show that the MiND framework allows for simple,
	direct DWI data visualization, and we illustrate its effectiveness
	by constructing a group atlas for 330 subjects using solely MiND-centric
	tools for DWI processing. Our results indicate that the MiND framework
	provides a practical solution to the problem of interoperability
	between DWI analysis tools, and it effectively expands the analysis
	options available to end users.},
  doi = {10.1016/j.neuroimage.2010.02.069},
  institution = {Laboratory of Neuro Imaging, University of California, Los Angeles,
	CA 90095-7334, USA.},
  keywords = {Database Management Systems, organization /&/ administration; Diffusion
	Magnetic Resonance Imaging; Humans; Image Interpretation, Computer-Assisted},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paupau},
  pii = {S1053-8119(10)00256-9},
  pmid = {20206274},
  timestamp = {2013.02.25},
  url = {http://dx.doi.org/10.1016/j.neuroimage.2010.02.069}
}

@ARTICLE{Pecevski_2009,
  author = {Dejan Pecevski and Thomas Natschläger and Klaus Schuch},
  title = {PCSIM: A Parallel Simulation Environment for Neural Circuits Fully
	Integrated with Python.},
  journal = {Front. Neuroinform.},
  year = {2009},
  volume = {3},
  pages = {11},
  abstract = {The Parallel Circuit SIMulator (PCSIM) is a software package for simulation
	of neural circuits. It is primarily designed for distributed simulation
	of large scale networks of spiking point neurons. Although its computational
	core is written in C++, PCSIM's primary interface is implemented
	in the Python programming language, which is a powerful programming
	environment and allows the user to easily integrate the neural circuit
	simulator with data analysis and visualization tools to manage the
	full neural modeling life cycle. The main focus of this paper is
	to describe PCSIM's full integration into Python and the benefits
	thereof. In particular we will investigate how the automatically
	generated bidirectional interface and PCSIM's object-oriented modular
	framework enable the user to adopt a hybrid modeling approach: using
	and extending PCSIM's functionality either employing pure Python
	or C++ and thus combining the advantages of both worlds. Furthermore,
	we describe several supplementary PCSIM packages written in pure
	Python and tailored towards setting up and analyzing neural simulations.},
  doi = {10.3389/neuro.11.011.2009},
  institution = {Institute for Theoretical Computer Science, Graz University of Technology
	Graz, Austria.},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {19543450},
  timestamp = {2013.02.01},
  url = {http://dx.doi.org/10.3389/neuro.11.011.2009}
}

@ARTICLE{scikit-learn,
  author = {Pedregosa, F. and Varoquaux, G. and Gramfort, A. and Michel, V. and
	Thirion, B. and Grisel, O. and Blondel, M. and Prettenhofer, P. and
	Weiss, R. and Dubourg, V. and Vanderplas, J. and Passos, A. and Cournapeau,
	D. and Brucher, M. and Perrot, M. and Duchesnay, E.},
  title = {Scikit-learn: Machine Learning in {P}ython},
  journal = {JMLR.},
  year = {2011},
  volume = {12},
  pages = {2825--2830}
}

@ARTICLE{Petermann_2009,
  author = {Thomas Petermann and Tara C Thiagarajan and Mikhail A Lebedev and
	Miguel A L Nicolelis and Dante R Chialvo and Dietmar Plenz},
  title = {Spontaneous cortical activity in awake monkeys composed of neuronal
	avalanches.},
  journal = {Proc. Natl. Acad. Sci. U.S.A.},
  year = {2009},
  volume = {106},
  pages = {15921--15926},
  number = {37},
  month = {Sep},
  abstract = {Spontaneous neuronal activity is an important property of the cerebral
	cortex but its spatiotemporal organization and dynamical framework
	remain poorly understood. Studies in reduced systems--tissue cultures,
	acute slices, and anesthetized rats--show that spontaneous activity
	forms characteristic clusters in space and time, called neuronal
	avalanches. Modeling studies suggest that networks with this property
	are poised at a critical state that optimizes input processing, information
	storage, and transfer, but the relevance of avalanches for fully
	functional cerebral systems has been controversial. Here we show
	that ongoing cortical synchronization in awake rhesus monkeys carries
	the signature of neuronal avalanches. Negative LFP deflections (nLFPs)
	correlate with neuronal spiking and increase in amplitude with increases
	in local population spike rate and synchrony. These nLFPs form neuronal
	avalanches that are scale-invariant in space and time and with respect
	to the threshold of nLFP detection. This dimension, threshold invariance,
	describes a fractal organization: smaller nLFPs are embedded in clusters
	of larger ones without destroying the spatial and temporal scale-invariance
	of the dynamics. These findings suggest an organization of ongoing
	cortical synchronization that is scale-invariant in its three fundamental
	dimensions--time, space, and local neuronal group size. Such scale-invariance
	has ontogenetic and phylogenetic implications because it allows large
	increases in network capacity without a fundamental reorganization
	of the system.},
  doi = {10.1073/pnas.0904089106},
  institution = {Section on Critical Brain Dynamics, National Institute of Mental
	Health, Bethesda, MD 20892, USA.},
  keywords = {Action Potentials; Animals; Cerebral Cortex, physiology; Electrophysiological
	Phenomena; Macaca mulatta; Membrane Potentials; Microelectrodes;
	Models, Neurological; Motor Cortex, physiology; Motor Neurons, physiology;
	Neurons, physiology; Rats},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {0904089106},
  pmid = {19717463},
  timestamp = {2013.03.05},
  url = {http://dx.doi.org/10.1073/pnas.0904089106}
}

@ARTICLE{Petzold_2008,
  author = {Petzold, GC and Albeanu, DF and Sato, TF and Murthy, VN},
  title = {Coupling of neural activity to blood flow in olfactory glomeruli
	is mediated by astrocytic pathways},
  journal = {Neuron},
  year = {2008},
  volume = {58},
  pages = {897–910},
  number = {6},
  month = {June},
  abstract = {Functional neuroimaging uses activity-dependent changes in cerebral
	blood flow to map brain activity, but the contributions of presynaptic
	and postsynaptic activity are incompletely understood, as are the
	underlying cellular pathways. Using intravital multiphoton microscopy,
	we measured presynaptic activity, postsynaptic neuronal and astrocytic
	calcium responses, and erythrocyte velocity and flux in olfactory
	glomeruli during odor stimulation in mice. Odor-evoked functional
	hyperemia in glomerular capillaries was highly correlated with glutamate
	release, but did not require local postsynaptic activity. Odor stimulation
	induced calcium transients in astrocyte endfeet and an associated
	dilation of upstream arterioles. Calcium elevations in astrocytes
	and functional hyperemia depended on astrocytic metabotropic glutamate
	receptor 5 and cyclooxygenase activation. Astrocytic glutamate transporters
	also contributed to functional hyperemia through mechanisms independent
	of calcium rises and cyclooxygenase activation. These local pathways
	initiated by glutamate account for a large part of the coupling between
	synaptic activity and functional hyperemia in the olfactory bulb.},
  owner = {paula},
  timestamp = {2012.10.18}
}

@ARTICLE{Pinotsis_2011,
  author = {D. A. Pinotsis and K. J. Friston},
  title = {Neural fields, spectral responses and lateral connections.},
  journal = {Neuroimage},
  year = {2011},
  volume = {55},
  pages = {39--48},
  number = {1},
  month = {Mar},
  abstract = {This paper describes a neural field model for local (mesoscopic) dynamics
	on the cortical surface. Our focus is on sparse intrinsic connections
	that are characteristic of real cortical microcircuits. This sparsity
	is modelled with radial connectivity functions or kernels with non-central
	peaks. The ensuing analysis allows one to generate or predict spectral
	responses to known exogenous input or random fluctuations. Here,
	we characterise the effect of different connectivity architectures
	(the range, dispersion and propagation speed of intrinsic or lateral
	connections) and synaptic gains on spatiotemporal dynamics. Specifically,
	we look at spectral responses to random fluctuations and examine
	the ability of synaptic gain and connectivity parameters to induce
	Turing instabilities. We find that although the spatial deployment
	and speed of lateral connections can have a profound affect on the
	behaviour of spatial modes over different scales, only synaptic gain
	is capable of producing phase-transitions. We discuss the implications
	of these findings for the use of neural fields as generative models
	in dynamic causal modeling (DCM).},
  doi = {10.1016/j.neuroimage.2010.11.081},
  institution = {The Wellcome Trust Centre for Neuroimaging, University College London,
	Queen Square, London WC1N 3BG, UK. d.pinotsis@fil.ion.ucl.ac.uk},
  keywords = {Action Potentials, physiology; Animals; Brain Mapping, methods; Brain,
	physiology; Computer Simulation; Humans; Models, Neurological; Nerve
	Net, physiology; Neural Pathways, physiology; Synapses, physiology;
	Synaptic Transmission, physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S1053-8119(10)01559-4},
  pmid = {21138771},
  timestamp = {2013.04.11},
  url = {http://dx.doi.org/10.1016/j.neuroimage.2010.11.081}
}

@ARTICLE{Pinotsis_2013,
  author = {D. A. Pinotsis and E. Hansen and K. J. Friston and V. K. Jirsa},
  title = {Anatomical connectivity and the resting state activity of large cortical
	networks.},
  journal = {Neuroimage},
  year = {2013},
  volume = {65},
  pages = {127--138},
  month = {Jan},
  abstract = {This paper uses mathematical modelling and simulations to explore
	the dynamics that emerge in large scale cortical networks, with a
	particular focus on the topological properties of the structural
	connectivity and its relationship to functional connectivity. We
	exploit realistic anatomical connectivity matrices (from diffusion
	spectrum imaging) and investigate their capacity to generate various
	types of resting state activity. In particular, we study emergent
	patterns of activity for realistic connectivity configurations together
	with approximations formulated in terms of neural mass or field models.
	We find that homogenous connectivity matrices, of the sort of assumed
	in certain neural field models give rise to damped spatially periodic
	modes, while more localised modes reflect heterogeneous coupling
	topologies. When simulating resting state fluctuations under realistic
	connectivity, we find no evidence for a spectrum of spatially periodic
	patterns, even when grouping together cortical nodes into communities,
	using graph theory. We conclude that neural field models with translationally
	invariant connectivity may be best applied at the mesoscopic scale
	and that more general models of cortical networks that embed local
	neural fields, may provide appropriate models of macroscopic cortical
	dynamics over the whole brain.},
  doi = {10.1016/j.neuroimage.2012.10.016},
  institution = {The Wellcome Trust Centre for Neuroimaging, University College London
	WC1N 3BG, UK. d.pinotsis@ucl.ac.uk},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S1053-8119(12)01019-1},
  pmid = {23085498},
  timestamp = {2013.02.18},
  url = {http://dx.doi.org/10.1016/j.neuroimage.2012.10.016}
}

@ARTICLE{Pinotsis_2012,
  author = {D. A. Pinotsis and R. J. Moran and K. J. Friston},
  title = {Dynamic causal modeling with neural fields.},
  journal = {Neuroimage},
  year = {2012},
  volume = {59},
  pages = {1261--1274},
  number = {2},
  month = {Jan},
  abstract = {The aim of this paper is twofold: first, to introduce a neural field
	model motivated by a well-known neural mass model; second, to show
	how one can estimate model parameters pertaining to spatial (anatomical)
	properties of neuronal sources based on EEG or LFP spectra using
	Bayesian inference. Specifically, we consider neural field models
	of cortical activity as generative models in the context of dynamic
	causal modeling (DCM). This paper considers the simplest case of
	a single cortical source modeled by the spatiotemporal dynamics of
	hidden neuronal states on a bounded cortical surface or manifold.
	We build this model using multiple layers, corresponding to cortical
	lamina in the real cortical manifold. These layers correspond to
	the populations considered in classical (Jansen and Rit) neural mass
	models. This allows us to formulate a neural field model that can
	be reduced to a neural mass model using appropriate constraints on
	its spatial parameters. In turn, this enables one to compare and
	contrast the predicted responses from equivalent neural field and
	mass models respectively. We pursue this using empirical LFP data
	from a single electrode to show that the parameters controlling the
	spatial dynamics of cortical activity can be recovered, using DCM,
	even in the absence of explicit spatial information in observed data.},
  doi = {10.1016/j.neuroimage.2011.08.020},
  institution = {The Wellcome Trust Centre for Neuroimaging, University College London,
	Queen Square, London WC1N 3BG, UK. d.pinotsis@fil.ion.ucl.ac.uk},
  keywords = {Action Potentials, physiology; Animals; Brain Mapping, methods; Brain,
	physiology; Computer Simulation; Electroencephalography, methods;
	Electromagnetic Fields; Humans; Models, Neurological; Nerve Net,
	physiology; Neurons, physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S1053-8119(11)00909-8},
  pmid = {21924363},
  timestamp = {2013.02.18},
  url = {http://dx.doi.org/10.1016/j.neuroimage.2011.08.020}
}

@ARTICLE{Pinotsis_2012a,
  author = {D. A. Pinotsis and D. S. Schwarzkopf and V. Litvak and G. Rees and
	G. Barnes and K. J. Friston},
  title = {Dynamic causal modelling of lateral interactions in the visual cortex.},
  journal = {Neuroimage},
  year = {2012},
  volume = {66C},
  pages = {563--576},
  month = {Nov},
  abstract = {This paper presents a dynamic causal model based upon neural field
	models of the Amari type. We consider the application of these models
	to non-invasive data, with a special focus on the mapping from source
	activity on the cortical surface to a single channel. We introduce
	a neural field model based upon the canonical microcircuit (CMC),
	in which neuronal populations are assigned to different cortical
	layers. We show that DCM can disambiguate between alternative (neural
	mass and field) models of cortical activity. However, unlike neural
	mass models, DCM with neural fields can address questions about neuronal
	microcircuitry and lateral interactions. This is because they are
	equipped with interlaminar connections and horizontal intra-laminar
	connections that are patchy in nature. These horizontal or lateral
	connections can be regarded as connecting macrocolumns with similar
	feature selectivity. Crucially, the spatial parameters governing
	horizontal connectivity determine the separation (width) of cortical
	macrocolumns. Thus we can estimate the width of macro columns, using
	non-invasive electromagnetic signals. We illustrate this estimation
	using dynamic causal models of steady-state or ongoing spectral activity
	measured using magnetoencephalography (MEG) in human visual cortex.
	Specifically, we revisit the hypothesis that the size of a macrocolumn
	is a key determinant of neuronal dynamics, particularly the peak
	gamma frequency. We are able to show a correlation, over subjects,
	between columnar size and peak gamma frequency - that fits comfortably
	with established correlations between peak gamma frequency and the
	size of visual cortex defined retinotopically. We also considered
	cortical excitability and assessed its relative influence on observed
	gamma activity. This example highlights the potential utility of
	dynamic causal modelling and neural fields in providing quantitative
	characterisations of spatially extended dynamics on the cortical
	surface - that are parameterised in terms of horizontal connections,
	implicit in the cortical micro-architecture and its synaptic parameters.},
  doi = {10.1016/j.neuroimage.2012.10.078},
  institution = {The Wellcome Trust Centre for Neuroimaging, University College London,
	Queen Square, London WC1N 3BG, UK. Electronic address: d.pinotsis@ucl.ac.uk.},
  language = {eng},
  medline-pst = {aheadofprint},
  owner = {paula},
  pii = {S1053-8119(12)01082-8},
  pmid = {23128079},
  timestamp = {2013.02.18},
  url = {http://dx.doi.org/10.1016/j.neuroimage.2012.10.078}
}

@ARTICLE{Plenz_2011,
  author = {Dietmar Plenz and Craig V Stewart and Woodrow Shew and Hongdian Yang
	and Andreas Klaus and Tim Bellay},
  title = {Multi-electrode array recordings of neuronal avalanches in organotypic
	cultures.},
  journal = {JoVE.},
  year = {2011},
  volume = {--},
  pages = {--},
  number = {54},
  abstract = {The cortex is spontaneously active, even in the absence of any particular
	input or motor output. During development, this activity is important
	for the migration and differentiation of cortex cell types and the
	formation of neuronal connections. In the mature animal, ongoing
	activity reflects the past and the present state of an animal into
	which sensory stimuli are seamlessly integrated to compute future
	actions. Thus, a clear understanding of the organization of ongoing
	i.e. spontaneous activity is a prerequisite to understand cortex
	function. Numerous recording techniques revealed that ongoing activity
	in cortex is comprised of many neurons whose individual activities
	transiently sum to larger events that can be detected in the local
	field potential (LFP) with extracellular microelectrodes, or in the
	electroencephalogram (EEG), the magnetoencephalogram (MEG), and the
	BOLD signal from functional magnetic resonance imaging (fMRI). The
	LFP is currently the method of choice when studying neuronal population
	activity with high temporal and spatial resolution at the mesoscopic
	scale (several thousands of neurons). At the extracellular microelectrode,
	locally synchronized activities of spatially neighbored neurons result
	in rapid deflections in the LFP up to several hundreds of microvolts.
	When using an array of microelectrodes, the organizations of such
	deflections can be conveniently monitored in space and time. Neuronal
	avalanches describe the scale-invariant spatiotemporal organization
	of ongoing neuronal activity in the brain. They are specific to the
	superficial layers of cortex as established in vitro, in vivo in
	the anesthetized rat, and in the awake monkey. Importantly, both
	theoretical and empirical studies suggest that neuronal avalanches
	indicate an exquisitely balanced critical state dynamics of cortex
	that optimizes information transfer and information processing. In
	order to study the mechanisms of neuronal avalanche development,
	maintenance, and regulation, in vitro preparations are highly beneficial,
	as they allow for stable recordings of avalanche activity under precisely
	controlled conditions. The current protocol describes how to study
	neuronal avalanches in vitro by taking advantage of superficial layer
	development in organotypic cortex cultures, i.e. slice cultures,
	grown on planar, integrated microelectrode arrays (MEA).},
  doi = {10.3791/2949},
  institution = {Section on Critical Brain Dynamics, National Institute of Mental
	Health, USA.},
  keywords = {Action Potentials, physiology; Animals; Cerebral Cortex, cytology/physiology;
	Electrodes; Haplorhini; Membrane Potentials, physiology; Mice; Neurons,
	cytology/physiology; Organ Culture Techniques, methods; Rats},
  language = {eng},
  medline-pst = {epublish},
  owner = {paula},
  pii = {2949},
  pmid = {21841767},
  timestamp = {2013.03.05},
  url = {http://dx.doi.org/10.3791/2949}
}

@ARTICLE{Plenz_2007,
  author = {Dietmar Plenz and Tara C Thiagarajan},
  title = {The organizing principles of neuronal avalanches: cell assemblies
	in the cortex?},
  journal = {Trends Neurosci.},
  year = {2007},
  volume = {30},
  pages = {101--110},
  number = {3},
  month = {Mar},
  abstract = {Neuronal avalanches are spatiotemporal patterns of neuronal activity
	that occur spontaneously in superficial layers of the mammalian cortex
	under various experimental conditions. These patterns reflect fast
	propagation of local synchrony, display a rich spatiotemporal diversity
	and recur over several hours. The statistical organization of pattern
	sizes is invariant to the choice of spatial scale, demonstrating
	that the functional linking of cortical sites into avalanches occurs
	on all spatial scales with a fractal organization. These features
	suggest an underlying network of neuronal interactions that balances
	diverse representations with predictable recurrence, similar to what
	has been theorized for cell assembly formation. We propose that avalanches
	reflect the transient formation of cell assemblies in the cortex
	and discuss various models that provide mechanistic insights into
	the underlying dynamics, suggesting that they arise in a critical
	regime.},
  doi = {10.1016/j.tins.2007.01.005},
  institution = {Section of Neural Network Physiology, National Institute of Mental
	Health, Porter Neuroscience Research Center, 35 Convent Drive, Bethesda,
	MD 20892, USA. plenzd@mail.nih.gov},
  keywords = {Animals; Cell Communication, physiology; Cerebral Cortex, cytology/physiology;
	Cortical Synchronization; Humans; Models, Neurological; Neural Pathways,
	cytology/physiology; Neurons, cytology/physiology; Signal Transduction,
	physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S0166-2236(07)00019-7},
  pmid = {17275102},
  timestamp = {2013.03.05},
  url = {http://dx.doi.org/10.1016/j.tins.2007.01.005}
}

@ARTICLE{Polonsky_2000,
  author = {A. Polonsky and R. Blake and J. Braun and D. J. Heeger},
  title = {Neuronal activity in human primary visual cortex correlates with
	perception during binocular rivalry.},
  journal = {Nat Neurosci},
  year = {2000},
  volume = {3},
  pages = {1153--1159},
  number = {11},
  month = {Nov},
  abstract = {During binocular rivalry, two incompatible monocular images compete
	for perceptual dominance, with one pattern temporarily suppressed
	from conscious awareness. We measured fMRI signals in early visual
	cortex while subjects viewed rival dichoptic images of two different
	contrasts; the contrast difference served as a 'tag' for the neuronal
	representations of the two monocular images. Activity in primary
	visual cortex (V1) increased when subjects perceived the higher contrast
	pattern and decreased when subjects perceived the lower contrast
	pattern. These fluctuations in V1 activity during rivalry were about
	55\% as large as those evoked by alternately presenting the two monocular
	images without rivalry. The rivalry-related fluctuations in V1 activity
	were roughly equal to those observed in other visual areas (V2, V3,
	V3a and V4v). These results challenge the view that the neuronal
	mechanisms responsible for binocular rivalry occur primarily in later
	visual areas.},
  doi = {10.1038/80676},
  institution = {Department of Psychology, Jordan Hall, Building 420, Stanford University,
	Stanford, California 94303, USA.},
  keywords = {Algorithms; Humans; Least-Squares Analysis; Magnetic Resonance Imaging;
	Pattern Recognition, Visual, physiology; Photic Stimulation, methods;
	Vision, Binocular, physiology; Visual Cortex, physiology; Visual
	Perception, physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {11036274},
  timestamp = {2013.08.19},
  url = {http://dx.doi.org/10.1038/80676}
}

@ARTICLE{Pyka_2010,
  author = {Pyka, Martin and Hertog, Matthias and Fernandez, Raul and Hauke,
	Sascha and Heider, Dominik and Dannlowski, Udo and Konrad, Carsten},
  title = {fMRI data visualization with BrainBlend and Blender.},
  journal = {Neuroinformatics},
  year = {2010},
  volume = {8},
  pages = {21--31},
  number = {1},
  month = {Mar},
  abstract = {The visualization and exploration of neuroimaging data is important
	for the analysis of anatomical and functional magnetic resonance
	(MR) images and thresholded statistical parametric maps. While two-dimensional
	orthogonal views of neuroimaging data are used to display statistical
	analyses, real three-dimensional (3d) depictions are helpful for
	showing the spatial distribution of a functional network, as well
	as its temporal evolution. However, viewers that are freely available
	on the internet offer only limited rendering capabilities and depictions
	of temporal changes of the blood oxygen level-dependent (BOLD) response.
	In this article, we present BrainBlend, a toolbox for the software
	package Statistical Parametric Mapping (SPM), that generates voxeldata
	files to be used with the open-source 3d-software "Blender". Our
	interface between SPM and Blender permits the use of any Analyze-
	and Nifti-file for the creation of images and animations of transparent
	volumetric objects. Different kinds of anatomical, functional and
	statistical data can be rendered as volumetric objects in order to
	convey an immediate understanding of the three-dimensional shape.
	Representations of functional networks can be animated using a time
	course extracted from the general linear model or the independent
	component analysis. Relative BOLD activations of functional MR-images
	can be calculated for a time-resolved depiction of hemodynamic changes.
	The resulting animation can be displayed along with its corresponding
	paradigm matrix and the presented stimuli. BrainBlend is particularly
	suitable for the visual exploration of interactions between functional
	networks, for time-resolved animations of BOLD changes and meets
	high demands on visual quality in images and animations.},
  doi = {10.1007/s12021-009-9060-3},
  institution = {Department of Psychiatry, University of Münster, Münster, Germany.
	martin.pyka@uni-muenster.de},
  keywords = {Brain Mapping; Brain, blood supply; Data Interpretation, Statistical;
	Humans; Image Processing, Computer-Assisted, methods; Magnetic Resonance
	Imaging, methods; Oxygen, blood; Software; User-Computer Interface},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paupau},
  pmid = {20033355},
  timestamp = {2013.02.25},
  url = {http://dx.doi.org/10.1007/s12021-009-9060-3}
}

@ARTICLE{Qubbaj_2007,
  author = {Qubbaj, Murad and Jirsa, VK},
  title = {Neural field dynamics with heterogeneous connection topology.},
  journal = {Phys Rev Lett},
  year = {2007},
  volume = {98},
  pages = {238102},
  number = {23},
  month = {Jun},
  abstract = {Neural fields receive inputs from local and nonlocal sources. Notably
	in a biologically realistic architecture the latter vary under spatial
	translations (heterogeneous), the former do not (homogeneous). To
	understand the mutual effects of homogeneous and heterogeneous connectivity,
	we study the stability of the steady state activity of a neural field
	as a function of its connectivity and transmission speed. We show
	that myelination, a developmentally relevant change of the heterogeneous
	connectivity, always results in the stabilization of the steady state
	via oscillatory instabilities, independent of the local connectivity.
	Nonoscillatory instabilities are shown to be independent of any influences
	of time delay.},
  institution = {Department of Physics, Florida Atlantic University, Boca Raton, Florida
	33431, USA.},
  keywords = {Humans; Models, Biological; Nerve Net, physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {17677938},
  timestamp = {2013.05.02}
}

@ARTICLE{Qubbaj_2012,
  author = {Murad R Qubbaj and Rachata Muneepeerakul},
  title = {Two-actor conflict with time delay: a dynamical model.},
  journal = {Phys Rev E Stat Nonlin Soft Matter Phys},
  year = {2012},
  volume = {86},
  pages = {056101},
  number = {5 Pt 2},
  month = {Nov},
  note = {I'm curious about this article ... definitely to read ...},
  abstract = {Recent mathematical dynamical models of the conflict between two different
	actors, be they nations, groups, or individuals, have been developed
	that are capable of predicting various outcomes depending on the
	chosen feedback strategies, initial conditions, and the previous
	states of the actors. In addition to these factors, this paper examines
	the effect of time delayed feedback on the conflict dynamics. Our
	analysis shows that under certain initial and feedback conditions,
	a stable neutral equilibrium of conflict may destabilize for some
	critical values of time delay, and the two actors may evolve to new
	emotional states. We investigate the results by constructing critical
	delay surfaces for different sets of parameters and analyzing results
	from numerical simulations. These results provide new insights regarding
	conflict and conflict resolution and may help planners in adjusting
	and assessing their strategic decisions.},
  institution = {School of Sustainability, Arizona State University, Tempe, Arizona
	85287, USA. Murad.Qubbaj@asu.edu},
  keywords = {Algorithms; Computer Simulation; Conflict (Psychology); Decision Making;
	Game Theory; Models, Theoretical},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {23214837},
  timestamp = {2013.08.30}
}

@ARTICLE{mayavi_2011,
  author = {Ramachandran, P. and Varoquaux, G.},
  title = {{Mayavi: 3D Visualization of Scientific Data}},
  journal = {Computing in science \& engineering},
  year = {2011},
  volume = {13},
  pages = {40--51},
  number = {2},
  issn = {1521-9615},
  publisher = {IEEE}
}

@ARTICLE{Ramnani_2002,
  author = {Narender Ramnani and Lucy Lee and Andrea Mechelli and Christophe
	Phillips and Alard Roebroeck and Elia Formisano},
  title = {Exploring brain connectivity: a new frontier in systems neuroscience.
	Functional Brain Connectivity, 4-6 April 2002, Dusseldorf, Germany.},
  journal = {Trends Neurosci.},
  year = {2002},
  volume = {25},
  pages = {496--497},
  number = {10},
  month = {Oct},
  abstract = {Functional Brain Connectivity, held on 4-6 April 2002, Dusseldorf,
	Germany.},
  institution = {Centre for fMRI of the Brain, University of Oxford, UK. nramnani@fmrib.ox.ac.uk},
  keywords = {Brain Mapping; Brain, physiology; Humans; Neural Pathways, physiology;
	Neurosciences, methods/trends},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S0166223602022270},
  pmid = {12220872},
  timestamp = {2013.02.14}
}

@ARTICLE{Ray_2008,
  author = {Subhasis Ray and Upinder S Bhalla},
  title = {PyMOOSE: Interoperable Scripting in Python for MOOSE.},
  journal = {Front. Neuroinform.},
  year = {2008},
  volume = {2},
  pages = {6},
  abstract = {Python is emerging as a common scripting language for simulators.
	This opens up many possibilities for interoperability in the form
	of analysis, interfaces, and communications between simulators. We
	report the integration of Python scripting with the Multi-scale Object
	Oriented Simulation Environment (MOOSE). MOOSE is a general-purpose
	simulation system for compartmental neuronal models and for models
	of signaling pathways based on chemical kinetics. We show how the
	Python-scripting version of MOOSE, PyMOOSE, combines the power of
	a compiled simulator with the versatility and ease of use of Python.
	We illustrate this by using Python numerical libraries to analyze
	MOOSE output online, and by developing a GUI in Python/Qt for a MOOSE
	simulation. Finally, we build and run a composite neuronal/signaling
	model that uses both the NEURON and MOOSE numerical engines, and
	Python as a bridge between the two. Thus PyMOOSE has a high degree
	of interoperability with analysis routines, with graphical toolkits,
	and with other simulators.},
  doi = {10.3389/neuro.11.006.2008},
  institution = {National Centre for Biological Sciences Bangalore, India.},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {19129924},
  timestamp = {2013.02.01},
  url = {http://dx.doi.org/10.3389/neuro.11.006.2008}
}

@ARTICLE{Rennie_2002,
  author = {C. J. Rennie and P. A. Robinson and J. J. Wright},
  title = {Unified neurophysical model of EEG spectra and evoked potentials.},
  journal = {Biol. Cybern.},
  year = {2002},
  volume = {86},
  pages = {457--471},
  number = {6},
  month = {Jun},
  abstract = {Evoked potentials -- the brain's transient electrical responses to
	discrete stimuli -- are modeled as impulse responses using a continuum
	model of brain electrical activity. Previous models of ongoing brain
	activity are refined by adding an improved model of thalamic connectivity
	and modulation, and by allowing for two populations of excitatory
	cortical neurons distinguished by their axonal ranges. Evoked potentials
	are shown to be modelable as an impulse response that is a sum of
	component responses. The component occurring about 100 ms poststimulus
	is attributed to sensory activation, and this, together with positive
	and negative feedback pathways between the cortex and thalamus, results
	in subsequent peaks and troughs that semiquantitatively reproduce
	those of observed evoked potentials. Modulation of the strengths
	of positive and negative feedback, in ways consistent with psychological
	theories of attentional focus, results in distinct responses resembling
	those seen in experiments involving attentional changes. The modeled
	impulse responses reproduce key features of typical experimental
	evoked response potentials: timing, relative amplitude, and number
	of peaks. The same model, with further modulation of feedback, also
	reproduces experimental spectra. Together, these results mean that
	a broad range of ongoing and transient electrocortical activity can
	be understood within a common framework, which is parameterized by
	values that are directly related to physiological and anatomical
	quantities.},
  doi = {10.1007/s00422-002-0310-9},
  institution = {School of Physics, University of Sydney and Department of Medical
	Physics, Westmead Hospital, New South Wales, Australia. rennie@physics.usyd.edu.au},
  keywords = {Cerebral Cortex, cytology/physiology; Electroencephalography; Evoked
	Potentials, physiology; Humans; Models, Neurological; Neural Pathways,
	physiology; Thalamus, cytology/physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {12111274},
  timestamp = {2013.02.18},
  url = {http://dx.doi.org/10.1007/s00422-002-0310-9}
}

@ARTICLE{Rennie_1999,
  author = {Rennie, C. J. and Robinson, P. A. and Wright, J. J.},
  title = {Effects of local feedback on dispersion of electrical waves in the
	cerebral cortex},
  journal = {Phys. Rev. E (3)},
  year = {1999},
  volume = {59},
  pages = {3320--3329},
  month = {Mar},
  doi = {10.1103/PhysRevE.59.3320},
  issue = {3},
  publisher = {American Physical Society},
  url = {http://link.aps.org/doi/10.1103/PhysRevE.59.3320}
}

@ARTICLE{Rennie_2000,
  author = {C. J. Rennie and J. J. Wright and P. A. Robinson},
  title = {Mechanisms of cortical electrical activity and emergence of gamma
	rhythm.},
  journal = {J. Theor. Biol.},
  year = {2000},
  volume = {205},
  pages = {17--35},
  number = {1},
  month = {Jul},
  abstract = {A continuum model of the electrical activity of the cerebral cortex
	is described which predicts the occurrence of a resonance in the
	gamma range near 40 Hz. The emergence of this resonance is due to
	two refinements to a previous model, namely the inclusion of a modulation
	of synaptic strength due to finite reversal potentials, and use of
	parameters that better match physiological measurements. Analytical
	expressions for the fixed points of the system and for its linear
	dynamics are found in terms of average neuronal properties, and together
	explain the occurrence and modulation of the gamma-like resonance.
	The analytical results are confirmed by a numerical simulation.},
  doi = {10.1006/jtbi.2000.2040},
  institution = {School of Physics, University of Sydney, New South Wales, 2006, Australia.
	rennie@physics.usyd.edu.au},
  keywords = {Cerebral Cortex, physiology; Computer Simulation; Electroencephalography;
	Electrophysiology; Humans; Linear Models; Models, Neurological; Neurons,
	physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S0022-5193(00)92040-X},
  pmid = {10860697},
  timestamp = {2013.02.18},
  url = {http://dx.doi.org/10.1006/jtbi.2000.2040}
}

@ARTICLE{Richardson2011,
  author = {Mark P Richardson and Fernando H Lopes da Silva},
  title = {TMS studies of preictal cortical excitability change.},
  journal = {Epilepsy Res.},
  year = {2011},
  volume = {97},
  pages = {273--277},
  number = {3},
  month = {Dec},
  abstract = {The transition between the interictal and ictal states may be characterised
	in terms of the dynamics of a complex system. Seizures may emerge
	because of a change in system parameters, but these parameters may
	be invisible to passive observation. Therefore, a number of investigators
	have developed methods to probe the system using stimulation; these
	probing stimuli may reveal important hidden parameters. Here we describe
	studies from two sets of investigators working independently, which
	have shown that motor responses to transcranial magnetic brain stimulation
	(TMS) differ between the interictal state remote from any seizure,
	and a period of hours immediately prior to a seizure. We place these
	studies in the context of the known physiology of motor responses
	to TMS and discuss how actively probing the state of brain excitability
	may open new windows on its dynamics.},
  doi = {10.1016/j.eplepsyres.2011.10.018},
  institution = {Paul Getty III Professor of Epilepsy, King's College London, Institute
	of Psychiatry, De Crespigny Park, London SE5 8AF, UK. mark.richardson@kcl.ac.uk},
  keywords = {Cerebral Cortex, physiology; Electroencephalography; Epilepsy, diagnosis/physiopathology;
	Humans; Predictive Value of Tests; Transcranial Magnetic Stimulation},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S0920-1211(11)00326-3},
  pmid = {22050977},
  timestamp = {2013.02.11},
  url = {http://dx.doi.org/10.1016/j.eplepsyres.2011.10.018}
}

@ARTICLE{Riera_2005,
  author = {Riera, J. and Aubert, E. and Iwata, K. and Kawashima, R. and Wan,
	X. and Ozaki, T.},
  title = {Fusing EEG and fMRI based on a bottom-up model: inferring activation
	and effective connectivity in neural masses.},
  journal = {Philos. Trans. R. Soc. Lond. B. Biol. Sci.},
  year = {2005},
  volume = {360},
  pages = {1025--1041},
  number = {1457},
  month = {May},
  abstract = {The elucidation of the complex machinery used by the human brain to
	segregate and integrate information while performing high cognitive
	functions is a subject of imminent future consequences. The most
	significant contributions to date in this field, known as cognitive
	neuroscience, have been achieved by using innovative neuroimaging
	techniques, such as electroencephalogram (EEG) and functional magnetic
	resonance imaging (fMRI), which measure variations in both the time
	and the space of some interpretable physical magnitudes. Extraordinary
	maps of cerebral activation involving function-restricted brain areas,
	as well as graphs of the functional connectivity between them, have
	been obtained from EEG and fMRI data by solving some spatio-temporal
	inverse problems, which constitutes a top-down approach. However,
	in many cases, a natural bridge between these maps/graphs and the
	causal physiological processes is lacking, leading to some misunderstandings
	in their interpretation. Recent advances in the comprehension of
	the underlying physiological mechanisms associated with different
	cerebral scales have provided researchers with an excellent scenario
	to develop sophisticated biophysical models that permit an integration
	of these neuroimage modalities, which must share a common aetiology.
	This paper proposes a bottom-up approach, involving physiological
	parameters in a specific mesoscopic dynamic equations system. Further
	observation equations encapsulating the relationship between the
	mesostates and the EEG/fMRI data are obtained on the basis of the
	physical foundations of these techniques. A methodology for the estimation
	of parameters from fused EEG/fMRI data is also presented. In this
	context, the concepts of activation and effective connectivity are
	carefully revised. This new approach permits us to examine and discuss
	some future prospects for the integration of multimodal neuroimages.},
  doi = {10.1098/rstb.2005.1646},
  institution = {Advanced Science and Technology of Materials, NICHe, Tohoku University,
	Aoba 10, Aramaki, Aobaku, Sendai 980-8579, Japan. riera@idac.tohoku.ac.jp},
  keywords = {Brain Mapping, methods; Brain, anatomy /&/ histology/physiology; Data
	Interpretation, Statistical; Electroencephalography, methods; Humans;
	Magnetic Resonance Imaging, methods; Models, Neurological; Psychomotor
	Performance, physiology; Regression Analysis; Time Factors},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paupau},
  pii = {LJDYNHGVDU9X77FL},
  pmid = {16087446},
  timestamp = {2013.04.09},
  url = {http://dx.doi.org/10.1098/rstb.2005.1646}
}

@ARTICLE{Riera_2007,
  author = {Riera, JJ and Jimenez, JC and Wan, X and Kawashima, R and Ozaki,
	T},
  title = {Nonlinear local electrovascular coupling. II: From data to neuronal
	masses.},
  journal = {Hum. Brain Mapp.},
  year = {2007},
  volume = {28},
  pages = {335–354},
  owner = {paupau},
  timestamp = {2013.04.09}
}

@ARTICLE{Riera_2004,
  author = {Riera, Jorge J. and Watanabe, Jobu and Kazuki, Iwata and Naoki, Miura
	and Aubert, Eduardo and Ozaki, Tohru and Kawashima, Ryuta},
  title = {A state-space model of the hemodynamic approach: nonlinear filtering
	of BOLD signals.},
  journal = {Neuroimage},
  year = {2004},
  volume = {21},
  pages = {547--567},
  number = {2},
  month = {Feb},
  abstract = {In this paper, a new procedure is presented which allows the estimation
	of the states and parameters of the hemodynamic approach from blood
	oxygenation level dependent (BOLD) responses. The proposed method
	constitutes an alternative to the recently proposed Friston [NeuroImage
	16 (2002) 513] method and has some advantages over it. The procedure
	is based on recent groundbreaking time series analysis techniques
	that have been, in this case, adopted to characterize hemodynamic
	responses in functional magnetic resonance imaging (fMRI). This work
	represents a fundamental improvement over existing approaches to
	system identification using nonlinear hemodynamic models and is important
	for three reasons. First, our model includes physiological noise.
	Previous models have been based upon ordinary differential equations
	that only allow for noise or error to enter at the level of observation.
	Secondly, by using the innovation method and the local linearization
	filter, not only the parameters, but also the underlying states of
	the system generating responses can be estimated. These states can
	include things like a flow-inducing signal triggered by neuronal
	activation, de-oxyhemoglobine, cerebral blood flow and volume. Finally,
	radial basis functions have been introduced as a parametric model
	to represent arbitrary temporal input sequences in the hemodynamic
	approach, which could be essential to understanding those brain areas
	indirectly related to the stimulus. Hence, thirdly, by inferring
	about the radial basis parameters, we are able to perform a blind
	deconvolution, which permits both the reconstruction of the dynamics
	of the most likely hemodynamic states and also, to implicitly reconstruct
	the underlying synaptic dynamics, induced experimentally, which caused
	these states variations. From this study, we conclude that in spite
	of the utility of the standard discrete convolution approach used
	in statistical parametric maps (SPM), nonlinear BOLD phenomena and
	unspecific input temporal sequences must be included in the fMRI
	analysis.},
  doi = {10.1016/j.neuroimage.2003.09.052},
  institution = {Advanced Science and Technology of Materials, NICHe, Tohoku University,
	Sendai 980-8579, Japan. riera@idac.tohoku.ac.jp},
  keywords = {Adult; Blood Flow Velocity, physiology; Blood Volume, physiology;
	Brain, blood supply/physiology; Cerebellum, blood supply/physiology;
	Female; Hemodynamics, physiology; Humans; Image Enhancement, methods;
	Image Processing, Computer-Assisted, methods; Imaging, Three-Dimensional,
	methods; Magnetic Resonance Imaging, methods/statistics /&/ numerical
	data; Male; Mathematical Computing; Motor Activity, physiology; Motor
	Cortex, blood supply/physiology; Neurons, physiology; Nonlinear Dynamics;
	Oxygen Consumption, physiology; Regional Blood Flow, physiology;
	Somatosensory Cortex, blood supply/physiology; Synaptic Transmission,
	physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paupau},
  pii = {S1053811903006025},
  pmid = {14980557},
  timestamp = {2013.04.09},
  url = {http://dx.doi.org/10.1016/j.neuroimage.2003.09.052}
}

@ARTICLE{Rinzel_1998,
  author = {J. Rinzel and D. Terman and X. Wang and B. Ermentrout},
  title = {Propagating activity patterns in large-scale inhibitory neuronal
	networks.},
  journal = {Science},
  year = {1998},
  volume = {279},
  pages = {1351--1355},
  number = {5355},
  month = {Feb},
  abstract = {The propagation of activity is studied in a spatially structured network
	model of gamma-aminobutyric acid-containing (GABAergic) neurons exhibiting
	postinhibitory rebound. In contrast to excitatory-coupled networks,
	recruitment spreads very slowly because cells fire only after the
	postsynaptic conductance decays, and with two possible propagation
	modes. If the connection strength decreases monotonically with distance
	(on-center), then propagation occurs in a discontinuous manner. If
	the self- and nearby connections are absent (off-center), propagation
	can proceed smoothly. Modest changes in the synaptic reversal potential
	can result in depolarization-mediated waves that are 25 times faster.
	Functional and developmental roles for these behaviors and implications
	for thalamic circuitry are suggested.},
  institution = {Mathematical Research Branch, National Institute of Diabetes and
	Digestive and Kidney Diseases, National Institutes of Health, Bethesda,
	MD 20892, USA. rinzel@cns.nyu.edu},
  keywords = {Feedback; Interneurons, physiology; Membrane Potentials; Models, Neurological;
	Nerve Net, physiology; Neural Inhibition; Recruitment, Neurophysiological;
	Synapses, physiology; Synaptic Transmission; Thalamus, physiology;
	gamma-Aminobutyric Acid, physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {9478895},
  timestamp = {2013.09.04}
}

@ARTICLE{Ritter_2013,
  author = {Ritter, P and Schirner, M and McIntosh, AR and Jirsa VK},
  title = {The Virtual Brain Integrates Computational Modelling and Multimodal
	Neuroimaging.},
  journal = {Brain Connectivity},
  year = {2013},
  volume = {In press},
  pages = {[Epub ahead of print]},
  owner = {paupau},
  timestamp = {2013.04.14}
}

@ARTICLE{Roberts_2012a,
  author = {J. A. Roberts and P. A. Robinson},
  title = {Corticothalamic dynamics: structure of parameter space, spectra,
	instabilities, and reduced model.},
  journal = {Phys. Rev. E: Stat., Nonlinear, Soft Matter Phys.},
  year = {2012},
  volume = {85},
  pages = {011910},
  number = {1 Pt 1},
  month = {Jan},
  abstract = {Linear instabilities are analyzed in a physiologically based mean-field
	corticothalamic model and a reduced-parameter model derived from
	it. In both models, the stable zone corresponding to normal arousal
	states is bounded by a series of surfaces demarcating the onsets
	of instabilities. The stable zone is found to depend on delay and
	rate parameters, whose values have a simple relationship to the number
	of instabilities and dominant frequencies on the stable zone's boundary.
	The dominant frequencies of linear activity inside the stable zone
	are found to lie in clearly delineated regions, each corresponding
	to an instability surface on its boundary and having approximately
	the same dominant frequency. These regions are ordered in parameter
	space according to their dominant frequencies, and an instability
	associated with the intrathalamic loop is shown to have the highest
	frequency that can become unstable. This reveals an important role
	for the thalamus in controlling the stability and bandwidth of dynamics
	in the corticothalamic system as a whole. The reduced model is found
	to agree well with the full model in a wide region of parameter space
	and, thus, is a useful guide to the full model's dynamics.},
  institution = {School of Physics, University of Sydney, New South Wales 2006, Australia.
	jamesr@physics.usyd.edu.au},
  keywords = {Action Potentials, physiology; Animals; Cerebral Cortex, physiology;
	Computer Simulation; Humans; Models, Neurological; Neural Pathways,
	physiology; Thalamus, physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {22400594},
  timestamp = {2013.03.25}
}

@ARTICLE{Roberts2012,
  author = {J. A. Roberts and P. A. Robinson},
  title = {Quantitative theory of driven nonlinear brain dynamics.},
  journal = {Neuroimage},
  year = {2012},
  volume = {62},
  pages = {1947--1955},
  number = {3},
  month = {Sep},
  abstract = {Strong periodic stimuli such as bright flashing lights evoke nonlinear
	responses in the brain and interact nonlinearly with ongoing cortical
	activity, but the underlying mechanisms for these phenomena are poorly
	understood at present. The dominant features of these experimentally
	observed dynamics are reproduced by the dynamics of a quantitative
	neural field model subject to periodic drive. Model power spectra
	over a range of drive frequencies show agreement with multiple features
	of experimental measurements, exhibiting nonlinear effects including
	entrainment over a range of frequencies around the natural alpha
	frequency f(α), subharmonic entrainment near 2f(α), and harmonic
	generation. Further analysis of the driven dynamics as a function
	of the drive parameters reveals rich nonlinear dynamics that is predicted
	to be observable in future experiments at high drive amplitude, including
	period doubling, bistable phase-locking, hysteresis, wave mixing,
	and chaos indicated by positive Lyapunov exponents. Moreover, photosensitive
	seizures are predicted for physiologically realistic model parameters
	yielding bistability between healthy and seizure dynamics. These
	results demonstrate the applicability of neural field models to the
	new regime of periodically driven nonlinear dynamics, enabling interpretation
	of experimental data in terms of specific generating mechanisms and
	providing new tests of the theory.},
  doi = {10.1016/j.neuroimage.2012.05.054},
  institution = {School of Physics, University of Sydney, New South Wales 2006, Australia.
	jamesr@physics.usyd.edu.au},
  keywords = {Brain, physiology; Electroencephalography; Evoked Potentials, Visual,
	physiology; Humans; Models, Neurological; Models, Theoretical; Nonlinear
	Dynamics},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S1053-8119(12)00542-3},
  pmid = {22652022},
  timestamp = {2013.03.25},
  url = {http://dx.doi.org/10.1016/j.neuroimage.2012.05.054}
}

@ARTICLE{Roberts_Robinson_2008Delay,
  author = {Roberts, J. A. and Robinson, P. A.},
  title = {Modeling distributed axonal delays in mean-field brain dynamics},
  journal = {Phys. Rev. E: Stat., Nonlinear, Soft Matter Phys.},
  year = {2008},
  volume = {78},
  pages = {051901},
  number = {5},
  month = {Nov},
  doi = {10.1103/PhysRevE.78.051901},
  numpages = {8},
  publisher = {American Physical Society}
}

@ARTICLE{Roberts_Robinson_2008Epilepsy,
  author = {Roberts, J.A. and Robinson, P.A.},
  title = {{Modeling absence seizure dynamics: Implications for basic mechanisms
	and measurement of thalamocortical and corticothalamic latencies}},
  journal = {J. Theor. Biol.},
  year = {2008},
  volume = {253},
  pages = {189--201},
  number = {1},
  issn = {0022-5193},
  publisher = {Elsevier}
}

@ARTICLE{Robinson_2012,
  author = {P. A. Robinson},
  title = {Neural field theory with variance dynamics.},
  journal = {J. Math. Biol.},
  year = {2012},
  volume = {--},
  pages = {--},
  month = {May},
  abstract = {Previous neural field models have mostly been concerned with prediction
	of mean neural activity and with second order quantities such as
	its variance, but without feedback of second order quantities on
	the dynamics. Here the effects of feedback of the variance on the
	steady states and adiabatic dynamics of neural systems are calculated
	using linear neural field theory to estimate the neural voltage variance,
	then including this quantity in the total variance parameter of the
	nonlinear firing rate-voltage response function, and thus into determination
	of the fixed points and the variance itself. The general results
	further clarify the limits of validity of approaches with and without
	inclusion of variance dynamics. Specific applications show that stability
	against a saddle-node bifurcation is reduced in a purely cortical
	system, but can be either increased or decreased in the corticothalamic
	case, depending on the initial state. Estimates of critical variance
	scalings near saddle-node bifurcation are also found, including physiologically
	based normalizations and new scalings for mean firing rate and the
	position of the bifurcation.},
  doi = {10.1007/s00285-012-0541-x},
  institution = {School of Physics, University of Sydney, Sydney, NSW, 2006, Australia,
	robinson@physics.usyd.edu.au.},
  language = {eng},
  medline-pst = {aheadofprint},
  owner = {paula},
  pmid = {22576451},
  timestamp = {2013.03.25},
  url = {http://dx.doi.org/10.1007/s00285-012-0541-x}
}

@ARTICLE{Robinson_2012a,
  author = {P. A. Robinson},
  title = {Interrelating anatomical, effective, and functional brain connectivity
	using propagators and neural field theory.},
  journal = {Phys. Rev. E: Stat., Nonlinear, Soft Matter Phys.},
  year = {2012},
  volume = {85},
  pages = {011912},
  number = {1 Pt 1},
  month = {Jan},
  abstract = {It is shown how to compute effective and functional connection matrices
	(eCMs and fCMs) from anatomical CMs (aCMs) and corresponding strength-of-connection
	matrices (sCMs) using propagator methods in which neural interactions
	play the role of scatterings. This analysis demonstrates how network
	effects dress the bare propagators (the sCMs) to yield effective
	propagators (the eCMs) that can be used to compute the covariances
	customarily used to define fCMs. The results incorporate excitatory
	and inhibitory connections, multiple structures and populations,
	asymmetries, time delays, and measurement effects. They can also
	be postprocessed in the same manner as experimental measurements
	for direct comparison with data and thereby give insights into the
	role of coarse-graining, thresholding, and other effects in determining
	the structure of CMs. The spatiotemporal results show how to generalize
	CMs to include time delays and how natural network modes give rise
	to long-range coherence at resonant frequencies. The results are
	demonstrated using tractable analytic cases via neural field theory
	of cortical and corticothalamic systems. These also demonstrate close
	connections between the structure of CMs and proximity to critical
	points of the system, highlight the importance of indirect links
	between brain regions and raise the possibility of imaging specific
	levels of indirect connectivity. Aside from the results presented
	explicitly here, the expression of the connections among aCMs, sCMs,
	eCMs, and fCMs in terms of propagators opens the way for propagator
	theory to be further applied to analysis of connectivity.},
  institution = {School of Physics, University of Sydney, New South Wales 2006, Australia.},
  keywords = {Action Potentials, physiology; Animals; Brain, physiology; Computer
	Simulation; Humans; Models, Neurological; Nerve Net, physiology;
	Synaptic Transmission, physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {22400596},
  timestamp = {2013.03.25}
}

@ARTICLE{Robinson_2011,
  author = {P. A. Robinson},
  title = {Neural field theory of synaptic plasticity.},
  journal = {J. Theor. Biol.},
  year = {2011},
  volume = {285},
  pages = {156--163},
  number = {1},
  month = {Sep},
  abstract = {Plasticity is crucial to neural development, learning, and memory.
	In the common in vivo situation where postsynaptic neural activity
	results from multiple presynaptic inputs, it is shown that a widely
	used class of correlation-dependent and spike-timing dependent plasticity
	rules can be written in a form that can be incorporated into neural
	field theory, which enables their system-level dynamics to be investigated.
	It is shown that the resulting plasticity dynamics depends strongly
	on the stimulus spectrum via overall system frequency responses.
	In the case of perturbations that are approximately linear, explicit
	formulas are found for the dynamics in terms of stimulus spectra
	via system transfer functions. The resulting theory is applied to
	a simple model system to reveal how collective effects, especially
	resonances, can drastically modify system-level plasticity dynamics
	from that implied by single-neuron analyses. The simplified model
	illustrates the potential relevance of these effects in applications
	to brain stimulation, synaptic homeostasis, and epilepsy.},
  doi = {10.1016/j.jtbi.2011.06.023},
  institution = {School of Physics, University of Sydney, Sydney, NSW 2006, Australia.
	robinson@physics.usyd.edu.au},
  keywords = {Electroconvulsive Therapy; Homeostasis, physiology; Humans; Models,
	Neurological; Neuronal Plasticity, physiology; Neurons, physiology;
	Seizures, physiopathology; Sleep, physiology; Synapses, physiology;
	Transcranial Magnetic Stimulation},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S0022-5193(11)00322-5},
  pmid = {21767551},
  timestamp = {2013.03.25},
  url = {http://dx.doi.org/10.1016/j.jtbi.2011.06.023}
}

@ARTICLE{Robinson_2007,
  author = {P. A. Robinson},
  title = {Visual gamma oscillations: waves, correlations, and other phenomena,
	including comparison with experimental data.},
  journal = {Biol. Cybern.},
  year = {2007},
  volume = {97},
  pages = {317--335},
  number = {4},
  month = {Oct},
  abstract = {Mean-field theory of brain dynamics is applied to explain the properties
	of gamma (> or approximately 30 Hz) oscillations of cortical activity
	often seen during vision experiments. It is shown that mm-scale patchy
	connections in the primary visual cortex can support collective gamma
	oscillations with the correct frequencies and spatial structure,
	even when driven by uncorrelated inputs. This occurs via resonances
	associated with the the periodic modulation of the network connections,
	rather than being due to single-cell properties alone. Near-resonant
	gamma waves are shown to obey the Schrödinger equation, which enables
	techniques and insights from quantum theory to be used in exploring
	these classical oscillations. Resulting predictions for gamma responses
	to stimuli account in a unified way for a wide range of experimental
	results, including why oscillations and zero-lag synchrony are associated,
	and variations in correlation functions with time delay, intercellular
	distance, and stimulus features. They also imply that gamma oscillations
	may enable a form of frequency multiplexing of neural signals. Most
	importantly, it is shown that correlations reproduce experimental
	results that show maximal correlations between cells that respond
	to related features, but little correlation with other cells, an
	effect that has been argued to be associated with segmentation of
	a scene into separate objects. Consistency with infill of missing
	contours and increase in response with length of bar-shaped stimuli
	are discussed. Background correlations expected in the absence of
	stimulation are also calculated and shown to be consistent in form
	with experimental measurements and similar to stimulus-induced correlations
	in structure. Finally, possible links of gamma instabilities to certain
	classes of photically induced seizures and visual hallucinations
	are discussed.},
  doi = {10.1007/s00422-007-0177-x},
  institution = {School of Physics, The University of Sydney, Sydney, NSW 2006, Australia.
	robinson@physics.usyd.edu.au},
  keywords = {Action Potentials, physiology; Algorithms; Animals; Biological Clocks,
	physiology; Computer Simulation; Electroencephalography; Evoked Potentials,
	physiology; Humans; Neurons, physiology; Pattern Recognition, Visual,
	physiology; Signal Processing, Computer-Assisted; Synaptic Transmission,
	physiology; Visual Cortex, physiology; Visual Pathways, physiology;
	Visual Perception, physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {17899164},
  timestamp = {2013.03.25},
  url = {http://dx.doi.org/10.1007/s00422-007-0177-x}
}

@ARTICLE{Robinson_2006,
  author = {P. A. Robinson and P. M. Drysdale and H. Van der Merwe and E. Kyriakou
	and M. K. Rigozzi and B. Germanoska and C. J. Rennie},
  title = {BOLD responses to stimuli: dependence on frequency, stimulus form,
	amplitude, and repetition rate.},
  journal = {Neuroimage},
  year = {2006},
  volume = {31},
  pages = {585--599},
  number = {2},
  month = {Jun},
  abstract = {A quantitative theory is developed for the relationship between stimulus
	and the resulting blood oxygen level-dependent (BOLD) functional
	MRI signal. The relationship of stimuli to neuronal activity during
	evoked responses is inferred from recent physiology-based quantitative
	modeling of evoked response potentials (ERPs). A hemodynamic model
	is then used to calculate the BOLD response to neuronal activity
	having the form of an impulse, a sinusoid, or an ERP-like damped
	sinusoid. Using the resulting equations, the BOLD response is analyzed
	for different forms, frequencies, and amplitudes of stimuli, in contrast
	with previous research, which has mostly concentrated on sustained
	stimuli. The BOLD frequency response is found to be closely linear
	in the parameter ranges of interest, with the form of a low-pass
	filter with a weak resonance at approximately 0.07 Hz. An improved
	BOLD impulse response is systematically obtained which includes initial
	dip and post-stimulus undershoot for some parameter ranges. It is
	found that the BOLD response depends strongly on the precise temporal
	course of the evoked neuronal activity, not just its peak value or
	typical amplitude. Indeed, for short stimuli, the linear BOLD response
	is closely proportional to the time-integrated activity change evoked
	by the stimulus, regardless of amplitude. It is concluded that there
	can be widely differing proportionalities between BOLD and peak activity,
	that this is the likely reason for the low level of correspondence
	seen experimentally between ERP sources and BOLD measurements and
	that non-BOLD measurements, such as ERPs, can be used to correct
	for this effect to obtain improved activity estimates. Finally, stimulus
	sequences that optimize the signal-to-noise ratio in event-related
	BOLD fMRI (efMRI) experiments are derived using the hemodynamic transfer
	function.},
  doi = {10.1016/j.neuroimage.2005.12.026},
  institution = {School of Physics, University of Sydney, NSW, 2006, Australia.},
  keywords = {Brain, anatomy /&/ histology/physiology/radionuclide imaging; Cerebrovascular
	Circulation; Evoked Potentials; Hemodynamics; Humans; Models, Neurological;
	Oxygen, blood; Positron-Emission Tomography},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S1053-8119(05)02574-7},
  pmid = {16466935},
  timestamp = {2013.02.18},
  url = {http://dx.doi.org/10.1016/j.neuroimage.2005.12.026}
}

@ARTICLE{Robinson_2012b,
  author = {P. A. Robinson and J. W. Kim},
  title = {Spike, rate, field, and hybrid methods for treating neuronal dynamics
	and interactions.},
  journal = {J Neurosci Methods},
  year = {2012},
  volume = {205},
  pages = {283--294},
  number = {2},
  month = {Apr},
  abstract = {Spike-, rate-, and field-based approaches to neural dynamics are adapted
	and hybridized to provide new methods of analyzing dynamics of single
	neurons and large neuronal systems, to elucidate the relationships
	and intermediate forms between these limiting cases, and to enable
	faster simulations with reduced memory requirements. At the single-neuron
	level, the new approaches involve reformulation of dynamics in synapses,
	dendrites, cell bodies, and axons to enable new types of analysis,
	longer numerical timesteps, and demonstration that rate-based methods
	can predict spike times. In multineuron systems, hybrids and intermediates
	between spike-based and field-based coupling between neurons are
	used to provide stepping stones between descriptions based on pairwise
	spike-based interactions between neurons and ones based on neural
	field-based interactions within and between populations, including
	arbitrary spatial structure and temporal delays in the connections
	in general. In particular, a new neuron-in-cell approach is introduced
	that is a hybrid between neural field theory and spiking-neuron models
	in analogy to particle-in-cell methods in plasma physics. This approach
	enables large speedups in computations while preserving spike shapes
	and times. Various approaches are illustrated numerically for specific
	cases.},
  doi = {10.1016/j.jneumeth.2012.01.018},
  institution = {School of Physics, The University of Sydney, Sydney, New South Wales
	2006, Australia. robinson@physics.usyd.edu.au},
  keywords = {Action Potentials, physiology; Algorithms; Models, Neurological; Models,
	Theoretical; Neural Networks (Computer); Neurons, physiology; Synapses,
	physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S0165-0270(12)00033-7},
  pmid = {22330795},
  timestamp = {2013.08.19},
  url = {http://dx.doi.org/10.1016/j.jneumeth.2012.01.018}
}

@ARTICLE{Robinson_2001b,
  author = {P. A. Robinson and P. N. Loxley and S. C. O'Connor and C. J. Rennie},
  title = {Modal analysis of corticothalamic dynamics, electroencephalographic
	spectra, and evoked potentials.},
  journal = {Phys Rev E Stat Nonlin Soft Matter Phys},
  year = {2001},
  volume = {63},
  pages = {041909},
  number = {4 Pt 1},
  month = {Apr},
  abstract = {The effects of cortical boundary conditions and resulting modal aspects
	of continuum corticothalamic electrodynamics are explored, including
	feedbacks. Dispersion relations, electroencephalographic spectra,
	and stimulus response functions are calculated from the underlying
	physiology, and the effects of discrete mode structure are determined.
	Conditions under which modal effects are important are obtained,
	along with estimates of the point at which modal series can be truncated,
	and the limit in which only a single globally uniform mode need be
	retained. It is found that for physiologically plausible parameters
	only the lowest cortical spatial eigenmode together with the set
	of next-lowest modes can produce distinct modal structure in spectra
	and response functions, and then only at frequencies where corticothalamic
	resonances reduce dissipation to the point where the spatial eigenmodes
	are weakly damped. The continuum limit is found to be a good approximation,
	except at very low frequencies and, under some circumstances, near
	the alpha resonance. It is argued that the major electroencephalographic
	rhythms result from corticothalamic feedback resonances, but that
	cortical modal effects can contribute to weak substructure in the
	alpha resonance. This mechanism is compared and contrasted with purely
	cortical and pacemaker-based alternatives and testable predictions
	are formulated to enable experimental discrimination between these
	possibilities.},
  institution = {School of Physics, University of Sydney, New South Wales 2006, Australia.
	robinson@physics.usyd.edu.au},
  keywords = {Analysis of Variance; Animals; Brain, pathology; Cerebral Cortex,
	pathology; Electroencephalography, methods; Evoked Potentials; Feedback,
	Physiological; Models, Neurological; Models, Statistical; Multivariate
	Analysis; Neurons, pathology; Synaptic Transmission; Thalamus, pathology;
	Vibration},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {11308879},
  timestamp = {2013.08.19}
}

@ARTICLE{Robinson_1998,
  author = {Peter A Robinson and Rennie, C. and Wright, J. and Bourke, P. D.},
  title = {Steady states and global dynamics of electrical activity in the cerebral
	cortex},
  journal = {Phys Rev E Stat Nonlin Soft Matter Phys},
  year = {1998},
  volume = {53},
  pages = {3557-3571},
  number = {3},
  abstract = {Steady states and global dynamics of electrical activity in the cerebral
	cortex are investigated within the
	
	framework of a recent continuum model. It is shown that for a particular
	physiologically realistic class of
	
	models, at most three steady states can occur, two of which are stable.
	The global dynamics of spatially
	
	uniform activity states is studied and it is shown that in a physiologically
	realistic class of models, the adiabatic
	
	dynamics is governed by a second-order differential equation equivalent
	to that for the motion of a Newtonian
	
	particle in a potential in the presence of friction. This result is
	used to derive a simplified dynamical equation
	
	in the friction-dominated limit. Solutions of these equations are
	compared with those of the full global dynam-
	
	ics equations and it is found that they are adequate for time scales
	longer than approximately 100 ms provided
	
	dendritic integration times are less than approximately 10 ms.},
  owner = {paula},
  timestamp = {2013.08.23}
}

@ARTICLE{Robinson_2002,
  author = {P. A. Robinson and C. J. Rennie and D. L. Rowe},
  title = {Dynamics of large-scale brain activity in normal arousal states and
	epileptic seizures.},
  journal = {Phys Rev E Stat Nonlin Soft Matter Phys},
  year = {2002},
  volume = {65},
  pages = {041924},
  number = {4 Pt 1},
  month = {Apr},
  abstract = {Links between electroencephalograms (EEGs) and underlying aspects
	of neurophysiology and anatomy are poorly understood. Here a nonlinear
	continuum model of large-scale brain electrical activity is used
	to analyze arousal states and their stability and nonlinear dynamics
	for physiologically realistic parameters. A simple ordered arousal
	sequence in a reduced parameter space is inferred and found to be
	consistent with experimentally determined parameters of waking states.
	Instabilities arise at spectral peaks of the major clinically observed
	EEG rhythms-mainly slow wave, delta, theta, alpha, and sleep spindle-with
	each instability zone lying near its most common experimental precursor
	arousal states in the reduced space. Theta, alpha, and spindle instabilities
	evolve toward low-dimensional nonlinear limit cycles that correspond
	closely to EEGs of petit mal seizures for theta instability, and
	grand mal seizures for the other types. Nonlinear stimulus-induced
	entrainment and seizures are also seen, EEG spectra and potentials
	evoked by stimuli are reproduced, and numerous other points of experimental
	agreement are found. Inverse modeling enables physiological parameters
	underlying observed EEGs to be determined by a new, noninvasive route.
	This model thus provides a single, powerful framework for quantitative
	understanding of a wide variety of brain phenomena.},
  institution = {Theoretical Physics Group and Center for Wave Physics, School of
	Physics, University of Sydney, New South Wales 2006, Australia.},
  keywords = {Adult; Arousal, physiology; Brain, metabolism/physiology/physiopathology;
	Cerebral Cortex, physiology/physiopathology; Electroencephalography;
	Epilepsy, Absence, physiopathology; Epilepsy, Tonic-Clonic, physiopathology;
	Epilepsy, physiopathology; Evoked Potentials, physiology; Humans;
	Models, Neurological; Nonlinear Dynamics; Thalamus, physiology/physiopathology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {12005890},
  timestamp = {2013.08.19}
}

@ARTICLE{Robinson_2004,
  author = {P. A. Robinson and C. J. Rennie and D. L. Rowe and S. C. O'Connor},
  title = {Estimation of multiscale neurophysiologic parameters by electroencephalographic
	means.},
  journal = {Hum. Brain Mapp.},
  year = {2004},
  volume = {23},
  pages = {53--72},
  number = {1},
  month = {Sep},
  abstract = {It is shown that new model-based electroencephalographic (EEG) methods
	can quantify neurophysiologic parameters that underlie EEG generation
	in ways that are complementary to and consistent with standard physiologic
	techniques. This is done by isolating parameter ranges that give
	good matches between model predictions and a variety of experimental
	EEG-related phenomena simultaneously. Resulting constraints range
	from the submicrometer synaptic level to length scales of tens of
	centimeters, and from timescales of around 1 ms to 1 s or more, and
	are found to be consistent with independent physiologic and anatomic
	measures. In the process, a new method of obtaining model parameters
	from the data is developed, including a Monte Carlo implementation
	for use when not all input data are available. Overall, the approaches
	used are complementary to other methods, constraining allowable parameter
	ranges in different ways and leading to much tighter constraints
	overall. EEG methods often provide the most restrictive individual
	constraints. This approach opens a new, noninvasive window on quantitative
	brain analysis, with the ability to monitor temporal changes, and
	the potential to map spatial variations. Unlike traditional phenomenologic
	quantitative EEG measures, the methods proposed here are based explicitly
	on physiology and anatomy.},
  doi = {10.1002/hbm.20032},
  institution = {School of Physics, University of Sydney, New South Wales, Australia.
	p.robinson@physics.usyd.edu.au},
  keywords = {Adult; Arousal, physiology; Brain Mapping, methods; Brain, anatomy
	/&/ histology/physiology; Electroencephalography, methods; Female;
	Humans; Male; Middle Aged; Models, Neurological; Monte Carlo Method;
	Neurophysiology, methods},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {15281141},
  timestamp = {2013.02.18},
  url = {http://dx.doi.org/10.1002/hbm.20032}
}

@ARTICLE{Robinson_2005,
  author = {P. A. Robinson and C. J. Rennie and D. L. Rowe and S. C. O'Connor
	and E. Gordon},
  title = {Multiscale brain modelling.},
  journal = {Philos. Trans. R. Soc. Lond. B. Biol. Sci.},
  year = {2005},
  volume = {360},
  pages = {1043--1050},
  number = {1457},
  month = {May},
  abstract = {A central difficulty of brain modelling is to span the range of spatio-temporal
	scales from synapses to the whole brain. This paper overviews results
	from a recent model of the generation of brain electrical activity
	that incorporates both basic microscopic neurophysiology and large-scale
	brain anatomy to predict brain electrical activity at scales from
	a few tenths of a millimetre to the whole brain. This model incorporates
	synaptic and dendritic dynamics, nonlinearity of the firing response,
	axonal propagation and corticocortical and corticothalamic pathways.
	Its relatively few parameters measure quantities such as synaptic
	strengths, corticothalamic delays, synaptic and dendritic time constants,
	and axonal ranges, and are all constrained by independent physiological
	measurements. It reproduces quantitative forms of electroencephalograms
	seen in various states of arousal, evoked response potentials, coherence
	functions, seizure dynamics and other phenomena. Fitting model predictions
	to experimental data enables underlying physiological parameters
	to be inferred, giving a new non-invasive window into brain function
	that complements slower, but finer-resolution, techniques such as
	fMRI. Because the parameters measure physiological quantities relating
	to multiple scales, and probe deep structures such as the thalamus,
	this will permit the testing of a range of hypotheses about vigilance,
	cognition, drug action and brain function. In addition, referencing
	to a standardized database of subjects adds strength and specificity
	to characterizations obtained.},
  doi = {10.1098/rstb.2005.1638},
  institution = {School of Physics, University of Sydney, NSW 2006, Australia. p.robinson@physics.usyd.edu.au},
  keywords = {Axons, physiology; Biophysical Phenomena; Biophysics; Brain Mapping,
	methods; Brain, anatomy /&/ histology/physiology; Dendrites, physiology;
	Electroencephalography, methods; Evoked Potentials, physiology; Humans;
	Magnetic Resonance Imaging, methods; Models, Neurological; Neural
	Pathways, physiology; Synapses, physiology; Synaptic Transmission,
	physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {Q746GHYMUVFH80EJ},
  pmid = {16087447},
  timestamp = {2013.02.18},
  url = {http://dx.doi.org/10.1098/rstb.2005.1638}
}

@ARTICLE{Robinson_2003,
  author = {P. A. Robinson and C. J. Rennie and D. L. Rowe and S. C. O'Connor
	and J. J. Wright and E. Gordon and R. W. Whitehouse},
  title = {Neurophysical modeling of brain dynamics.},
  journal = {Neuropsychopharmacology},
  year = {2003},
  volume = {28 Suppl 1},
  pages = {S74--S79},
  month = {Jul},
  abstract = {A recent neurophysical model of brain electrical activity is outlined
	and applied to EEG phenomena. It incorporates single-neuron physiology
	and the large-scale anatomy of corticocortical and corticothalamic
	pathways, including synaptic strengths, dendritic propagation, nonlinear
	firing responses, and axonal conduction. Small perturbations from
	steady states account for observed EEGs as functions of arousal.
	Evoked response potentials (ERPs), correlation, and coherence functions
	are also reproduced. Feedback via thalamic nuclei is critical in
	determining the forms of these quantities, the transition between
	sleep and waking, and stability against seizures. Many disorders
	correspond to significant changes in EEGs, which can potentially
	be quantified in terms of the underlying physiology using this theory.
	In the nonlinear regime, limit cycles are often seen, including a
	regime in which they have the characteristic petit mal 3 Hz spike-and-wave
	form.},
  doi = {10.1038/sj.npp.1300143},
  institution = {School of Physics, University of Sydney, NSW 2006, Australia. p.robinson@physics.usvd.edu.au},
  keywords = {Brain, physiology; Cerebral Cortex, physiology; Models, Neurological;
	Seizures, physiopathology; Thalamus, physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {1300143},
  pmid = {12827147},
  timestamp = {2013.02.18},
  url = {http://dx.doi.org/10.1038/sj.npp.1300143}
}

@ARTICLE{Robinson_2001a,
  author = {P. A. Robinson and C. J. Rennie and J. J. Wright and H. Bahramali
	and E. Gordon and D. L. Rowe},
  title = {Prediction of electroencephalographic spectra from neurophysiology.},
  journal = {Phys. Rev. E: Stat., Nonlinear, Soft Matter Phys.},
  year = {2001},
  volume = {63},
  pages = {021903},
  number = {2 Pt 1},
  month = {Feb},
  abstract = {A recent neurophysical model of propagation of electrical waves in
	the cortex is extended to include a physiologically motivated subcortical
	feedback loop via the thalamus. The electroencephalographic spectrum
	when the system is driven by white noise is then calculated analytically
	in terms of physiological parameters, including the effects of filtering
	of signals by the cerebrospinal fluid, skull, and scalp. The spectral
	power at low frequencies is found to vary as f(-1) when awake and
	f(-3) when asleep, with a breakpoint to a steeper power-law tail
	at frequencies above about 20 Hz in both cases; the f(-1) range concurs
	with recent magnetoencephalographic observations of such a regime.
	Parameter sensitivities are explored, enabling a model with fewer
	free parameters to be proposed, and showing that spectra predicted
	for physiologically reasonable parameter values strongly resemble
	those observed in the laboratory. Alpha and beta peaks seen near
	10 Hz and twice that frequency, respectively, in the relaxed wakeful
	state are generated via subcortical feedback in this model, thereby
	leading to predictions of their frequencies in terms of physiological
	parameters, and of correlations in their occurrence. Subcortical
	feedback is also predicted to be responsible for production of anticorrelated
	peaks in deep sleep states that correspond to the occurrence of theta
	rhythm at around half the alpha frequency and sleep spindles at 3/2
	times the alpha frequency. An additional positively correlated waking
	peak near three times the alpha frequency is also predicted and tentatively
	observed, as are two new types of sleep spindle near 5/2 and 7/2
	times the alpha frequency, and anticorrelated with alpha. These results
	provide a theoretical basis for the conventional division of EEG
	spectra into frequency bands, but imply that the exact bounds of
	these bands depend on the individual. Three types of potential instability
	are found: one at zero frequency, another in the theta band at around
	half the alpha frequency, and a third at the alpha frequency itself.},
  institution = {School of Physics, University of Sydney, New South Wales 2006, Australia.
	robinson@physics.usyd.edu.au},
  keywords = {Adult; Biophysical Phenomena; Biophysics; Cerebral Cortex, pathology;
	Electroencephalography, instrumentation/methods; Female; Humans;
	Neurons, physiology; Neurophysiology; Sleep; Sleep Stages; Statistics
	as Topic; Thalamus, pathology; Wakefulness},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {11308514},
  timestamp = {2013.02.18}
}

@ARTICLE{Robinson_1997,
  author = {Robinson, PA and Rennie, CJ and Wright, JJ},
  title = {Propagation and stability of waves of electrical activity in the
	cerebral cortex},
  journal = {Phys. Rev. E},
  year = {1997},
  volume = {56},
  pages = {826-840},
  keywords = {electrical activity},
  owner = {paula},
  timestamp = {2012.10.18}
}

@ARTICLE{Robinson_2009,
  author = {Simon Robinson and Gianpaolo Basso and Nicola Soldati and Uta Sailer
	and Jorge Jovicich and Lorenzo Bruzzone and Ilse Kryspin-Exner and
	Herbert Bauer and Ewald Moser},
  title = {A resting state network in the motor control circuit of the basal
	ganglia.},
  journal = {BMC Neurosci.},
  year = {2009},
  volume = {10},
  pages = {137},
  abstract = {In the absence of overt stimuli, the brain shows correlated fluctuations
	in functionally related brain regions. Approximately ten largely
	independent resting state networks (RSNs) showing this behaviour
	have been documented to date. Recent studies have reported the existence
	of an RSN in the basal ganglia - albeit inconsistently and without
	the means to interpret its function. Using two large study groups
	with different resting state conditions and MR protocols, the reproducibility
	of the network across subjects, behavioural conditions and acquisition
	parameters is assessed. Independent Component Analysis (ICA), combined
	with novel analyses of temporal features, is applied to establish
	the basis of signal fluctuations in the network and its relation
	to other RSNs. Reference to prior probabilistic diffusion tractography
	work is used to identify the basal ganglia circuit to which these
	fluctuations correspond.An RSN is identified in the basal ganglia
	and thalamus, comprising the pallidum, putamen, subthalamic nucleus
	and substantia nigra, with a projection also to the supplementary
	motor area. Participating nuclei and thalamo-cortical connection
	probabilities allow this network to be identified as the motor control
	circuit of the basal ganglia. The network was reproducibly identified
	across subjects, behavioural conditions (fixation, eyes closed),
	field strength and echo-planar imaging parameters. It shows a frequency
	peak at 0.025 +/- 0.007 Hz and is most similar in spectral composition
	to the Default Mode (DM), a network of regions that is more active
	at rest than during task processing. Frequency features allow the
	network to be classified as an RSN rather than a physiological artefact.
	Fluctuations in this RSN are correlated with those in the task-positive
	fronto-parietal network and anticorrelated with those in the DM,
	whose hemodynamic response it anticipates.Although the basal ganglia
	RSN has not been reported in most ICA-based studies using a similar
	methodology, we demonstrate that it is reproducible across subjects,
	common resting state conditions and imaging parameters, and show
	that it corresponds with the motor control circuit. This characterisation
	of the basal ganglia network opens a potential means to investigate
	the motor-related neuropathologies in which the basal ganglia are
	involved.},
  doi = {10.1186/1471-2202-10-137},
  institution = {Functional Neuroimaging Laboratory, Center for Mind/Brain Sciences,
	University of Trento, Trento, Italy. simon.robinson@meduniwien.ac.at},
  keywords = {Adult; Basal Ganglia, physiology; Brain Mapping; Cerebral Cortex,
	physiology; Female; Humans; Image Processing, Computer-Assisted;
	Magnetic Resonance Imaging; Male; Middle Aged; Nerve Net, physiology;
	Neural Pathways, physiology; Patient Selection; Thalamus, physiology},
  language = {eng},
  medline-pst = {epublish},
  owner = {paula},
  pii = {1471-2202-10-137},
  pmid = {19930640},
  timestamp = {2013.03.25},
  url = {http://dx.doi.org/10.1186/1471-2202-10-137}
}

@ARTICLE{Robinson_1996,
  author = {Robinson and Drysdale},
  title = {Phase Transition between Coherent and Incoherent Three-Wave Interactions.},
  journal = {Phys. Rev. Lett.},
  year = {1996},
  volume = {77},
  pages = {2698--2701},
  number = {13},
  month = {Sep},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {10062023},
  timestamp = {2013.02.18}
}

@ARTICLE{Roebroeck_2011,
  author = {Alard Roebroeck and Elia Formisano and Rainer Goebel},
  title = {The identification of interacting networks in the brain using fMRI:
	Model selection, causality and deconvolution.},
  journal = {Neuroimage},
  year = {2011},
  volume = {58},
  pages = {296--302},
  number = {2},
  month = {Sep},
  abstract = {Functional magnetic resonance imaging (fMRI) is increasingly used
	to study functional connectivity in large-scale brain networks that
	support cognitive and perceptual processes. We face serious conceptual,
	statistical and data analysis challenges when addressing the combinatorial
	explosion of possible interactions within high-dimensional fMRI data.
	Moreover, we need to know, and account for, the physiological mechanisms
	underlying our signals. We argue here that (i) model selection procedures
	for connectivity should include consideration of more than just a
	few brain structures, (ii) temporal precedence - and causality concepts
	based on it - are essential in dynamic models of connectivity and
	(iii) undoing the effect of hemodynamics on fMRI data (by deconvolution)
	can be an important tool. However, it is crucially dependent upon
	assumptions that need to be verified.},
  doi = {10.1016/j.neuroimage.2009.09.036},
  institution = {Department of Cognitive Neuroscience, Faculty of Psychology and Neuroscience,
	Maastricht University, Postbus 616, 6200MD Maastricht, The Netherlands.
	a.roebroeck@maastrichtuniversity.nl},
  keywords = {Brain, physiology; Causality; Cerebrovascular Circulation, physiology;
	Hemodynamics, physiology; Humans; Image Processing, Computer-Assisted,
	statistics /&/ numerical data; Magnetic Resonance Imaging, methods;
	Models, Neurological; Models, Statistical; Nerve Net, physiology;
	Neural Pathways, physiology; Stochastic Processes},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S1053-8119(09)01015-5},
  pmid = {19786106},
  timestamp = {2013.02.14},
  url = {http://dx.doi.org/10.1016/j.neuroimage.2009.09.036}
}

@ARTICLE{Roebroeck_2005,
  author = {Alard Roebroeck and Elia Formisano and Rainer Goebel},
  title = {Mapping directed influence over the brain using Granger causality
	and fMRI.},
  journal = {Neuroimage},
  year = {2005},
  volume = {25},
  pages = {230--242},
  number = {1},
  month = {Mar},
  abstract = {We propose Granger causality mapping (GCM) as an approach to explore
	directed influences between neuronal populations (effective connectivity)
	in fMRI data. The method does not rely on a priori specification
	of a model that contains pre-selected regions and connections between
	them. This distinguishes it from other fMRI effective connectivity
	approaches that aim at testing or contrasting specific hypotheses
	about neuronal interactions. Instead, GCM relies on the concept of
	Granger causality to define the existence and direction of influence
	from information in the data. Temporal precedence information is
	exploited to compute Granger causality maps that identify voxels
	that are sources or targets of directed influence for any selected
	region-of-interest. We investigated the method by simulations and
	by application to fMRI data of a complex visuomotor task. The presented
	exploratory approach of mapping influences between a region of interest
	and the rest of the brain can form a useful complement to existing
	models of effective connectivity.},
  doi = {10.1016/j.neuroimage.2004.11.017},
  institution = {Department of Cognitive Neuroscience, Faculty of Psychology, University
	of Maastricht, The Netherlands.},
  keywords = {Attention, physiology; Brain Mapping, methods; Cerebral Cortex, physiology;
	Computer Simulation; Dominance, Cerebral, physiology; Evoked Potentials,
	physiology; Humans; Image Enhancement; Image Processing, Computer-Assisted,
	statistics /&/ numerical data; Imaging, Three-Dimensional, statistics
	/&/ numerical data; Magnetic Resonance Imaging, statistics /&/ numerical
	data; Nerve Net, physiology; Oxygen, blood; Parietal Lobe, physiology;
	Pattern Recognition, Visual, physiology; Psychomotor Performance,
	physiology; Reaction Time, physiology; Regression Analysis},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S1053-8119(04)00668-8},
  pmid = {15734358},
  timestamp = {2013.02.14},
  url = {http://dx.doi.org/10.1016/j.neuroimage.2004.11.017}
}

@ARTICLE{Roebroeck_2008,
  author = {Alard Roebroeck and Ralf Galuske and Elia Formisano and Oriana Chiry
	and Hansjürgen Bratzke and Itamar Ronen and Dae-shik Kim and Rainer
	Goebel},
  title = {High-resolution diffusion tensor imaging and tractography of the
	human optic chiasm at 9.4 T.},
  journal = {Neuroimage},
  year = {2008},
  volume = {39},
  pages = {157--168},
  number = {1},
  month = {Jan},
  abstract = {The optic chiasm with its complex fiber micro-structure is a challenge
	for diffusion tensor models and tractography methods. Likewise, it
	is an ideal candidate for evaluation of diffusion tensor imaging
	tractography approaches in resolving inter-regional connectivity
	because the macroscopic connectivity of the optic chiasm is well
	known. Here, high-resolution (156 microm in-plane) diffusion tensor
	imaging of the human optic chiasm was performed ex vivo at ultra-high
	field (9.4 T). Estimated diffusion tensors at this high resolution
	were able to capture complex fiber configurations such as sharp curves,
	and convergence and divergence of tracts, but were unable to resolve
	directions at sites of crossing fibers. Despite the complex microstructure
	of the fiber paths through the optic chiasm, all known connections
	could be tracked by a line propagation algorithm. However, fibers
	crossing from the optic nerve to the contralateral tract were heavily
	underrepresented, whereas ipsilateral nerve-to-tract connections,
	as well as tract-to-tract connections, were overrepresented, and
	erroneous nerve-to-nerve connections were tracked. The effects of
	spatial resolution and the varying degrees of partial volume averaging
	of complex fiber architecture on the performance of these methods
	could be investigated. Errors made by the tractography algorithm
	at high resolution were shown to increase at lower resolutions closer
	to those used in vivo. This study shows that increases in resolution,
	made possible by higher field strengths, improve the accuracy of
	DTI-based tractography. More generally, post-mortem investigation
	of fixed tissue samples with diffusion imaging at high field strengths
	is important in the evaluation of MR-based diffusion models and tractography
	algorithms.},
  doi = {10.1016/j.neuroimage.2007.08.015},
  institution = {Department of Cognitive Neuroscience, Faculty of Psychology, Maastricht
	University, The Netherlands. a.roebroeck@psychology.unimaas.nl},
  keywords = {Adult; Algorithms; Diffusion Magnetic Resonance Imaging, methods;
	Female; Humans; Image Enhancement, methods; Image Interpretation,
	Computer-Assisted, methods; Male; Nerve Fibers, Myelinated, ultrastructure;
	Optic Chiasm, cytology; Reproducibility of Results; Sensitivity and
	Specificity; Visual Pathways, cytology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S1053-8119(07)00729-X},
  pmid = {17936015},
  timestamp = {2013.02.14},
  url = {http://dx.doi.org/10.1016/j.neuroimage.2007.08.015}
}

@ARTICLE{vanRotterdam_1982,
  author = {A. van Rotterdam and F. H. Lopes da Silva and J. van den Ende and
	M. A. Viergever and A. J. Hermans},
  title = {A model of the spatial-temporal characteristics of the alpha rhythm.},
  journal = {Bull Math Biol},
  year = {1982},
  volume = {44},
  pages = {283--305},
  number = {2},
  keywords = {Action Potentials; Animals; Cerebral Cortex, physiology; Interneurons,
	physiology; Models, Biological; Nerve Fibers, anatomy /&/ histology;
	Neurons, anatomy /&/ histology/physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {7074252},
  timestamp = {2013.08.19}
}

@ARTICLE{Rowe_2004,
  author = {Donald L Rowe and Peter A Robinson and Christopher J Rennie},
  title = {Estimation of neurophysiological parameters from the waking EEG using
	a biophysical model of brain dynamics.},
  journal = {J. Theor. Biol.},
  year = {2004},
  volume = {231},
  pages = {413--433},
  number = {3},
  month = {Dec},
  abstract = {This paper presents the results from using electroencephalographic
	(EEG) data to estimate the values of key neurophysiological parameters
	using a detailed biophysical model of brain activity. The model incorporates
	spatial and temporal aspects of cortical function including axonal
	transmission delays, synapto-dendritic rates, range-dependent connectivities,
	excitatory and inhibitory neural populations, and intrathalamic,
	intracortical, corticocortical and corticothalamic pathways. Parameter
	estimates were obtained by fitting the model's theoretical spectrum
	to EEG spectra from each of 100 healthy human subjects. Statistical
	analysis was used to infer significant parameter variations occurring
	between eyes-closed and eyes-open states, and a correlation matrix
	was used to investigate links between the parameter variations and
	traditional measures of quantitative EEG (qEEG). Accurate fits to
	all experimental spectra were observed, and both inter-subject and
	between-state variability were accounted for by the variance in the
	fitted biophysical parameters, which were in turn consistent with
	known independent experimental and theoretical estimates. These values
	thus provide physiological information regarding the state. transitions
	(eyes-closed vs. eyes-open) and phenomena including cortical idling
	and alpha desynchronization. The parameters are also consistent with
	traditional qEEG, but are more informative, since they provide links
	to underlying physiological processes. To our knowledge, this is
	the first study where a detailed biophysical model of the brain is
	used to estimate neurophysiological parameters underlying the transitions
	in a broad range (0.25-50 Hz) of EEG spectra obtained from a large
	set of human data.},
  doi = {10.1016/j.jtbi.2004.07.004},
  institution = {School of Physics, University of Sydney, New South Wales 2006, Australia.
	drowe@physics.usyd.edu.au},
  keywords = {Awareness; Biophysical Phenomena; Biophysics; Brain, physiology; Electroencephalography;
	Humans; Models, Neurological},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S0022-5193(04)00325-X},
  pmid = {15501472},
  timestamp = {2013.02.18},
  url = {http://dx.doi.org/10.1016/j.jtbi.2004.07.004}
}

@ARTICLE{Rowe2004,
  author = {Donald L Rowe and Peter A Robinson and Christopher J Rennie and Anthony
	W Harris and Kim L Felmingham and Ilario L Lazzaro and Evian Gordon},
  title = {Neurophysiologically-based mean-field modelling of tonic cortical
	activity in post-traumatic stress disorder (PTSD), schizophrenia,
	first episode schizophrenia and attention deficit hyperactivity disorder
	(ADHD).},
  journal = {J. Integr. Neurosci.},
  year = {2004},
  volume = {3},
  pages = {453--487},
  number = {4},
  month = {Dec},
  abstract = {A recently developed quantitative model of cortical activity is used
	that permits data comparison with experiment using a quantitative
	and standardized means. The model incorporates properties of neurophysiology
	including axonal transmission delays, synaptodendritic rates, range-dependent
	connectivities, excitatory and inhibitory neural populations, and
	intrathalamic, intracortical, corticocortical and corticothalamic
	pathways. This study tests the ability of the model to determine
	unique physiological properties in a number of different data sets
	varying in mean age and pathology. The model is used to fit individual
	electroencephalographic (EEG) spectra from post-traumatic stress
	disorder (PTSD), schizophrenia, first episode schizophrenia (FESz),
	attention deficit hyperactivity disorder (ADHD), and their age/sex
	matched controls. The results demonstrate that the model is able
	to distinguish each group in terms of a unique cluster of abnormal
	parameter deviations. The abnormal physiology inferred from these
	parameters is also consistent with known theoretical and experimental
	findings from each disorder. The model is also found to be sensitive
	to the effects of medication in the schizophrenia and FESz group,
	further supporting the validity of the model.},
  institution = {School of Physics, University of Sydney, NSW 2006, Australia. donrowe@med.usyd.edu.au},
  keywords = {Adolescent; Adult; Attention Deficit Disorder with Hyperactivity,
	physiopathology; Cerebral Cortex, physiology; Chi-Square Distribution;
	Child; Epilepsy, Post-Traumatic, physiopathology; Female; Humans;
	Male; Middle Aged; Models, Neurological; Schizophrenia, physiopathology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S0219635204000592},
  pmid = {15657979},
  timestamp = {2013.03.25}
}

@ARTICLE{Roy_2013,
  author = {Dipanjan Roy and Viktor Jirsa},
  title = {Inferring network properties of cortical neurons with synaptic coupling
	and parameter dispersion.},
  journal = {Front. Comput. Neurosci.},
  year = {2013},
  volume = {7},
  pages = {20},
  abstract = {Computational models at different space-time scales allow us to understand
	the fundamental mechanisms that govern neural processes and relate
	uniquely these processes to neuroscience data. In this work, we propose
	a novel neurocomputational unit (a mesoscopic model which tell us
	about the interaction between local cortical nodes in a large scale
	neural mass model) of bursters that qualitatively captures the complex
	dynamics exhibited by a full network of parabolic bursting neurons.
	We observe that the temporal dynamics and fluctuation of mean synaptic
	action term exhibits a high degree of correlation with the spike/burst
	activity of our population. With heterogeneity in the applied drive
	and mean synaptic coupling derived from fast excitatory synapse approximations
	we observe long term behavior in our population dynamics such as
	partial oscillations, incoherence, and synchrony. In order to understand
	the origin of multistability at the population level as a function
	of mean synaptic coupling and heterogeneity in the firing rate threshold
	we employ a simple generative model for parabolic bursting recently
	proposed by Ghosh et al. (2009). Further, we use here a mean coupling
	formulated for fast spiking neurons for our analysis of generic model.
	Stability analysis of this mean field network allow us to identify
	all the relevant network states found in the detailed biophysical
	model. We derive here analytically several boundary solutions, a
	result which holds for any number of spikes per burst. These findings
	illustrate the role of oscillations occurring at slow time scales
	(bursts) on the global behavior of the network.},
  doi = {10.3389/fncom.2013.00020},
  institution = {Theoretical Neuroscience Group, Faculté de Médecine, Institut de
	Neurosciences des Systèmes, Inserm UMR1106, Aix-Marseille Université
	Marseille, France ; Bernstein Center for Computational Neuroscience
	Berlin, Germany ; Department of Software Engineering and Theoretical
	Computer Science, Technische Universität Berlin Berlin, Germany.},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {23533147},
  timestamp = {2013.04.17},
  url = {http://dx.doi.org/10.3389/fncom.2013.00020}
}

@ARTICLE{Rubin_2009,
  author = {Jonathan E Rubin and Natalia A Shevtsova and G. Bard Ermentrout and
	Jeffrey C Smith and Ilya A Rybak},
  title = {Multiple rhythmic states in a model of the respiratory central pattern
	generator.},
  journal = {J Neurophysiol},
  year = {2009},
  volume = {101},
  pages = {2146--2165},
  number = {4},
  month = {Apr},
  abstract = {The three-phase respiratory pattern observed during normal breathing
	changes with alterations in metabolic or physiological conditions.
	A recent study using in situ perfused rat brain preparations demonstrated
	a reorganization of the respiratory pattern with sequential reduction
	of the brain stem respiratory network. Specifically, with removal
	of the pons, the normal three-phase pattern transformed to a two-phase
	inspiratory-expiratory pattern and, with more caudal transections,
	to one-phase, intrinsically generated inspiratory oscillations. A
	minimal neural network proposed to reproduce these transformations
	includes 1) a ringlike mutually inhibitory network composed of the
	postinspiratory, augmenting expiratory, and early-inspiratory neurons
	and 2) an excitatory preinspiratory neuron, with persistent sodium
	current (I(NaP))-dependent intrinsic bursting properties, that dynamically
	participates in the expiratory-inspiratory phase transition and inspiratory
	phase generation. We used activity-based single-neuron models and
	applied numerical simulations, bifurcation methods, and fast-slow
	decomposition to describe the behavior of this network in the functional
	states corresponding to the three-, two-, and one-phase oscillatory
	regimes, as well as to analyze the transitions between states and
	between respiratory phases within each state. We demonstrate that,
	although I(NaP) is not necessary for the generation of three- and
	two-phase oscillations, it contributes to control of the oscillation
	period in each state. We also show that the transitions between states
	can be produced by progressive changes of drives to particular neurons
	and proceed through intermediate regimes, featuring high-amplitude
	late-expiratory and biphasic-expiratory activities or ectopic burst
	generation. Our results provide important insights for understanding
	the state-dependent mechanisms for respiratory rhythm generation
	and control.},
  doi = {10.1152/jn.90958.2008},
  institution = {Dept. of Mathematics, Univ. of Pittsburgh, Pittsburgh, PA, USA. rubin@math.pitt.edu},
  keywords = {Animals; Computer Simulation; Models, Neurological; Nerve Net, physiology;
	Neural Inhibition, physiology; Neurons, classification/physiology;
	Nonlinear Dynamics; Periodicity; Respiratory Center, cytology; Respiratory
	Mechanics, physiology; Respiratory System},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {90958.2008},
  pmid = {19193773},
  timestamp = {2013.09.04},
  url = {http://dx.doi.org/10.1152/jn.90958.2008}
}

@ARTICLE{Rubinov_2011a,
  author = {Mikail Rubinov and Olaf Sporns},
  title = {Weight-conserving characterization of complex functional brain networks.},
  journal = {Neuroimage},
  year = {2011},
  volume = {56},
  pages = {2068--2079},
  number = {4},
  month = {Jun},
  abstract = {Complex functional brain networks are large networks of brain regions
	and functional brain connections. Statistical characterizations of
	these networks aim to quantify global and local properties of brain
	activity with a small number of network measures. Important functional
	network measures include measures of modularity (measures of the
	goodness with which a network is optimally partitioned into functional
	subgroups) and measures of centrality (measures of the functional
	influence of individual brain regions). Characterizations of functional
	networks are increasing in popularity, but are associated with several
	important methodological problems. These problems include the inability
	to characterize densely connected and weighted functional networks,
	the neglect of degenerate topologically distinct high-modularity
	partitions of these networks, and the absence of a network null model
	for testing hypotheses of association between observed nontrivial
	network properties and simple weighted connectivity properties. In
	this study we describe a set of methods to overcome these problems.
	Specifically, we generalize measures of modularity and centrality
	to fully connected and weighted complex networks, describe the detection
	of degenerate high-modularity partitions of these networks, and introduce
	a weighted-connectivity null model of these networks. We illustrate
	our methods by demonstrating degenerate high-modularity partitions
	and strong correlations between two complementary measures of centrality
	in resting-state functional magnetic resonance imaging (MRI) networks
	from the 1000 Functional Connectomes Project, an open-access repository
	of resting-state functional MRI datasets. Our methods may allow more
	sound and reliable characterizations and comparisons of functional
	brain networks across conditions and subjects.},
  doi = {10.1016/j.neuroimage.2011.03.069},
  institution = {Black Dog Institute and School of Psychiatry, University of New South
	Wales, Sydney, Australia. m.rubinov@student.unsw.edu.au},
  keywords = {Algorithms; Brain Mapping, methods; Brain, physiology; Humans; Image
	Interpretation, Computer-Assisted, methods; Magnetic Resonance Imaging;
	Models, Neurological; Nerve Net, physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S1053-8119(11)00348-X},
  pmid = {21459148},
  timestamp = {2012.12.26},
  url = {http://dx.doi.org/10.1016/j.neuroimage.2011.03.069}
}

@ARTICLE{Rubinov_2010,
  author = {Mikail Rubinov and Olaf Sporns},
  title = {Complex network measures of brain connectivity: uses and interpretations.},
  journal = {Neuroimage},
  year = {2010},
  volume = {52},
  pages = {1059--1069},
  number = {3},
  month = {Sep},
  abstract = {Brain connectivity datasets comprise networks of brain regions connected
	by anatomical tracts or by functional associations. Complex network
	analysis-a new multidisciplinary approach to the study of complex
	systems-aims to characterize these brain networks with a small number
	of neurobiologically meaningful and easily computable measures. In
	this article, we discuss construction of brain networks from connectivity
	data and describe the most commonly used network measures of structural
	and functional connectivity. We describe measures that variously
	detect functional integration and segregation, quantify centrality
	of individual brain regions or pathways, characterize patterns of
	local anatomical circuitry, and test resilience of networks to insult.
	We discuss the issues surrounding comparison of structural and functional
	network connectivity, as well as comparison of networks across subjects.
	Finally, we describe a Matlab toolbox (http://www.brain-connectivity-toolbox.net)
	accompanying this article and containing a collection of complex
	network measures and large-scale neuroanatomical connectivity datasets.},
  doi = {10.1016/j.neuroimage.2009.10.003},
  institution = {Black Dog Institute and School of Psychiatry, University of New South
	Wales, Sydney, Australia.},
  keywords = {Brain, physiology; Models, Neurological; Nerve Net, physiology; Neural
	Networks (Computer)},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S1053-8119(09)01074-X},
  pmid = {19819337},
  timestamp = {2012.12.26},
  url = {http://dx.doi.org/10.1016/j.neuroimage.2009.10.003}
}

@ARTICLE{Rubinov_2009,
  author = {Mikail Rubinov and Olaf Sporns and Cees van Leeuwen and Michael Breakspear},
  title = {Symbiotic relationship between brain structure and dynamics.},
  journal = {BMC Neurosci.},
  year = {2009},
  volume = {10},
  pages = {55},
  abstract = {Brain structure and dynamics are interdependent through processes
	such as activity-dependent neuroplasticity. In this study, we aim
	to theoretically examine this interdependence in a model of spontaneous
	cortical activity. To this end, we simulate spontaneous brain dynamics
	on structural connectivity networks, using coupled nonlinear maps.
	On slow time scales structural connectivity is gradually adjusted
	towards the resulting functional patterns via an unsupervised, activity-dependent
	rewiring rule. The present model has been previously shown to generate
	cortical-like, modular small-world structural topology from initially
	random connectivity. We provide further biophysical justification
	for this model and quantitatively characterize the relationship between
	structure, function and dynamics that accompanies the ensuing self-organization.We
	show that coupled chaotic dynamics generate ordered and modular functional
	patterns, even on a random underlying structural connectivity. Consequently,
	structural connectivity becomes more modular as it rewires towards
	these functional patterns. Functional networks reflect the underlying
	structural networks on slow time scales, but significantly less so
	on faster time scales. In spite of ordered functional topology, structural
	networks remain robustly interconnected--and therefore small-world--due
	to the presence of central, inter-modular hub nodes. The noisy dynamics
	of these hubs enable them to persist despite ongoing rewiring and
	despite their comparative absence in functional networks.Our results
	outline a theoretical mechanism by which brain dynamics may facilitate
	neuroanatomical self-organization. We find time scale dependent differences
	between structural and functional networks. These differences are
	likely to arise from the distinct dynamics of central structural
	nodes.},
  doi = {10.1186/1471-2202-10-55},
  institution = {Black Dog Institute and School of Psychiatry, University of New South
	Wales, Sydney, Australia. m.rubinov@student.unsw.edu.au},
  keywords = {Animals; Brain Mapping; Brain, anatomy /&/ histology/physiology; Computer
	Simulation; Humans; Models, Neurological; Neural Networks (Computer);
	Neural Pathways, physiology; Neuronal Plasticity, physiology; Nonlinear
	Dynamics; Symbiosis, physiology},
  language = {eng},
  medline-pst = {epublish},
  owner = {paula},
  pii = {1471-2202-10-55},
  pmid = {19486538},
  timestamp = {2012.12.26},
  url = {http://dx.doi.org/10.1186/1471-2202-10-55}
}

@ARTICLE{Rubinov_2011,
  author = {Mikail Rubinov and Olaf Sporns and Jean-Philippe Thivierge and Michael
	Breakspear},
  title = {Neurobiologically realistic determinants of self-organized criticality
	in networks of spiking neurons.},
  journal = {PLoS Comput. Biol.},
  year = {2011},
  volume = {7},
  pages = {e1002038},
  number = {6},
  month = {Jun},
  abstract = {Self-organized criticality refers to the spontaneous emergence of
	self-similar dynamics in complex systems poised between order and
	randomness. The presence of self-organized critical dynamics in the
	brain is theoretically appealing and is supported by recent neurophysiological
	studies. Despite this, the neurobiological determinants of these
	dynamics have not been previously sought. Here, we systematically
	examined the influence of such determinants in hierarchically modular
	networks of leaky integrate-and-fire neurons with spike-timing-dependent
	synaptic plasticity and axonal conduction delays. We characterized
	emergent dynamics in our networks by distributions of active neuronal
	ensemble modules (neuronal avalanches) and rigorously assessed these
	distributions for power-law scaling. We found that spike-timing-dependent
	synaptic plasticity enabled a rapid phase transition from random
	subcritical dynamics to ordered supercritical dynamics. Importantly,
	modular connectivity and low wiring cost broadened this transition,
	and enabled a regime indicative of self-organized criticality. The
	regime only occurred when modular connectivity, low wiring cost and
	synaptic plasticity were simultaneously present, and the regime was
	most evident when between-module connection density scaled as a power-law.
	The regime was robust to variations in other neurobiologically relevant
	parameters and favored systems with low external drive and strong
	internal interactions. Increases in system size and connectivity
	facilitated internal interactions, permitting reductions in external
	drive and facilitating convergence of postsynaptic-response magnitude
	and synaptic-plasticity learning rate parameter values towards neurobiologically
	realistic levels. We hence infer a novel association between self-organized
	critical neuronal dynamics and several neurobiologically realistic
	features of structural connectivity. The central role of these features
	in our model may reflect their importance for neuronal information
	processing.},
  doi = {10.1371/journal.pcbi.1002038},
  institution = {Black Dog Institute and School of Psychiatry, University of New South
	Wales, Sydney, Australia. m.rubinov@student.unsw.edu.au},
  keywords = {Action Potentials, physiology; Algorithms; Cluster Analysis; Humans;
	Models, Neurological; Nerve Net, physiology; Neuronal Plasticity;
	Neurons, physiology; Synapses, physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {PCOMPBIOL-D-10-00059},
  pmid = {21673863},
  timestamp = {2012.12.26},
  url = {http://dx.doi.org/10.1371/journal.pcbi.1002038}
}

@ARTICLE{Sanabria-Diaz2010,
  author = {Gretel Sanabria-Diaz and Lester Melie-García and Yasser Iturria-Medina
	and Yasser Alemán-Gómez and Gertrudis Hernández-González and Lourdes
	Valdés-Urrutia and Lídice Galán and Pedro Valdés-Sosa},
  title = {Surface area and cortical thickness descriptors reveal different
	attributes of the structural human brain networks.},
  journal = {Neuroimage},
  year = {2010},
  volume = {50},
  pages = {1497--1510},
  number = {4},
  month = {May},
  abstract = {Recently, a related morphometry-based connection concept has been
	introduced using local mean cortical thickness and volume to study
	the underlying complex architecture of the brain networks. In this
	article, the surface area is employed as a morphometric descriptor
	to study the concurrent changes between brain structures and to build
	binarized connectivity graphs. The statistical similarity in surface
	area between pair of regions was measured by computing the partial
	correlation coefficient across 186 normal subjects of the Cuban Human
	Brain Mapping Project. We demonstrated that connectivity matrices
	obtained follow a small-world behavior for two different parcellations
	of the brain gray matter. The properties of the connectivity matrices
	were compared to the matrices obtained using the mean cortical thickness
	for the same cortical parcellations. The topology of the cortical
	thickness and surface area networks were statistically different,
	demonstrating that both capture distinct properties of the interaction
	or different aspects of the same interaction (mechanical, anatomical,
	chemical, etc.) between brain structures. This finding could be explained
	by the fact that each descriptor is driven by distinct cellular mechanisms
	as result of a distinct genetic origin. To our knowledge, this is
	the first time that surface area is used to study the morphological
	connectivity of brain networks.},
  doi = {10.1016/j.neuroimage.2010.01.028},
  institution = {Clinical Neuroimaging Department, Cuban Neuroscience Center, Cuba.},
  keywords = {Adolescent; Adult; Aged; Brain Mapping; Brain, anatomy /&/ histology;
	Cerebral Cortex, anatomy /&/ histology; Cluster Analysis; Corpus
	Callosum, anatomy /&/ histology; Cuba; Female; Humans; Image Processing,
	Computer-Assisted, methods; Magnetic Resonance Imaging, methods;
	Male; Middle Aged; Nerve Fibers, Unmyelinated; Neural Pathways, anatomy
	/&/ histology; Organ Size; Young Adult},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S1053-8119(10)00048-0},
  pmid = {20083210},
  timestamp = {2013.07.04},
  url = {http://dx.doi.org/10.1016/j.neuroimage.2010.01.028}
}

@ARTICLE{Sanz-Leon_2013,
  author = {Paula Sanz-Leon and Stuart A Knock and M. Marmaduke Woodman and Lia
	Domide and Jochen Mersmann and Anthony R McIntosh and Viktor Jirsa},
  title = {The Virtual Brain: a simulator of primate brain network dynamics.},
  journal = {Front Neuroinform},
  year = {2013},
  volume = {7},
  pages = {10},
  abstract = {We present The Virtual Brain (TVB), a neuroinformatics platform for
	full brain network simulations using biologically realistic connectivity.
	This simulation environment enables the model-based inference of
	neurophysiological mechanisms across different brain scales that
	underlie the generation of macroscopic neuroimaging signals including
	functional MRI (fMRI), EEG and MEG. Researchers from different backgrounds
	can benefit from an integrative software platform including a supporting
	framework for data management (generation, organization, storage,
	integration and sharing) and a simulation core written in Python.
	TVB allows the reproduction and evaluation of personalized configurations
	of the brain by using individual subject data. This personalization
	facilitates an exploration of the consequences of pathological changes
	in the system, permitting to investigate potential ways to counteract
	such unfavorable processes. The architecture of TVB supports interaction
	with MATLAB packages, for example, the well known Brain Connectivity
	Toolbox. TVB can be used in a client-server configuration, such that
	it can be remotely accessed through the Internet thanks to its web-based
	HTML5, JS, and WebGL graphical user interface. TVB is also accessible
	as a standalone cross-platform Python library and application, and
	users can interact with the scientific core through the scripting
	interface IDLE, enabling easy modeling, development and debugging
	of the scientific kernel. This second interface makes TVB extensible
	by combining it with other libraries and modules developed by the
	Python scientific community. In this article, we describe the theoretical
	background and foundations that led to the development of TVB, the
	architecture and features of its major software components as well
	as potential neuroscience applications.},
  doi = {10.3389/fninf.2013.00010},
  institution = {Institut de Neurosciences des Systèmes, Aix Marseille Université
	Marseille, France.},
  language = {eng},
  medline-pst = {epublish},
  owner = {paula},
  pmid = {23781198},
  timestamp = {2013.07.04},
  url = {http://dx.doi.org/10.3389/fninf.2013.00010}
}

@ARTICLE{Sarvas_1987,
  author = {Sarvas, J},
  title = {Basic mathematical and electromagnetic concepts of the biomagnetic
	inverse problems.},
  journal = {Phys. Med. Biol.},
  year = {1987},
  volume = {32},
  pages = {11–22},
  number = {1},
  month = {January},
  owner = {paula},
  timestamp = {2012.10.26}
}

@ARTICLE{Schneider_1969,
  author = {G. E. Schneider},
  title = {Two visual systems.},
  journal = {Science},
  year = {1969},
  volume = {163},
  pages = {895--902},
  number = {3870},
  month = {Feb},
  keywords = {APPLICATION, Animals; Cerebral Cortex, physiology; Cricetinae; Discrimination
	(Psychology); Orientation; Tectum Mesencephali, physiology; Vision,
	Ocular; Visual Cortex, physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {5763873},
  timestamp = {2013.02.11}
}

@ARTICLE{Schulz_2004,
  author = {Schulz, M and Chau, W and Graham, SJ and McIntosh, AR and Ross, B
	and Ishi, R and Pantev, C},
  title = {An integrative MEG-fMRI study of the primary somatosensory cortex
	using cross-modal correspondence analysis},
  journal = {Neuroimage},
  year = {2004},
  volume = {22},
  pages = {120-133},
  number = {1},
  owner = {paula},
  timestamp = {2012.10.18}
}

@ARTICLE{Seehaus_2013,
  author = {Arne K Seehaus and Alard Roebroeck and Oriana Chiry and Dae-Shik
	Kim and Itamar Ronen and Hansjürgen Bratzke and Rainer Goebel and
	Ralf A W Galuske},
  title = {Histological Validation of DW-MRI Tractography in Human Postmortem
	Tissue.},
  journal = {Cereb. Cortex},
  year = {2013},
  volume = {23},
  pages = {442--450},
  number = {2},
  month = {Feb},
  abstract = {Despite several previous attempts, histological validation of diffusion-weighted
	magnetic resonance imaging (DW-MRI)-based tractography as true axonal
	fiber pathways remains difficult. In the present study, we establish
	a method to compare histological and tractography data precisely
	enough for statements on the level of single tractography pathways.
	To this end, we used carbocyanine dyes to trace connections in human
	postmortem tissue and aligned them to high-resolution DW-MRI of the
	same tissue processed within the diffusion tensor imaging (DTI) formalism.
	We provide robust definitions of sensitivity (true positives) and
	specificity (true negatives) for DTI tractography and characterize
	tractography paths in terms of receiver operating characteristics.
	With sensitivity and specificity rates of approximately 80\%, we
	could show a clear correspondence between histological and inferred
	tracts. Furthermore, we investigated the effect of fractional anisotropy
	(FA) thresholds for the tractography and identified FA values between
	0.02 and 0.08 as optimal in our study. Last, we validated the course
	of entire tractography curves to move beyond correctness determination
	based on pairs of single points on a tract. Thus, histological techniques,
	in conjunction with alignment and processing tools, may serve as
	an important validation method of DW-MRI on the level of inferred
	tractography projections between brain areas.},
  doi = {10.1093/cercor/bhs036},
  institution = {Department of Biology, Technische Universität Darmstadt, 64287 Darmstadt,
	Germany.},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {bhs036},
  pmid = {22345356},
  timestamp = {2013.02.14},
  url = {http://dx.doi.org/10.1093/cercor/bhs036}
}

@ARTICLE{Senden_2012,
  author = {Mario Senden and Rainer Goebel and Gustavo Deco},
  title = {Structural connectivity allows for multi-threading during rest: the
	structure of the cortex leads to efficient alternation between resting
	state exploratory behavior and default mode processing.},
  journal = {Neuroimage},
  year = {2012},
  volume = {60},
  pages = {2274--2284},
  number = {4},
  month = {May},
  abstract = {Despite the absence of stimulation or task conditions the cortex exhibits
	highly structured spatio-temporal activity patterns. These patterns
	are known as resting state networks (RSNs) and emerge as low-frequency
	fluctuations (<0.1 Hz) observed in the fMRI signal of human subjects
	during rest. We are interested in the relationship between structural
	connectivity of the cortex and the fluctuations exhibited during
	resting conditions. We are especially interested in the effect of
	degree of connectivity on resting state dynamics as the default mode
	network (DMN) is highly connected. We find in experimental resting
	fMRI data that the DMN is the functional network that is most frequently
	active and for the longest time. In large-scale computational simulations
	of the cortex based on the corresponding underlying DTI/DSI based
	neuroanatomical connectivity matrix, we additionally find a strong
	correlation between the mean degree of functional networks and the
	proportion of time they are active. By artificially modifying different
	types of neuroanatomical connectivity matrices in the model, we were
	able to demonstrate that only models based on structural connectivity
	containing hubs give rise to this relationship. We conclude that,
	during rest, the cortex alternates efficiently between explorations
	of its externally oriented functional repertoire and internally oriented
	processing as a consequence of the DMN's high degree of connectivity.},
  doi = {10.1016/j.neuroimage.2012.02.061},
  institution = {Department of Cognitive Neuroscience, Faculty of Psychology and Neuroscience,
	Maastricht University, 6201BC Maastricht, The Netherlands. mario.senden@maastrichtuniversity.nl},
  keywords = {Cerebral Cortex, physiology; Exploratory Behavior, physiology; Humans;
	Models, Neurological; Neural Networks (Computer); Neural Pathways,
	physiology; Rest, physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S1053-8119(12)00239-X},
  pmid = {22394674},
  timestamp = {2012.11.14},
  url = {http://dx.doi.org/10.1016/j.neuroimage.2012.02.061}
}

@ARTICLE{Shattuck_2008,
  author = {David W Shattuck and Mubeena Mirza and Vitria Adisetiyo and Cornelius
	Hojatkashani and Georges Salamon and Katherine L Narr and Russell
	A Poldrack and Robert M Bilder and Arthur W Toga},
  title = {Construction of a 3D probabilistic atlas of human cortical structures.},
  journal = {Neuroimage},
  year = {2008},
  volume = {39},
  pages = {1064--1080},
  number = {3},
  month = {Feb},
  abstract = {We describe the construction of a digital brain atlas composed of
	data from manually delineated MRI data. A total of 56 structures
	were labeled in MRI of 40 healthy, normal volunteers. This labeling
	was performed according to a set of protocols developed for this
	project. Pairs of raters were assigned to each structure and trained
	on the protocol for that structure. Each rater pair was tested for
	concordance on 6 of the 40 brains; once they had achieved reliability
	standards, they divided the task of delineating the remaining 34
	brains. The data were then spatially normalized to well-known templates
	using 3 popular algorithms: AIR5.2.5's nonlinear warp (Woods et al.,
	1998) paired with the ICBM452 Warp 5 atlas (Rex et al., 2003), FSL's
	FLIRT (Smith et al., 2004) was paired with its own template, a skull-stripped
	version of the ICBM152 T1 average; and SPM5's unified segmentation
	method (Ashburner and Friston, 2005) was paired with its canonical
	brain, the whole head ICBM152 T1 average. We thus produced 3 variants
	of our atlas, where each was constructed from 40 representative samples
	of a data processing stream that one might use for analysis. For
	each normalization algorithm, the individual structure delineations
	were then resampled according to the computed transformations. We
	next computed averages at each voxel location to estimate the probability
	of that voxel belonging to each of the 56 structures. Each version
	of the atlas contains, for every voxel, probability densities for
	each region, thus providing a resource for automated probabilistic
	labeling of external data types registered into standard spaces;
	we also computed average intensity images and tissue density maps
	based on the three methods and target spaces. These atlases will
	serve as a resource for diverse applications including meta-analysis
	of functional and structural imaging data and other bioinformatics
	applications where display of arbitrary labels in probabilistically
	defined anatomic space will facilitate both knowledge-based development
	and visualization of findings from multiple disciplines.},
  doi = {10.1016/j.neuroimage.2007.09.031},
  institution = {Laboratory of Neuro Imaging, Department of Neurology, David Geffen
	School of Medicine, University of California, Los Angeles, 635 Charles
	Young Drive South, NRB1, Suite 225, Los Angeles, CA 90095, USA. shattuck@loni.ucla.edu},
  keywords = {Adolescent; Adult; Algorithms; Atlases as Topic; Brain Mapping; Cerebral
	Cortex, anatomy /&/ histology/physiology; Echo-Planar Imaging; Humans;
	Image Processing, Computer-Assisted; Likelihood Functions; Models,
	Statistical; Nonlinear Dynamics; Observer Variation; Reference Values},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S1053-8119(07)00809-9},
  pmid = {18037310},
  timestamp = {2013.02.21},
  url = {http://dx.doi.org/10.1016/j.neuroimage.2007.09.031}
}

@ARTICLE{Shew_2009,
  author = {Woodrow L Shew and Hongdian Yang and Thomas Petermann and Rajarshi
	Roy and Dietmar Plenz},
  title = {Neuronal avalanches imply maximum dynamic range in cortical networks
	at criticality.},
  journal = {J. Neurosci.},
  year = {2009},
  volume = {29},
  pages = {15595--15600},
  number = {49},
  month = {Dec},
  abstract = {Spontaneous neuronal activity is a ubiquitous feature of cortex. Its
	spatiotemporal organization reflects past input and modulates future
	network output. Here we study whether a particular type of spontaneous
	activity is generated by a network that is optimized for input processing.
	Neuronal avalanches are a type of spontaneous activity observed in
	superficial cortical layers in vitro and in vivo with statistical
	properties expected from a network operating at "criticality." Theory
	predicts that criticality and, therefore, neuronal avalanches are
	optimal for input processing, but until now, this has not been tested
	in experiments. Here, we use cortex slice cultures grown on planar
	microelectrode arrays to demonstrate that cortical networks that
	generate neuronal avalanches benefit from a maximized dynamic range,
	i.e., the ability to respond to the greatest range of stimuli. By
	changing the ratio of excitation and inhibition in the cultures,
	we derive a network tuning curve for stimulus processing as a function
	of distance from criticality in agreement with predictions from our
	simulations. Our findings suggest that in the cortex, (1) balanced
	excitation and inhibition establishes criticality, which maximizes
	the range of inputs that can be processed, and (2) spontaneous activity
	and input processing are unified in the context of critical phenomena.},
  doi = {10.1523/JNEUROSCI.3864-09.2009},
  institution = {Section on Critical Brain Dynamics, Laboratory of Systems Neuroscience,
	National Institute of Mental Health, Bethesda, Maryland 20892, USA.},
  keywords = {Animals; Coculture Techniques; Computer Simulation; Dopamine, metabolism;
	Evoked Potentials; Mesencephalon, physiology; Microelectrodes; Models,
	Neurological; Neural Inhibition, physiology; Neural Pathways, physiology;
	Neurons, physiology; Rats; Rats, Sprague-Dawley; Somatosensory Cortex,
	physiology; Synaptic Transmission},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {29/49/15595},
  pmid = {20007483},
  timestamp = {2013.03.05},
  url = {http://dx.doi.org/10.1523/JNEUROSCI.3864-09.2009}
}

@ARTICLE{Shmuel_2010,
  author = {Amir Shmuel and Denis Chaimow and Guenter Raddatz and Kamil Ugurbil
	and Essa Yacoub},
  title = {Mechanisms underlying decoding at 7 T: ocular dominance columns,
	broad structures, and macroscopic blood vessels in V1 convey information
	on the stimulated eye.},
  journal = {Neuroimage},
  year = {2010},
  volume = {49},
  pages = {1957--1964},
  number = {3},
  month = {Feb},
  abstract = {Recent studies have demonstrated that multivariate machine learning
	algorithms applied to human functional MRI data can decode information
	segregated in cortical columns, despite the voxel size being large
	relative to the width of columns. The mechanism by which low spatial
	resolution imaging decodes information represented in a fine-scale
	organization is not clear. To investigate mechanisms underlying decoding
	signals we employed high-resolution gradient-echo BOLD functional
	MRI of visual area V1. We show that in addition to the fine-scale
	ocular dominance columns, coarse-scale structures extending over
	several millimeters also convey discriminative power for decoding
	the stimulated eye. Discriminative power is conveyed by both macroscopic
	blood vessels and gray matter regions. We hypothesize that gray-matter
	regions which drain into specific vessels may preferentially contain
	ocular-dominance columns biased towards one eye; the bias of a specific
	region thereby causing a functionally selective ocular-dominance
	response in the associated vessel. Our findings indicate that coarse-scale
	structures and macroscopic blood vessels contribute to decoding of
	the stimulated eye based on low-resolution multivariate data.},
  doi = {10.1016/j.neuroimage.2009.08.040},
  institution = {Department of Neurology and Neurosurgery, Montreal Neurological Institute,
	McGill University, Montreal, Quebec, Canada. amir.shmuel@mcgill.ca},
  keywords = {Algorithms; Brain Mapping, methods; Cerebrovascular Circulation, physiology;
	Dominance, Ocular, physiology; Humans; Image Interpretation, Computer-Assisted,
	methods; Magnetic Resonance Imaging; Photic Stimulation; Visual Cortex,
	blood supply/physiology; Visual Pathways, physiology; Visual Perception,
	physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S1053-8119(09)00950-1},
  pmid = {19715765},
  timestamp = {2013.08.19},
  url = {http://dx.doi.org/10.1016/j.neuroimage.2009.08.040}
}

@ARTICLE{Shmuel_2007,
  author = {Amir Shmuel and Essa Yacoub and Denis Chaimow and Nikos K Logothetis
	and Kamil Ugurbil},
  title = {Spatio-temporal point-spread function of fMRI signal in human gray
	matter at 7 Tesla.},
  journal = {Neuroimage},
  year = {2007},
  volume = {35},
  pages = {539--552},
  number = {2},
  month = {Apr},
  abstract = {This study investigated the spatio-temporal properties of blood-oxygenation
	level-dependent (BOLD) functional MRI (fMRI) signals in gray matter,
	excluding the confounding, inaccurate contributions of large blood
	vessels. We quantified the spatial specificity of the BOLD response,
	and we investigated whether this specificity varies as a function
	of time from stimulus onset. fMRI was performed at 7 Tesla (T), where
	mapping signals of parenchymal origin are easily detected. Two abutting
	visual stimuli were adjusted to elicit responses centered on a flat
	gray matter region in V1. fMRI signals were sampled at high-resolution
	orthogonal to the retinotopic boundary between the representations
	of the stimuli. Signals from macro-vessels were masked out. Principal
	component analysis revealed that the first component in space accounted
	for 96.2+/-1.6\% of the variance over time. The spatial profile of
	this time-invariant response was fitted with a model consisting of
	the convolution of a step function and a Gaussian point-spread-function
	(PSF). The mean full-width at half-maximal-height of the fitted PSF
	was 2.34+/-0.20 mm. Based on simulations of confounding effects,
	we estimate that BOLD PSF in human gray matter is smaller than 2
	mm. A time-point to time-point analysis revealed that the PSF obtained
	during the 3rd (1.52 mm) and 4th (1.99 mm) seconds of stimulation
	were narrower than the mean PSF obtained from the 5th second on (2.42+/-0.15
	mm). The position of the edge of the responding region was offset
	(1.72+/-0.07 mm) from the boundary of the stimulated region, indicating
	a spatial non-linearity. Simulations showed that the effective contrast
	between active and non-active columns is reduced 25-fold when imaged
	using a PSF whose width is equal to the cycle of the imaged columnar
	organization. Thus, the PSF of the hyper-oxygenated BOLD response
	in human gray matter is narrower than that reported at 1.5 T, where
	macro-vessels dominate the mapping signals. The initial phase of
	this response is more spatially specific than later phases. Data
	acquisition methods that suppress macro-vascular signals should increase
	the spatial specificity of BOLD fMRI. The choice of optimal stimulus
	duration represents a trade-off between the spatial specificity and
	the overhead associated with short stimulus duration.},
  doi = {10.1016/j.neuroimage.2006.12.030},
  institution = {Center for MR Research, University of Minnesota Medical School, 2021
	6th St. SE, Minneapolis, MN, USA. amir.shmuel@tuebingen.mpg.de},
  keywords = {Adult; Brain, blood supply/physiology; Female; Humans; Magnetic Resonance
	Imaging, methods; Male; Mathematics; Oxygen, blood; Time Factors},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S1053-8119(06)01244-4},
  pmid = {17306989},
  timestamp = {2013.08.19},
  url = {http://dx.doi.org/10.1016/j.neuroimage.2006.12.030}
}

@BOOK{opengl-redbook,
  title = {{OpenGL(R) Programming Guide : The Official Guide to Learning OpenGL(R),
	Version 2 (5th Edition)}},
  publisher = {Addison-Wesley Professional},
  year = {2005},
  author = {Shreiner, D. and Woo, M. and Neider, J. and Davis, T.},
  month = aug,
  abstract = {{The <I>OpenGL Programming Guide</I>, now in its third edition, is
	the definitive volume for programmers using this evolving graphics
	interface standard. Written by members of the OpenGL Architecture
	Review Board, this book offers understandable tutorials and lessons
	on getting up to speed and getting the most out of the latest version
	of OpenGL, version 1.2.<p> The guide uses code examples in C and
	is targeted at programmers who have experience in coding yet are
	new to coding for OpenGL applications. The opening chapters go into
	descriptive detail of how OpenGL, the software interface for hardware
	3-D chipsets, works and what you can expect from it, which turns
	out to be much more than you might have thought. Color plates are
	used, for example, to show how OpenGL handles such effects as motion
	blur and depth-of-field blur, in addition to shadows and texture
	mapping.<p> This is not a beginner's guide to programming computer
	graphics. Some previous knowledge of both programming in general
	and computer graphics in particular is required. For example, code
	snippets are used to describe how to implement these effects, but
	because OpenGL is platform-independent, some code examples may need
	to be modified when used with your specific compiler.<p> Filled with
	the expertise of those who standardized OpenGL, there is no better
	reference volume for learning and understanding this system. The
	examples cited are clear, commented, and explained. The only drawback
	to the book is that it lacks a companion CD-ROM--all examples must
	be either typed in or downloaded from an Internet FTP site. (The
	URL is listed in the preface.) <I>--Mike Caputo</I>} {OpenGL is a
	powerful software interface for graphics hardware that allows graphics
	programmers to produce high-quality color images of 3D objects. The
	functions in the OpenGL library enable programmers to build geometric
	models, view models interactively in 3D space, control color and
	lighting, manipulate images, and perform such tasks as alpha blending,
	antialiasing, depth cueing, and texture mapping. <P> <B>The OpenGL
	Reference Manual, Second Edition</b>, documents all OpenGL functions,
	including brand new features recently approved by the OpenGL Architecture
	Review Board (ARB) for inclusion in OpenGL, Version 1.1. The ARB
	is an industry consortium responsible for defining OpenGL, composed
	of such industry leaders as Digital Equipment Corporation, Evans
	\& Sutherland, Hewlett-Packard, Intel, IBM, Intergraph, Microsoft,
	Sun Microsystems, and Silicon Graphics. <P> Each reference page fully
	describes: C specifications, relevant parameters, the effects of
	functions, possible errors generated by functions, associated effects,
	Reference pages for the OpenGL Utility Library (GLU) and the OpenGL
	extension to the X Window System (GLX) are included in this manual.}},
  citeulike-article-id = {407851},
  citeulike-linkout-0 = {http://www.amazon.ca/exec/obidos/redirect?tag=citeulike09-20\&amp;path=ASIN/0321335732},
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  citeulike-linkout-3 = {http://www.amazon.jp/exec/obidos/ASIN/0321335732},
  citeulike-linkout-4 = {http://www.amazon.co.uk/exec/obidos/ASIN/0321335732/citeulike00-21},
  citeulike-linkout-5 = {http://www.amazon.com/exec/obidos/redirect?tag=citeulike07-20\&path=ASIN/0321335732},
  citeulike-linkout-6 = {http://www.worldcat.org/isbn/0321335732},
  citeulike-linkout-7 = {http://books.google.com/books?vid=ISBN0321335732},
  citeulike-linkout-8 = {http://www.amazon.com/gp/search?keywords=0321335732\&index=books\&linkCode=qs},
  citeulike-linkout-9 = {http://www.librarything.com/isbn/0321335732},
  day = {01},
  howpublished = {Paperback},
  isbn = {0321335732},
  keywords = {opengl},
  posted-at = {2008-02-26 23:26:00},
  priority = {0},
  url = {http://www.amazon.com/exec/obidos/redirect?tag=citeulike07-20\&path=ASIN/0321335732}
}

@ARTICLE{Simard_1976,
  author = {J. M. Simard and G. T. Schneider and C. C. Turbes},
  title = {Development of telemetric techniques for use in studies of the electrical
	activity of the brain.},
  journal = {ISA T},
  year = {1976},
  volume = {15},
  pages = {246--252},
  number = {3},
  abstract = {A telemetry system has been designed to transmit two channels of wideband
	activity (0.2 Hz-2.5 KHz) recorded from high-impedance microelectrodes
	in the brains of free-moving cats. Thus, both unit activity and slow-wave
	field activity are accessible without disruption of the animals'
	behavior. In addition, circuitry is described that conditions the
	receiver signals, that dicriminates valid subcarrier signals from
	receiver noise and that automatically aborts data output in the absence
	of discriminable subcarrier. This receiver signal processing circuitry
	thus assures the fidelity of the decoded subcarrier, greatly facilitates
	further machine processing of the data and frees the experimenter
	from having to continuously monitor the receiver signals to subjectively
	edit out noisy data.},
  keywords = {Animals; Brain, physiology; Cats; Electrodes, Implanted; Electrophysiology,
	instrumentation; Female; Male; Microelectrodes; Telemetry, instrumentation},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {992998},
  timestamp = {2013.02.11}
}

@ARTICLE{Smith_2004,
  author = {Smith, Stephen M. and Jenkinson, Mark and Woolrich, Mark W. and Beckmann,
	Christian F. and Behrens, Timothy E J. and Johansen-Berg, Heidi and
	Bannister, Peter R. and {De Luca}, Marilena and Drobnjak, Ivana and
	Flitney, David E. and Niazy, Rami K. and Saunders, James and Vickers,
	John and Zhang, Yongyue and {De Stefano}, Nicola and Brady, J Michael
	and Matthews, Paul M.},
  title = {Advances in functional and structural MR image analysis and implementation
	as FSL.},
  journal = {Neuroimage},
  year = {2004},
  volume = {23 Suppl 1},
  pages = {S208--S219},
  abstract = {The techniques available for the interrogation and analysis of neuroimaging
	data have a large influence in determining the flexibility, sensitivity,
	and scope of neuroimaging experiments. The development of such methodologies
	has allowed investigators to address scientific questions that could
	not previously be answered and, as such, has become an important
	research area in its own right. In this paper, we present a review
	of the research carried out by the Analysis Group at the Oxford Centre
	for Functional MRI of the Brain (FMRIB). This research has focussed
	on the development of new methodologies for the analysis of both
	structural and functional magnetic resonance imaging data. The majority
	of the research laid out in this paper has been implemented as freely
	available software tools within FMRIB's Software Library (FSL).},
  doi = {10.1016/j.neuroimage.2004.07.051},
  institution = {Oxford Centre for Functional Magnetic Resonance Imaging of the Brain
	(FMRIB), Department of Clinical Neurology, John Radcliffe Hospital,
	Oxford University, Headington, Oxford OX3 9DU, UK. steve@fmrib.ox.ac.uk},
  keywords = {Bayes Theorem; Brain, anatomy /&/ histology/physiology; Databases,
	Factual; Humans; Image Processing, Computer-Assisted; Magnetic Resonance
	Imaging, statistics /&/ numerical data; Models, Neurological; Models,
	Statistical; Software},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paupau},
  pii = {S1053-8119(04)00393-3},
  pmid = {15501092},
  timestamp = {2013.10.24},
  url = {http://dx.doi.org/10.1016/j.neuroimage.2004.07.051}
}

@ARTICLE{Sotero_2011,
  author = {Roberto C Sotero and Yasser Iturria-Medina},
  title = {From blood oxygenation level dependent (BOLD) signals to brain temperature
	maps.},
  journal = {Bull Math Biol},
  year = {2011},
  volume = {73},
  pages = {2731--2747},
  number = {11},
  month = {Nov},
  abstract = {A theoretical framework is presented for converting Blood Oxygenation
	Level Dependent (BOLD) images to brain temperature maps, based on
	the idea that disproportional local changes in cerebral blood flow
	(CBF) as compared with cerebral metabolic rate of oxygen consumption
	(CMRO₂) during functional brain activity, lead to both brain temperature
	changes and the BOLD effect. Using an oxygen limitation model and
	a BOLD signal model, we obtain a transcendental equation relating
	CBF and CMRO₂ changes with the corresponding BOLD signal, which is
	solved in terms of the Lambert W function. Inserting this result
	in the dynamic bioheat equation describing the rate of temperature
	changes in the brain, we obtain a nonautonomous ordinary differential
	equation that depends on the BOLD response, which is solved numerically
	for each brain voxel. Temperature maps obtained from a real BOLD
	dataset registered in an attention to visual motion experiment were
	calculated, obtaining temperature variations in the range: (-0.15,
	0.1) which is consistent with experimental results. The statistical
	analysis revealed that significant temperature activations have a
	similar distribution pattern than BOLD activations. An interesting
	difference was the activation of the precuneus in temperature maps,
	a region involved in visuospatial processing, an effect that was
	not observed on BOLD maps. Furthermore, temperature maps were more
	localized to gray matter regions than the original BOLD maps, showing
	less activated voxels in white matter and cerebrospinal fluid.},
  doi = {10.1007/s11538-011-9645-5},
  institution = {National Bioinformatics Center (BIOINFO), InSTEC, Havana, Cuba. rcsotero@gmail.com},
  keywords = {Body Temperature, physiology; Brain, blood supply/physiology; Cerebrovascular
	Circulation; Databases, Factual; Humans; Magnetic Resonance Imaging;
	Mathematical Concepts; Models, Neurological; Oxygen Consumption;
	Oxygen, blood; Regional Blood Flow},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {21409512},
  timestamp = {2013.07.04},
  url = {http://dx.doi.org/10.1007/s11538-011-9645-5}
}

@ARTICLE{Sotero_2008,
  author = {Sotero, Roberto C. and Trujillo-Barreto, Nelson J.},
  title = {Biophysical model for integrating neuronal activity, EEG, fMRI and
	metabolism.},
  journal = {Neuroimage},
  year = {2008},
  volume = {39},
  pages = {290--309},
  number = {1},
  month = {Jan},
  abstract = {Our goal is to model the coupling between neuronal activity, cerebral
	metabolic rates of glucose and oxygen consumption, cerebral blood
	flow (CBF), electroencephalography (EEG) and blood oxygenation level-dependent
	(BOLD) responses. In order to accomplish this, two previous models
	are coupled: a metabolic/hemodynamic model (MHM) for a voxel, linking
	BOLD signals and neuronal activity, and a neural mass model describing
	the neuronal dynamics within a voxel and its interactions with voxels
	of the same area (short-range interactions) and other areas (long-range
	interactions). For coupling both models, we take as the input to
	the BOLD model, the number of active synapses within the voxel, that
	is, the average number of synapses that will receive an action potential
	within the time unit. This is obtained by considering the action
	potentials transmitted between neuronal populations within the voxel,
	as well as those arriving from other voxels. Simulations are carried
	out for testing the integrated model. Results show that realistic
	evoked potentials (EP) at electrodes on the scalp surface and the
	corresponding BOLD signals for each voxel are produced by the model.
	In another simulation, the alpha rhythm was reproduced and reasonable
	similarities with experimental data were obtained when calculating
	correlations between BOLD signals and the alpha power curve. The
	origin of negative BOLD responses and the characteristics of EEG,
	PET and BOLD signals in Alzheimer's disease were also studied.},
  doi = {10.1016/j.neuroimage.2007.08.001},
  institution = {Brain Dynamics Department, Cuban Neuroscience Center, Avenue 25,
	Esq 158, \#15202, PO Box 6412, 6414, Cubanacán, Playa, Havana, Cuba.
	rcarlos@cneuro.edu.cu},
  keywords = {Alzheimer Disease, diagnosis/physiopathology; Biophysics, methods;
	Brain Mapping, methods; Brain, physiopathology; Computer Simulation;
	Diagnosis, Computer-Assisted, methods; Electroencephalography, methods;
	Glucose, metabolism; Image Interpretation, Computer-Assisted, methods;
	Magnetic Resonance Imaging, methods; Models, Neurological; Neurons;
	Oxygen, metabolism; Positron-Emission Tomography, methods; Systems
	Integration},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paupau},
  pii = {S1053-8119(07)00704-5},
  pmid = {17919931},
  timestamp = {2013.04.09},
  url = {http://dx.doi.org/10.1016/j.neuroimage.2007.08.001}
}

@ARTICLE{Sotero_2007,
  author = {Sotero, Roberto C. and Trujillo-Barreto, Nelson J. and Iturria-Medina,
	Yasser and Carbonell, Felix and Jimenez, Juan C.},
  title = {Realistically coupled neural mass models can generate EEG rhythms.},
  journal = {Neural Comput.},
  year = {2007},
  volume = {19},
  pages = {478--512},
  number = {2},
  month = {Feb},
  abstract = {We study the generation of EEG rhythms by means of realistically coupled
	neural mass models. Previous neural mass models were used to model
	cortical voxels and the thalamus. Interactions between voxels of
	the same and other cortical areas and with the thalamus were taken
	into account. Voxels within the same cortical area were coupled (short-range
	connections) with both excitatory and inhibitory connections, while
	coupling between areas (long-range connections) was considered to
	be excitatory only. Short-range connection strengths were modeled
	by using a connectivity function depending on the distance between
	voxels. Coupling strength parameters between areas were defined from
	empirical anatomical data employing the information obtained from
	probabilistic paths, which were tracked by water diffusion imaging
	techniques and used to quantify white matter tracts in the brain.
	Each cortical voxel was then described by a set of 16 random differential
	equations, while the thalamus was described by a set of 12 random
	differential equations. Thus, for analyzing the neuronal dynamics
	emerging from the interaction of several areas, a large system of
	differential equations needs to be solved. The sparseness of the
	estimated anatomical connectivity matrix reduces the number of connection
	parameters substantially, making the solution of this system faster.
	Simulations of human brain rhythms were carried out in order to test
	the model. Physiologically plausible results were obtained based
	on this anatomically constrained neural mass model.},
  doi = {10.1162/neco.2007.19.2.478},
  institution = {Cuban Neuroscience Center, Brain Dynamics Department, Havana, Cuba.
	rcarlos@cneuro.edu.cu},
  keywords = {Brain Mapping; Cerebral Cortex, physiology; Computer Simulation; Electroencephalography;
	Humans; Models, Neurological; Nerve Net, physiology; Neural Networks
	(Computer); Neural Pathways, physiology; Physiological Phenomena,
	physiology; Thalamus, physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paupau},
  pmid = {17206872},
  timestamp = {2013.04.09},
  url = {http://dx.doi.org/10.1162/neco.2007.19.2.478}
}

@ARTICLE{Spacek_2008,
  author = {Martin Spacek and Tim Blanche and Nicholas Swindale},
  title = {Python for large-scale electrophysiology.},
  journal = {Front. Neuroinform.},
  year = {2008},
  volume = {2},
  pages = {9},
  abstract = {Electrophysiology is increasingly moving towards highly parallel recording
	techniques which generate large data sets. We record extracellularly
	in vivo in cat and rat visual cortex with 54-channel silicon polytrodes,
	under time-locked visual stimulation, from localized neuronal populations
	within a cortical column. To help deal with the complexity of generating
	and analysing these data, we used the Python programming language
	to develop three software projects: one for temporally precise visual
	stimulus generation ("dimstim"); one for electrophysiological waveform
	visualization and spike sorting ("spyke"); and one for spike train
	and stimulus analysis ("neuropy"). All three are open source and
	available for download (http://swindale.ecc.ubc.ca/code). The requirements
	and solutions for these projects differed greatly, yet we found Python
	to be well suited for all three. Here we present our software as
	a showcase of the extensive capabilities of Python in neuroscience.},
  doi = {10.3389/neuro.11.009.2008},
  institution = {Ophthalmology and Visual Sciences, University of British Columbia
	Vancouver, BC, Canada.},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {19198646},
  timestamp = {2012.12.27},
  url = {http://dx.doi.org/10.3389/neuro.11.009.2008}
}

@ARTICLE{Spiegler_2013,
  author = {A. Spiegler and V. Jirsa},
  title = {Systematic approximations of neural fields through networks of neural
	masses in the virtual brain.},
  journal = {Neuroimage},
  year = {2013},
  volume = {83C},
  pages = {704--725},
  month = {Jun},
  abstract = {Full brain network models comprise a large-scale connectivity (the
	connectome) and neural mass models as the network's nodes. Neural
	mass models absorb implicitly a variety of properties in their constant
	parameters to achieve a reduction in complexity. In situations, where
	the local network connectivity undergoes major changes, such as in
	development or epilepsy, it becomes crucial to model local connectivity
	explicitly. This leads naturally to a description of neural fields
	on folded cortical sheets with local and global connectivities. The
	numerical approximation of neural fields in biologically realistic
	situations as addressed in Virtual Brain simulations (see http://thevirtualbrain.org/app/
	(version 1.0)) is challenging and requires a thorough evaluation
	if the Virtual Brain approach is to be adapted for systematic studies
	of disease and disorders. Here we analyze the sampling problem of
	neural fields for arbitrary dimensions and provide explicit results
	for one, two and three dimensions relevant to realistically folded
	cortical surfaces. We characterize (i) the error due to sampling
	of spatial distribution functions; (ii) useful sampling parameter
	ranges in the context of encephalographic (EEG, MEG, ECoG and functional
	MRI) signals; (iii) guidelines for choosing the right spatial distribution
	function for given anatomical and geometrical constraints.},
  doi = {10.1016/j.neuroimage.2013.06.018},
  institution = {Institut de Neurosciences des Systèmes, UMR INSERM 1106, Aix-Marseille
	Université, Faculté de Médecine, 27, Boulevard Jean Moulin, 13005
	Marseille, France. Electronic address: andreas.spiegler@univ-amu.fr.},
  language = {eng},
  medline-pst = {aheadofprint},
  owner = {paula},
  pii = {S1053-8119(13)00655-1},
  pmid = {23774395},
  timestamp = {2013.08.19},
  url = {http://dx.doi.org/10.1016/j.neuroimage.2013.06.018}
}

@ARTICLE{Spiegler_2010,
  author = {Andreas Spiegler and Stefan J Kiebel and Fatihcan M Atay and Thomas
	R Knösche},
  title = {Bifurcation analysis of neural mass models: Impact of extrinsic inputs
	and dendritic time constants.},
  journal = {Neuroimage},
  year = {2010},
  volume = {52},
  pages = {1041--1058},
  number = {3},
  month = {Sep},
  abstract = {Neural mass models (NMMs) explain dynamics of neuronal populations
	and were designed to strike a balance between mathematical simplicity
	and biological plausibility. They are currently widely used as generative
	models for noninvasive electrophysiological brain measurements; that
	is, magneto- and electroencephalography (M/EEG). Here, we systematically
	describe the oscillatory regimes which a NMM of a single cortical
	source with extrinsic input from other cortical and subcortical areas
	to each subpopulation can explain. For this purpose, we used bifurcation
	analysis to describe qualitative changes in system behavior in response
	to quantitative input changes. This approach allowed us to describe
	sequences of oscillatory regimes, given some specific input trajectory.
	We systematically classified these sequential phenomena and mapped
	them into parameter space. Our analysis suggests a principled scheme
	of how complex M/EEG phenomena can be modeled parsimoniously on two
	time scales: While the system displays fast oscillations, it slowly
	traverses phase space to another qualitatively different oscillatory
	regime, depending on the input dynamics. The resulting scheme is
	useful for applications where one needs to model an ordered sequence
	of switching between qualitatively different oscillatory regimes,
	for example, in pharmacological interventions, epilepsy, sleep, or
	context-induced state changes.},
  doi = {10.1016/j.neuroimage.2009.12.081},
  institution = {Max Planck Institute for Human Cognitive and Brain Sciences, Leipzig,
	Germany. spiegler@cbs.mpg.de},
  keywords = {Brain, physiology; Electroencephalography; Magnetoencephalography;
	Models, Neurological; Nerve Net, physiology; Neural Networks (Computer);
	Signal Processing, Computer-Assisted},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S1053-8119(09)01370-6},
  pmid = {20045068},
  timestamp = {2012.12.18},
  url = {http://dx.doi.org/10.1016/j.neuroimage.2009.12.081}
}

@ARTICLE{Spiegler_2011,
  author = {Andreas Spiegler and Thomas R Knösche and Karin Schwab and Jens Haueisen
	and Fatihcan M Atay},
  title = {Modeling brain resonance phenomena using a neural mass model.},
  journal = {PLoS Comput Biol},
  year = {2011},
  volume = {7},
  pages = {e1002298},
  number = {12},
  month = {Dec},
  abstract = {Stimulation with rhythmic light flicker (photic driving) plays an
	important role in the diagnosis of schizophrenia, mood disorder,
	migraine, and epilepsy. In particular, the adjustment of spontaneous
	brain rhythms to the stimulus frequency (entrainment) is used to
	assess the functional flexibility of the brain. We aim to gain deeper
	understanding of the mechanisms underlying this technique and to
	predict the effects of stimulus frequency and intensity. For this
	purpose, a modified Jansen and Rit neural mass model (NMM) of a cortical
	circuit is used. This mean field model has been designed to strike
	a balance between mathematical simplicity and biological plausibility.
	We reproduced the entrainment phenomenon observed in EEG during a
	photic driving experiment. More generally, we demonstrate that such
	a single area model can already yield very complex dynamics, including
	chaos, for biologically plausible parameter ranges. We chart the
	entire parameter space by means of characteristic Lyapunov spectra
	and Kaplan-Yorke dimension as well as time series and power spectra.
	Rhythmic and chaotic brain states were found virtually next to each
	other, such that small parameter changes can give rise to switching
	from one to another. Strikingly, this characteristic pattern of unpredictability
	generated by the model was matched to the experimental data with
	reasonable accuracy. These findings confirm that the NMM is a useful
	model of brain dynamics during photic driving. In this context, it
	can be used to study the mechanisms of, for example, perception and
	epileptic seizure generation. In particular, it enabled us to make
	predictions regarding the stimulus amplitude in further experiments
	for improving the entrainment effect.},
  doi = {10.1371/journal.pcbi.1002298},
  institution = {Max Planck Institute for Human Cognitive and Brain Sciences, Leipzig,
	Germany. spiegler@cbs.mpg.de},
  keywords = {Brain, physiopathology; Electroencephalography; Epilepsy, physiopathology;
	Humans; Models, Neurological; Nerve Net, physiology; Schizophrenia,
	physiopathology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {PCOMPBIOL-D-11-00101},
  pmid = {22215992},
  timestamp = {2013.04.29},
  url = {http://dx.doi.org/10.1371/journal.pcbi.1002298}
}

@ARTICLE{Sporns_2013,
  author = {Olaf Sporns},
  title = {Making sense of brain network data.},
  journal = {Nat Methods},
  year = {2013},
  volume = {10},
  pages = {491--493},
  number = {6},
  month = {Jun},
  doi = {10.1038/nmeth.2485},
  institution = {Department of Psychological and Brain Sciences, Indiana University,
	Bloomington, Indiana, USA. osporns@indiana.edu},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {nmeth.2485},
  pmid = {23722207},
  timestamp = {2013.07.30},
  url = {http://dx.doi.org/10.1038/nmeth.2485}
}

@ARTICLE{Sporns_2012,
  author = {Olaf Sporns},
  title = {From simple graphs to the connectome: networks in neuroimaging.},
  journal = {Neuroimage},
  year = {2012},
  volume = {62},
  pages = {881--886},
  number = {2},
  month = {Aug},
  abstract = {Connectivity is fundamental for understanding the nature of brain
	function. The intricate web of synaptic connections among neurons
	is critically important for shaping neural responses, representing
	statistical features of the sensory environment, coordinating distributed
	resources for brain-wide processing, and retaining a structural record
	of the past in order to anticipate future events and infer their
	relations. The importance of brain connectivity naturally leads to
	the adoption of the theoretical framework of networks and graphs.
	Network science approaches have been productively deployed in other
	domains of science and technology and are now beginning to make contributions
	across many areas of neuroscience. This article offers a personal
	perspective on the confluence of networks and neuroimaging, charting
	the origins of some of its major intellectual themes.},
  doi = {10.1016/j.neuroimage.2011.08.085},
  institution = {Department of Psychological and Brain Sciences, Indiana University,
	Bloomington, IN 47405, USA. osporns@indiana.edu},
  keywords = {Brain, anatomy /&/ histology/physiology; Humans; Nerve Net, anatomy
	/&/ histology/physiology; Neuroimaging, methods},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S1053-8119(11)01017-2},
  pmid = {21964480},
  timestamp = {2012.12.26},
  url = {http://dx.doi.org/10.1016/j.neuroimage.2011.08.085}
}

@ARTICLE{Sporns_2011,
  author = {Olaf Sporns},
  title = {The non-random brain: efficiency, economy, and complex dynamics.},
  journal = {Front. Comput. Neurosci.},
  year = {2011},
  volume = {5},
  pages = {5},
  abstract = {Modern anatomical tracing and imaging techniques are beginning to
	reveal the structural anatomy of neural circuits at small and large
	scales in unprecedented detail. When examined with analytic tools
	from graph theory and network science, neural connectivity exhibits
	highly non-random features, including high clustering and short path
	length, as well as modules and highly central hub nodes. These characteristic
	topological features of neural connections shape non-random dynamic
	interactions that occur during spontaneous activity or in response
	to external stimulation. Disturbances of connectivity and thus of
	neural dynamics are thought to underlie a number of disease states
	of the brain, and some evidence suggests that degraded functional
	performance of brain networks may be the outcome of a process of
	randomization affecting their nodes and edges. This article provides
	a survey of the non-random structure of neural connectivity, primarily
	at the large scale of regions and pathways in the mammalian cerebral
	cortex. In addition, we will discuss how non-random connections can
	give rise to differentiated and complex patterns of dynamics and
	information flow. Finally, we will explore the idea that at least
	some disorders of the nervous system are associated with increased
	randomness of neural connections.},
  doi = {10.3389/fncom.2011.00005},
  institution = {Department of Psychological and Brain Sciences, Indiana University
	Bloomington, IN, USA.},
  language = {eng},
  medline-pst = {epublish},
  owner = {paula},
  pmid = {21369354},
  timestamp = {2012.12.26},
  url = {http://dx.doi.org/10.3389/fncom.2011.00005}
}

@ARTICLE{Sporns_2011a,
  author = {Olaf Sporns},
  title = {The human connectome: a complex network.},
  journal = {Ann. N.Y. Acad. Sci.},
  year = {2011},
  volume = {1224},
  pages = {109--125},
  month = {Apr},
  abstract = {The human brain is a complex network. An important first step toward
	understanding the function of such a network is to map its elements
	and connections, to create a comprehensive structural description
	of the network architecture. This paper reviews current empirical
	efforts toward generating a network map of the human brain, the human
	connectome, and explores how the connectome can provide new insights
	into the organization of the brain's structural connections and their
	role in shaping functional dynamics. Network studies of structural
	connectivity obtained from noninvasive neuroimaging have revealed
	a number of highly nonrandom network attributes, including high clustering
	and modularity combined with high efficiency and short path length.
	The combination of these attributes simultaneously promotes high
	specialization and high integration within a modular small-world
	architecture. Structural and functional networks share some of the
	same characteristics, although their relationship is complex and
	nonlinear. Future studies of the human connectome will greatly expand
	our knowledge of network topology and dynamics in the healthy, developing,
	aging, and diseased brain.},
  doi = {10.1111/j.1749-6632.2010.05888.x},
  institution = {Department of Psychological and Brain Sciences, Indiana University,
	Bloomington, IN 47405, USA. osporns@indiana.edu},
  keywords = {Animals; Brain Mapping, methods; Brain, metabolism/physiology; Humans;
	Models, Biological; Models, Neurological; Nerve Net, physiology;
	Neural Pathways, physiology; Synaptic Transmission, physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {21251014},
  timestamp = {2012.12.26},
  url = {http://dx.doi.org/10.1111/j.1749-6632.2010.05888.x}
}

@ARTICLE{Sporns_2005,
  author = {Olaf Sporns and Giulio Tononi and Rolf Kötter},
  title = {The human connectome: A structural description of the human brain.},
  journal = {PLoS Comput. Biol.},
  year = {2005},
  volume = {1},
  pages = {e42},
  number = {4},
  month = {Sep},
  abstract = {The connection matrix of the human brain (the human "connectome")
	represents an indispensable foundation for basic and applied neurobiological
	research. However, the network of anatomical connections linking
	the neuronal elements of the human brain is still largely unknown.
	While some databases or collations of large-scale anatomical connection
	patterns exist for other mammalian species, there is currently no
	connection matrix of the human brain, nor is there a coordinated
	research effort to collect, archive, and disseminate this important
	information. We propose a research strategy to achieve this goal,
	and discuss its potential impact.},
  doi = {10.1371/journal.pcbi.0010042},
  institution = {Department of Psychology, Indiana University, Bloomington, Indiana,
	United States of America. osporns@indiana.edu},
  keywords = {Animals; Brain, anatomy /&/ histology/cytology/metabolism; Humans;
	Nerve Net; Neurons, metabolism; Synapses, metabolism},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {16201007},
  timestamp = {2012.12.26},
  url = {http://dx.doi.org/10.1371/journal.pcbi.0010042}
}

@ARTICLE{Srebro_1996,
  author = {Srebro, R.},
  title = {{A modified boundary element method for the estimation of potential
	fields on the scalp}},
  journal = {IEEE Trans. Biomed. Eng.},
  year = {1996},
  volume = {43},
  pages = {650--653},
  number = {6},
  doi = {10.1109/10.495284},
  issn = {0018-9294}
}

@ARTICLE{Stefanescu_2011,
  author = {Stefanescu, RA and Jirsa, VK},
  title = {Reduced representations of heterogeneous mixed neural networks with
	synaptic coupling},
  journal = {Phys. Rev. E: Stat., Nonlinear, Soft Matter Phys.},
  year = {2011},
  volume = {83},
  pages = {-},
  number = {2},
  comment = {12 pages},
  owner = {paula},
  timestamp = {2012.10.18}
}

@ARTICLE{Stefanescu_2008,
  author = {Stefanescu, R and Jirsa, VK},
  title = {A Low Dimensional Description of Globally Coupled Heterogeneous Neural
	Networks of Excitatory and Inhibitory},
  journal = {PLoS Comput. Biol.},
  year = {2008},
  volume = {4},
  pages = {26-36},
  number = {11},
  keywords = {model},
  owner = {paula},
  timestamp = {2012.10.18}
}

@ARTICLE{Stephan2010,
  author = {Klaas Enno Stephan and Karl J Friston},
  title = {Analyzing effective connectivity with fMRI.},
  journal = {Wiley. Interdiscip. Rev. Cogn. Sci.},
  year = {2010},
  volume = {1},
  pages = {446--459},
  number = {3},
  month = {Jun},
  abstract = {Functional neuroimaging techniques are used widely in cognitive neuroscience
	to investigate aspects of functional specialization and functional
	integration in the human brain. Functional integration can be characterized
	in two ways, functional connectivity and effective connectivity.
	While functional connectivity describes statistical dependencies
	between data, effective connectivity rests on a mechanistic model
	of the causal effects that generated the data. This review addresses
	the conceptual and methodological basis of established techniques
	for characterizing effective connectivity using functional magnetic
	resonance imaging (fMRI) data. In particular, we focus on dynamic
	causal modeling (DCM) of fMRI data and emphasize the importance of
	model selection procedures and nonlinear mechanisms for context-dependent
	changes in connection strengths.},
  doi = {10.1002/wcs.58},
  institution = {Laboratory for Social and Neural Systems Research, Institute for
	Empirical Research in Economics, University of Zurich, Switzerland.},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {21209846},
  timestamp = {2013.04.11},
  url = {http://dx.doi.org/10.1002/wcs.58}
}

@ARTICLE{Stephan_2012,
  author = {Klaas Enno Stephan and Alard Roebroeck},
  title = {A short history of causal modeling of fMRI data.},
  journal = {Neuroimage},
  year = {2012},
  volume = {62},
  pages = {856--863},
  number = {2},
  month = {Aug},
  abstract = {Twenty years ago, the discovery of the blood oxygen level dependent
	(BOLD) contrast and invention of functional magnetic resonance imaging
	(MRI) not only allowed for enhanced analyses of regional brain activity,
	but also laid the foundation for novel approaches to studying effective
	connectivity, which is essential for mechanistically interpretable
	accounts of neuronal systems. Dynamic causal modeling (DCM) and Granger
	causality (G-causality) modeling have since become the most frequently
	used techniques for inferring effective connectivity from fMRI data.
	In this paper, we provide a short historical overview of these approaches,
	describing milestones of their development from our subjective perspectives.},
  doi = {10.1016/j.neuroimage.2012.01.034},
  institution = {Laboratory for Social and Neural Systems Research, Dept of Economics,
	University of Zurich, Switzerland. klaasenno.stephan@econ.uzh.ch},
  keywords = {Brain Mapping, history/methods; Brain, anatomy /&/ histology/physiology;
	History, 20th Century; History, 21st Century; Humans; Magnetic Resonance
	Imaging, history/methods; Models, Neurological; Models, Theoretical},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S1053-8119(12)00051-1},
  pmid = {22248576},
  timestamp = {2013.02.14},
  url = {http://dx.doi.org/10.1016/j.neuroimage.2012.01.034}
}

@ARTICLE{Stephan_2007,
  author = {Klaas Enno Stephan and Nikolaus Weiskopf and Peter M Drysdale and
	Peter A Robinson and Karl J Friston},
  title = {Comparing hemodynamic models with DCM.},
  journal = {Neuroimage},
  year = {2007},
  volume = {38},
  pages = {387--401},
  number = {3},
  month = {Nov},
  abstract = {The classical model of blood oxygen level-dependent (BOLD) responses
	by Buxton et al. [Buxton, R.B., Wong, E.C., Frank, L.R., 1998. Dynamics
	of blood flow and oxygenation changes during brain activation: the
	Balloon model. Magn. Reson. Med. 39, 855-864] has been very important
	in providing a biophysically plausible framework for explaining different
	aspects of hemodynamic responses. It also plays an important role
	in the hemodynamic forward model for dynamic causal modeling (DCM)
	of fMRI data. A recent study by Obata et al. [Obata, T., Liu, T.T.,
	Miller, K.L., Luh, W.M., Wong, E.C., Frank, L.R., Buxton, R.B., 2004.
	Discrepancies between BOLD and flow dynamics in primary and supplementary
	motor areas: application of the Balloon model to the interpretation
	of BOLD transients. NeuroImage 21, 144-153] linearized the BOLD signal
	equation and suggested a revised form for the model coefficients.
	In this paper, we show that the classical and revised models are
	special cases of a generalized model. The BOLD signal equation of
	this generalized model can be reduced to that of the classical Buxton
	model by simplifying the coefficients or can be linearized to give
	the Obata model. Given the importance of hemodynamic models for investigating
	BOLD responses and analyses of effective connectivity with DCM, the
	question arises which formulation is the best model for empirically
	measured BOLD responses. In this article, we address this question
	by embedding different variants of the BOLD signal equation in a
	well-established DCM of functional interactions among visual areas.
	This allows us to compare the ensuing models using Bayesian model
	selection. Our model comparison approach had a factorial structure,
	comparing eight different hemodynamic models based on (i) classical
	vs. revised forms for the coefficients, (ii) linear vs. non-linear
	output equations, and (iii) fixed vs. free parameters, epsilon, for
	region-specific ratios of intra- and extravascular signals. Using
	fMRI data from a group of twelve subjects, we demonstrate that the
	best model is a non-linear model with a revised form for the coefficients,
	in which epsilon is treated as a free parameter.},
  doi = {10.1016/j.neuroimage.2007.07.040},
  institution = {Wellcome Trust Centre for Neuroimaging, Institute of Neurology, University
	College London, 12 Queen Square, London WC1N 3BG, UK, and Brain Dynamics
	Center, Westmead Millenium Institute, Westmead Hospital, NSW, Australia.
	k.stephan@fil.ion.ucl.ac.uk},
  keywords = {Animals; Hemodynamics, physiology; Magnetic Resonance Imaging; Models,
	Biological; Nervous System Physiological Phenomena; Oxygen Consumption;
	Oxygen, blood},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S1053-8119(07)00648-9},
  pmid = {17884583},
  timestamp = {2013.08.19},
  url = {http://dx.doi.org/10.1016/j.neuroimage.2007.07.040}
}

@ARTICLE{Steyn-Ross_1999,
  author = {M. L. Steyn-Ross and D. A. Steyn-Ross and J. W. Sleigh and D. T.
	Liley},
  title = {Theoretical electroencephalogram stationary spectrum for a white-noise-driven
	cortex: evidence for a general anesthetic-induced phase transition.},
  journal = {Phys Rev E Stat Phys Plasmas Fluids Relat Interdiscip Topics},
  year = {1999},
  volume = {60},
  pages = {7299--7311},
  number = {6 Pt B},
  month = {Dec},
  abstract = {We present a model for the dynamics of a cerebral cortex in which
	inputs to neuronal assemblies are treated as random Gaussian fluctuations
	about a mean value. We incorporate the effect of general anesthetic
	agents on the cortex as a modulation of the inhibitory neurotransmitter
	rate constant. Stochastic differential equations are derived for
	the state variable h(e), the average excitatory soma potential, coherent
	fluctuations of which are believed to be the source of scalp-measured
	electroencephalogram (EEG) signals. Using this stochastic approach
	we derive a stationary (long-time limit) fluctuation spectrum for
	h(e). The model predicts that there will be three distinct stationary
	(equilibrium) regimes for cortical activity. In region I ("coma"),
	corresponding to a strong inhibitory anesthetic effect, h(e) is single
	valued, large, and negative, so that neuronal firing rates are suppressed.
	In region II for a zero or small anesthetic effect, h(e) can take
	on three values, two of which are stable; we label the stable solutions
	as "active" (enhanced firing) and "quiescent" (suppressed firing).
	For region III, corresponding to negative anesthetic (i.e., analeptic)
	effect, h(e) again becomes single valued, but is now small and negative,
	resulting in strongly elevated firing rates ("seizure"). If we identify
	region II as associated with the conscious state of the cortex, then
	the model predicts that there will be a rapid transit between the
	active-conscious and comatose unconscious states at a critical value
	of anesthetic concentration, suggesting the existence of phase transitions
	in the cortex. The low-frequency spectral power in the h(e) signal
	should increase strongly during the initial stage of anesthesia induction,
	before collapsing to much lower values after the transition into
	comatose-unconsciousness. These qualitative predictions are consistent
	with clinical measurements by Bührer et al. [Anaesthesiology 77,
	226 (1992)], MacIver et al. [ibid. 84, 1411 (1996)], and Kuizenga
	et al. [Br. J. Anaesthesia 80, 725 (1998)]. This strong increase
	in EEG spectral power in the vicinity of the critical point is similar
	to the divergences observed during thermodynamic phase transitions.
	We show that the divergence in low-frequency power in our model is
	a natural consequence of the existence of turning points in the trajectory
	of stationary states for the cortex.},
  institution = {Department of Physics and Electronic Engineering, Private Bag 3105,
	University of Waikato, Hamilton, New Zealand.},
  keywords = {Action Potentials, drug effects/physiology; Anesthesia, General, methods;
	Anesthetics, blood/pharmacology; Cerebral Cortex, drug effects/physiology;
	Coma, chemically induced; Computer Simulation; Electroencephalography,
	methods/statistics /&/ numerical data; Evoked Potentials, Somatosensory,
	drug effects/physiology; Humans; Leg, surgery; Linear Models; Male;
	Models, Neurological; Noise; Propofol, blood/pharmacology; Reaction
	Time, drug effects/physiology; Seizures, chemically induced; Stochastic
	Processes},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {11970675},
  timestamp = {2013.08.19}
}

@ARTICLE{Tadel_2011,
  author = {Tadel, François and Baillet, Sylvain and Mosher, John C. and Pantazis,
	Dimitrios and Leahy, Richard M.},
  title = {Brainstorm: a user-friendly application for MEG/EEG analysis.},
  journal = {Comput. Intell. Neurosci.},
  year = {2011},
  volume = {2011},
  pages = {879716},
  abstract = {Brainstorm is a collaborative open-source application dedicated to
	magnetoencephalography (MEG) and electroencephalography (EEG) data
	visualization and processing, with an emphasis on cortical source
	estimation techniques and their integration with anatomical magnetic
	resonance imaging (MRI) data. The primary objective of the software
	is to connect MEG/EEG neuroscience investigators with both the best-established
	and cutting-edge methods through a simple and intuitive graphical
	user interface (GUI).},
  doi = {10.1155/2011/879716},
  institution = { Image Processing Institute, University of Southern California, Los
	Angeles, CA 90089, USA. tadel@usc.edu},
  keywords = {Animals; Automatic Data Processing; Brain Mapping; Brain Waves, physiology;
	Brain, physiology; Computer Graphics; Electroencephalography; Humans;
	Magnetic Resonance Imaging; Magnetoencephalography; Models, Neurological;
	Software; Time Factors; User-Computer Interface},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paupau},
  pmid = {21584256},
  timestamp = {2013.02.17},
  url = {http://dx.doi.org/10.1155/2011/879716}
}

@ARTICLE{Tagliazucchi_2012,
  author = {Enzo Tagliazucchi and Pablo Balenzuela and Daniel Fraiman and Dante
	R Chialvo},
  title = {Criticality in large-scale brain FMRI dynamics unveiled by a novel
	point process analysis.},
  journal = {Front. Physiol.},
  year = {2012},
  volume = {3},
  pages = {15},
  abstract = {Functional magnetic resonance imaging (fMRI) techniques have contributed
	significantly to our understanding of brain function. Current methods
	are based on the analysis of gradual and continuous changes in the
	brain blood oxygenated level dependent (BOLD) signal. Departing from
	that approach, recent work has shown that equivalent results can
	be obtained by inspecting only the relatively large amplitude BOLD
	signal peaks, suggesting that relevant information can be condensed
	in discrete events. This idea is further explored here to demonstrate
	how brain dynamics at resting state can be captured just by the timing
	and location of such events, i.e., in terms of a spatiotemporal point
	process. The method allows, for the first time, to define a theoretical
	framework in terms of an order and control parameter derived from
	fMRI data, where the dynamical regime can be interpreted as one corresponding
	to a system close to the critical point of a second order phase transition.
	The analysis demonstrates that the resting brain spends most of the
	time near the critical point of such transition and exhibits avalanches
	of activity ruled by the same dynamical and statistical properties
	described previously for neuronal events at smaller scales. Given
	the demonstrated functional relevance of the resting state brain
	dynamics, its representation as a discrete process might facilitate
	large-scale analysis of brain function both in health and disease.},
  doi = {10.3389/fphys.2012.00015},
  institution = {Departamento de Física, Facultad de Ciencias Exactas y Naturales,
	Universidad de Buenos Aires Buenos Aires, Argentina.},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {22347863},
  timestamp = {2013.03.05},
  url = {http://dx.doi.org/10.3389/fphys.2012.00015}
}

@MISC{Talton_2004,
  author = {Talton, JO},
  title = {A Short Survey of Mesh Simplification Algorithms},
  howpublished = {manuscript, University of Illinois at Urbana-Champaign, Octoboer},
  month = {October},
  year = {2004},
  abstract = {The problem of approximating a given input mesh with a less complex
	but geometrically faithful representation is well-established in
	computer graphics. Given the visual complexity required to create
	realistic-looking scenes, simplification efforts can be essential
	to efficient rendering.}
}

@ARTICLE{Teeters_2008,
  author = {Jeffrey L Teeters and Kenneth D Harris and K. Jarrod Millman and
	Bruno A Olshausen and Friedrich T Sommer},
  title = {Data sharing for computational neuroscience.},
  journal = {Neuroinformatics},
  year = {2008},
  volume = {6},
  pages = {47--55},
  number = {1},
  abstract = {Computational neuroscience is a subfield of neuroscience that develops
	models to integrate complex experimental data in order to understand
	brain function. To constrain and test computational models, researchers
	need access to a wide variety of experimental data. Much of those
	data are not readily accessible because neuroscientists fall into
	separate communities that study the brain at different levels and
	have not been motivated to provide data to researchers outside their
	community. To foster sharing of neuroscience data, a workshop was
	held in 2007, bringing together experimental and theoretical neuroscientists,
	computer scientists, legal experts and governmental observers. Computational
	neuroscience was recommended as an ideal field for focusing data
	sharing, and specific methods, strategies and policies were suggested
	for achieving it. A new funding area in the NSF/NIH Collaborative
	Research in Computational Neuroscience (CRCNS) program has been established
	to support data sharing, guided in part by the workshop recommendations.
	The new funding area is dedicated to the dissemination of high quality
	data sets with maximum scientific value for computational neuroscience.
	The first round of the CRCNS data sharing program supports the preparation
	of data sets which will be publicly available in 2008. These include
	electrophysiology and behavioral (eye movement) data described towards
	the end of this article.},
  doi = {10.1007/s12021-008-9009-y},
  institution = { Helen Wills Neuroscience Institute, University of California, Berkeley,
	3210F Tolman Hall, MC 3192, Berkeley, CA 94720-3192, USA.},
  keywords = {Access to Information, ethics; Animals; Computational Biology, methods/standards/trends;
	Computer Communication Networks, standards/trends; Computer Simulation,
	standards/trends; Cooperative Behavior; Databases, Factual; Electrophysiology,
	standards/trends; Eye Movements, physiology; Humans; Information
	Storage and Retrieval, standards/trends; Internet, standards/trends;
	Neurosciences, methods/standards/trends; Research Design, standards/trends},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {18259695},
  timestamp = {2013.02.21},
  url = {http://dx.doi.org/10.1007/s12021-008-9009-y}
}

@MISC{HDF5,
  author = {The HDF Group, .},
  title = {Hierarchical data format version 5. http://www.hdfgroup.org/},
  year = {2000-2010},
  owner = {paula},
  timestamp = {2013.04.11},
  url = {http://www.hdfgroup.org/}
}

@ARTICLE{Tohka_2007,
  author = {Jussi Tohka and Evgeny Krestyannikov and Ivo D Dinov and Allan MacKenzie
	Graham and David W Shattuck and Ulla Ruotsalainen and Arthur W Toga},
  title = {Genetic algorithms for finite mixture model based voxel classification
	in neuroimaging.},
  journal = {IEEE Trans. Med. Imag.},
  year = {2007},
  volume = {26},
  pages = {696--711},
  number = {5},
  month = {May},
  abstract = {Finite mixture models (FMMs) are an indispensable tool for unsupervised
	classification in brain imaging. Fitting an FMM to the data leads
	to a complex optimization problem. This optimization problem is difficult
	to solve by standard local optimization methods, such as the expectation-maximization
	(EM) algorithm, if a principled initialization is not available.
	In this paper, we propose a new global optimization algorithm for
	the FMM parameter estimation problem, which is based on real coded
	genetic algorithms. Our specific contributions are two-fold: 1) we
	propose to use blended crossover in order to reduce the premature
	convergence problem to its minimum and 2) we introduce a completely
	new permutation operator specifically meant for the FMM parameter
	estimation. In addition to improving the optimization results, the
	permutation operator allows for imposing biologically meaningful
	constraints to the FMM parameter values. We also introduce a hybrid
	of the genetic algorithm and the EM algorithm for efficient solution
	of multidimensional FMM fitting problems. We compare our algorithm
	to the self-annealing EM-algorithm and a standard real coded genetic
	algorithm with the voxel classification tasks within the brain imaging.
	The algorithms are tested on synthetic data as well as real three-dimensional
	image data from human magnetic resonance imaging, positron emission
	tomography, and mouse brain MRI. The tissue classification results
	by our method are shown to be consistently more reliable and accurate
	than with the competing parameter estimation methods.},
  doi = {10.1109/TMI.2007.895453},
  institution = {Laboratory of Neuro Imaging, Department of Neurology, UCLA School
	of Medicine, University of California, Los Angeles, CA 90095, USA.
	jussi.tohka@tut.fi},
  keywords = {Algorithms; Animals; Artificial Intelligence; Brain, anatomy /&/ histology/radionuclide
	imaging; Computer Simulation; Finite Element Analysis; Humans; Image
	Enhancement, methods; Image Interpretation, Computer-Assisted, methods;
	Imaging, Three-Dimensional, methods; Magnetic Resonance Imaging,
	methods; Mice; Models, Genetic; Models, Neurological; Neuroanatomy,
	methods; Pattern Recognition, Automated, methods; Positron-Emission
	Tomography, methods; Reproducibility of Results; Sensitivity and
	Specificity},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {17518064},
  timestamp = {2013.01.18},
  url = {http://dx.doi.org/10.1109/TMI.2007.895453}
}

@ARTICLE{Tohka_2012,
  author = {Jussi Tohka and Ulla Ruotsalainen},
  title = {Imaging brain change across different time scales.},
  journal = {Front. Neuroinform.},
  year = {2012},
  volume = {6},
  pages = {29},
  doi = {10.3389/fninf.2012.00029},
  institution = {Department of Signal Processing, Tampere University of Technology
	Tampere, Finland.},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {23267327},
  timestamp = {2013.01.18},
  url = {http://dx.doi.org/10.3389/fninf.2012.00029}
}

@ARTICLE{Touboul_2010,
  author = {Jonathan Touboul and Alain Destexhe},
  title = {Can power-law scaling and neuronal avalanches arise from stochastic
	dynamics?},
  journal = {PLoS One},
  year = {2010},
  volume = {5},
  pages = {e8982},
  number = {2},
  abstract = {The presence of self-organized criticality in biology is often evidenced
	by a power-law scaling of event size distributions, which can be
	measured by linear regression on logarithmic axes. We show here that
	such a procedure does not necessarily mean that the system exhibits
	self-organized criticality. We first provide an analysis of multisite
	local field potential (LFP) recordings of brain activity and show
	that event size distributions defined as negative LFP peaks can be
	close to power-law distributions. However, this result is not robust
	to change in detection threshold, or when tested using more rigorous
	statistical analyses such as the Kolmogorov-Smirnov test. Similar
	power-law scaling is observed for surrogate signals, suggesting that
	power-law scaling may be a generic property of thresholded stochastic
	processes. We next investigate this problem analytically, and show
	that, indeed, stochastic processes can produce spurious power-law
	scaling without the presence of underlying self-organized criticality.
	However, this power-law is only apparent in logarithmic representations,
	and does not survive more rigorous analysis such as the Kolmogorov-Smirnov
	test. The same analysis was also performed on an artificial network
	known to display self-organized criticality. In this case, both the
	graphical representations and the rigorous statistical analysis reveal
	with no ambiguity that the avalanche size is distributed as a power-law.
	We conclude that logarithmic representations can lead to spurious
	power-law scaling induced by the stochastic nature of the phenomenon.
	This apparent power-law scaling does not constitute a proof of self-organized
	criticality, which should be demonstrated by more stringent statistical
	tests.},
  doi = {10.1371/journal.pone.0008982},
  institution = {Department of Mathematics, University of Pittsburgh, Pittsburgh,
	Pennsylvania, United States of America.},
  keywords = {Algorithms; Animals; Cats; Cerebral Cortex, cytology/physiology; Models,
	Neurological; Neural Networks (Computer); Neurons, cytology/physiology;
	Stochastic Processes},
  language = {eng},
  medline-pst = {epublish},
  owner = {paula},
  pmid = {20161798},
  timestamp = {2013.03.05},
  url = {http://dx.doi.org/10.1371/journal.pone.0008982}
}

@ARTICLE{Tuere_2000,
  author = {U. Türe and M. G. Yaşargil and A. H. Friedman and O. Al-Mefty},
  title = {Fiber dissection technique: lateral aspect of the brain.},
  journal = {Neurosurgery},
  year = {2000},
  volume = {47},
  pages = {417--26; discussion 426-7},
  number = {2},
  month = {Aug},
  abstract = {The fiber dissection technique involves peeling away the white matter
	tracts of the brain to display its three-dimensional anatomic organization.
	Early anatomists demonstrated many tracts and fasciculi of the brain
	using this technique. The complexities of the preparation of the
	brain and the execution of fiber dissection have led to the neglect
	of this method, particularly since the development of the microtome
	and histological techniques. Nevertheless, the fiber dissection technique
	is a very relevant and reliable method for neurosurgeons to study
	the details of brain anatomic features.Twenty previously frozen,
	formalin-fixed human brains were dissected from the lateral surface
	to the medial surface, using the operating microscope. Each stage
	of the process is described. The primary dissection tools were handmade,
	thin, wooden spatulas with tips of various sizes.We exposed and studied
	the myelinated fiber bundles of the brain and acquired a comprehensive
	understanding of their configurations and locations.The complex structures
	of the brain can be more clearly defined and understood when the
	fiber dissection technique is used. This knowledge can be incorporated
	into the preoperative planning process and applied to surgical strategies.
	Fiber dissection is time-consuming and complex, but it greatly adds
	to our knowledge of brain anatomic features and thus helps improve
	the quality of microneurosurgery. Because other anatomic techniques
	fail to provide a true understanding of the complex internal structures
	of the brain, the reestablishment of fiber dissection of white matter
	as a standard study method is recommended.},
  institution = {Department of Neurosurgery, Marmara University School of Medicine,
	Istanbul, Turkey. ugurture@turk.net},
  keywords = {Brain, anatomy /&/ histology/surgery; Cadaver; Dissection, methods;
	Humans},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {10942015},
  timestamp = {2013.07.04}
}

@OTHER{Turner_1998,
  abstract = {It is now feasible to create spatial maps of activity in the human
	brain completely non-invasively using magnetic resonance imaging.
	Magnetic resonance imaging (MRI) images in which the spin magnetization
	is refocussed by gradient switching are sensitive to local changes
	in magnetic susceptibility, which can occur when the oxygenation
	state of blood changes. Cortical neural activity causes increases
	in blood flow, which usually result in changes in blood oxygenation.
	Hence changes of image intensity can be observed, given rise to the
	socalled Blood Oxygenation Level Dependent (BOLD) contrast technique.
	Use of echo-planar imaging methods (EPI) allows the monitoring over
	the entire brain of such changes in real time. A temporal resolution
	of 13 s, and a spatial resolution of 2 mm in-plane, can thus be obtained.
	Generally in a brain mapping experiment hundred of brain image volumes
	are acquired at repeat times of 16 s, while brain tasks are performed.
	The data are transformed into statist...},
  author = {Turner, Robert and Howseman, Alastair and Geraint E. Rees and Josephs,
	Oliver and Friston, Karl and Turner, R. and Howseman, A. and Rees,
	G. E. and Josephs, O. and Friston, K.},
  owner = {paupau},
  timestamp = {2013.08.21},
  title = {Functional Magnetic Resonance Imaging of the Human Brain: Data Acquisition
	and Analysis},
  year = {1998}
}

@ARTICLE{Valdes-Hernandez2011,
  author = {Pedro Antonio Valdés-Hernández and Akira Sumiyoshi and Hiroi Nonaka
	and Risa Haga and Eduardo Aubert-Vásquez and Takeshi Ogawa and Yasser
	Iturria-Medina and Jorge J Riera and Ryuta Kawashima},
  title = {An in vivo MRI Template Set for Morphometry, Tissue Segmentation,
	and fMRI Localization in Rats.},
  journal = {Front Neuroinform},
  year = {2011},
  volume = {5},
  pages = {26},
  abstract = {Over the last decade, several papers have focused on the construction
	of highly detailed mouse high field magnetic resonance image (MRI)
	templates via non-linear registration to unbiased reference spaces,
	allowing for a variety of neuroimaging applications such as robust
	morphometric analyses. However, work in rats has only provided medium
	field MRI averages based on linear registration to biased spaces
	with the sole purpose of approximate functional MRI (fMRI) localization.
	This precludes any morphometric analysis in spite of the need of
	exploring in detail the neuroanatomical substrates of diseases in
	a recent advent of rat models. In this paper we present a new in
	vivo rat T2 MRI template set, comprising average images of both intensity
	and shape, obtained via non-linear registration. Also, unlike previous
	rat template sets, we include white and gray matter probabilistic
	segmentations, expanding its use to those applications demanding
	prior-based tissue segmentation, e.g., statistical parametric mapping
	(SPM) voxel-based morphometry. We also provide a preliminary digitalization
	of latest Paxinos and Watson atlas for anatomical and functional
	interpretations within the cerebral cortex. We confirmed that, like
	with previous templates, forepaw and hindpaw fMRI activations can
	be correctly localized in the expected atlas structure. To exemplify
	the use of our new MRI template set, were reported the volumes of
	brain tissues and cortical structures and probed their relationships
	with ontogenetic development. Other in vivo applications in the near
	future can be tensor-, deformation-, or voxel-based morphometry,
	morphological connectivity, and diffusion tensor-based anatomical
	connectivity. Our template set, freely available through the SPM
	extension website, could be an important tool for future longitudinal
	and/or functional extensive preclinical studies.},
  doi = {10.3389/fninf.2011.00026},
  institution = {Department of Neuroimaging, Cuban Neuroscience Center Havana, Cuba.},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {22275894},
  timestamp = {2013.07.04},
  url = {http://dx.doi.org/10.3389/fninf.2011.00026}
}

@ARTICLE{Valdes-Sosa_2011,
  author = {Pedro A Valdes-Sosa and Alard Roebroeck and Jean Daunizeau and Karl
	Friston},
  title = {Effective connectivity: influence, causality and biophysical modeling.},
  journal = {Neuroimage},
  year = {2011},
  volume = {58},
  pages = {339--361},
  number = {2},
  month = {Sep},
  abstract = {This is the final paper in a Comments and Controversies series dedicated
	to "The identification of interacting networks in the brain using
	fMRI: Model selection, causality and deconvolution". We argue that
	discovering effective connectivity depends critically on state-space
	models with biophysically informed observation and state equations.
	These models have to be endowed with priors on unknown parameters
	and afford checks for model Identifiability. We consider the similarities
	and differences among Dynamic Causal Modeling, Granger Causal Modeling
	and other approaches. We establish links between past and current
	statistical causal modeling, in terms of Bayesian dependency graphs
	and Wiener-Akaike-Granger-Schweder influence measures. We show that
	some of the challenges faced in this field have promising solutions
	and speculate on future developments.},
  doi = {10.1016/j.neuroimage.2011.03.058},
  institution = {Cuban Neuroscience Center, Ave 25 \#15202 esquina 158, Cubanacan,
	Playa, Cuba. peter@cneuro.edu.cu},
  keywords = {Algorithms; Bayes Theorem; Biophysics; Causality; Data Interpretation,
	Statistical; Electroencephalography; Image Processing, Computer-Assisted,
	methods/statistics /&/ numerical data; Magnetic Resonance Imaging;
	Markov Chains; Models, Neurological; Nerve Net, anatomy /&/ histology/physiology;
	Neural Pathways, anatomy /&/ histology/physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S1053-8119(11)00337-5},
  pmid = {21477655},
  timestamp = {2013.02.14},
  url = {http://dx.doi.org/10.1016/j.neuroimage.2011.03.058}
}

@ARTICLE{Valdes-Sosa_2009,
  author = {Valdes-Sosa, Pedro A. and Sanchez-Bornot, Jose Miguel and Sotero,
	Roberto Carlos and Iturria-Medina, Yasser and Aleman-Gomez, Yasser
	and Bosch-Bayard, Jorge and Carbonell, Felix and Ozaki, Tohru},
  title = {Model driven EEG/fMRI fusion of brain oscillations.},
  journal = {Hum. Brain Mapp.},
  year = {2009},
  volume = {30},
  pages = {2701--2721},
  number = {9},
  month = {Sep},
  abstract = {This article reviews progress and challenges in model driven EEG/fMRI
	fusion with a focus on brain oscillations. Fusion is the combination
	of both imaging modalities based on a cascade of forward models from
	ensemble of post-synaptic potentials (ePSP) to net primary current
	densities (nPCD) to EEG; and from ePSP to vasomotor feed forward
	signal (VFFSS) to BOLD. In absence of a model, data driven fusion
	creates maps of correlations between EEG and BOLD or between estimates
	of nPCD and VFFS. A consistent finding has been that of positive
	correlations between EEG alpha power and BOLD in both frontal cortices
	and thalamus and of negative ones for the occipital region. For model
	driven fusion we formulate a neural mass EEG/fMRI model coupled to
	a metabolic hemodynamic model. For exploratory simulations we show
	that the Local Linearization (LL) method for integrating stochastic
	differential equations is appropriate for highly nonlinear dynamics.
	It has been successfully applied to small and medium sized networks,
	reproducing the described EEG/BOLD correlations. A new LL-algebraic
	method allows simulations with hundreds of thousands of neural populations,
	with connectivities and conduction delays estimated from diffusion
	weighted MRI. For parameter and state estimation, Kalman filtering
	combined with the LL method estimates the innovations or prediction
	errors. From these the likelihood of models given data are obtained.
	The LL-innovation estimation method has been already applied to small
	and medium scale models. With improved Bayesian computations the
	practical estimation of very large scale EEG/fMRI models shall soon
	be possible.},
  doi = {10.1002/hbm.20704},
  institution = {Cuban Neuroscience Center, Havana, Cuba. peter@cneuro.edu.cu},
  keywords = {Bayes Theorem; Biological Clocks, physiology; Brain Mapping, methods;
	Brain, anatomy /&/ histology/physiology; Cerebrovascular Circulation,
	physiology; Computer Simulation; Electroencephalography, methods;
	Evoked Potentials, physiology; Humans; Magnetic Resonance Imaging,
	methods; Nerve Net, physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paupau},
  pmid = {19107753},
  timestamp = {2013.04.09},
  url = {http://dx.doi.org/10.1002/hbm.20704}
}

@ARTICLE{VanOosterom_1983,
  author = {Van Oosterom, A. and Strackee, J.},
  title = {The solid angle of a plane triangle},
  journal = {IEEE Trans. Biomed. Eng.},
  year = {1983},
  volume = {30},
  pages = {125--126},
  number = {2},
  doi = {10.1109/TBME.1983.325207},
  issn = {0018-9294}
}

@ARTICLE{Varoquaux_2013,
  author = {Gaël Varoquaux and R. Cameron Craddock},
  title = {Learning and comparing functional connectomes across subjects.},
  journal = {Neuroimage},
  year = {2013},
  volume = {80},
  pages = {405--415},
  month = {Oct},
  abstract = {Functional connectomes capture brain interactions via synchronized
	fluctuations in the functional magnetic resonance imaging signal.
	If measured during rest, they map the intrinsic functional architecture
	of the brain. With task-driven experiments they represent integration
	mechanisms between specialized brain areas. Analyzing their variability
	across subjects and conditions can reveal markers of brain pathologies
	and mechanisms underlying cognition. Methods of estimating functional
	connectomes from the imaging signal have undergone rapid developments
	and the literature is full of diverse strategies for comparing them.
	This review aims to clarify links across functional-connectivity
	methods as well as to expose different steps to perform a group study
	of functional connectomes.},
  doi = {10.1016/j.neuroimage.2013.04.007},
  institution = {Parietal project-team, INRIA Saclay-île de France, France; INSERM,
	U992, France; CEA/Neurospin bât 145, 91191 Gif-Sur-Yvette, France.
	Electronic address: gael.varoquaux@inria.fr.},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S1053-8119(13)00334-0},
  pmid = {23583357},
  timestamp = {2013.08.20},
  url = {http://dx.doi.org/10.1016/j.neuroimage.2013.04.007}
}

@ARTICLE{Verduzco-Flores_2009,
  author = {Sergio Verduzco-Flores and Bard Ermentrout and Mark Bodner},
  title = {From working memory to epilepsy: dynamics of facilitation and inhibition
	in a cortical network.},
  journal = {Chaos},
  year = {2009},
  volume = {19},
  pages = {015115},
  number = {1},
  month = {Mar},
  abstract = {Persistent states are believed to be the correlate for short-term
	or working memory. Using a previously derived model for working memory,
	we show that disruption of the lateral inhibition can lead to a variety
	of pathological states. These states are analogs of reflex or pattern-sensitive
	epilepsy. Simulations, numerical bifurcation analysis, and fast-slow
	decomposition are used to explore the dynamics of this network.},
  doi = {10.1063/1.3080663},
  institution = {University of Pittsburgh, Pittsburgh, Pennsylvania 15260, USA.},
  keywords = {Action Potentials, physiology; Algorithms; Animals; Biophysics, methods;
	Epilepsy; Humans; Memory; Models, Biological; Nerve Net, physiology;
	Neural Inhibition, physiology; Neurons, cytology/metabolism/physiology;
	Nonlinear Dynamics; Seizures, physiopathology; Time Factors},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {19335019},
  timestamp = {2013.09.04},
  url = {http://dx.doi.org/10.1063/1.3080663}
}

@ARTICLE{Victor_2011,
  author = {Jonathan D Victor and Jonathan D Drover and Mary M Conte and Nicholas
	D Schiff},
  title = {Mean-field modeling of thalamocortical dynamics and a model-driven
	approach to EEG analysis.},
  journal = {Proc Natl Acad Sci U S A},
  year = {2011},
  volume = {108 Suppl 3},
  pages = {15631--15638},
  month = {Sep},
  abstract = {Higher brain function depends on task-dependent information flow between
	cortical regions. Converging lines of evidence suggest that interactions
	between cortical regions and the central thalamus play a key role
	in establishing the dynamic patterns of functional connectivity that
	normally support these processes. In patients with chronic disturbances
	of cognitive function due to severe brain injury, dysfunction of
	this circuitry likely plays a crucial role in pathogenesis. However,
	assaying thalamocortical interactions is challenging even in healthy
	subjects and more so in severely impaired patients. To approach this
	problem, we apply a dynamical-systems approach to motivate an analysis
	of the electroencephalogram (EEG). We begin with a model for a single
	thalamocortical module [Robinson PA, Rennie CJ, Rowe DL (2002) Phys
	Rev E Stat Nonlin Soft Matter Phys 65:041924; Robinson PA, Rennie
	CJ, Wright JJ, Bourke PD (1998) Phys Rev E Stat Nonlin Soft Matter
	Phys 58:3557-3571]. When two such modules interact via shared thalamic
	inhibition, multistable behavior emerges; each mode is characterized
	by a different pattern of coherence between cortical regions. This
	observation suggests that changing patterns of cortical coherence
	are a hallmark of normal thalamocortical dynamics. In a preliminary
	study, we test this idea by analyzing the EEG of a patient with chronic
	brain injury, who has a marked improvement in behavior and frontal
	brain metabolism in response to zolpidem. The analysis shows that
	following zolpidem administration, changing patterns of coherence
	are identified between the frontal lobes and between frontal and
	distant brain regions. These observations support the role of the
	central thalamus in the organization of patterns of cortical interactions
	and suggest how indexes of thalamocortical dynamics can be extracted
	from the EEG.},
  doi = {10.1073/pnas.1012168108},
  institution = {Division of Systems Neurology and Neuroscience, Department of Neurology
	and Neuroscience, Weill Cornell Medical College, New York, NY 10065,
	USA. jdvicto@med.cornell.edu},
  keywords = {Adult; Behavior, physiology; Cerebral Cortex, physiology; Electroencephalography,
	methods; Humans; Male; Models, Neurological; Thalamus, physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {1012168108},
  pmid = {21368177},
  timestamp = {2013.08.23},
  url = {http://dx.doi.org/10.1073/pnas.1012168108}
}

@ARTICLE{Vreeswijk_1994,
  author = {C. Van Vreeswijk and L. F. Abbott and G. B. Ermentrout},
  title = {When inhibition not excitation synchronizes neural firing.},
  journal = {J Comput Neurosci},
  year = {1994},
  volume = {1},
  pages = {313--321},
  number = {4},
  month = {Dec},
  abstract = {Excitatory and inhibitory synaptic coupling can have counter-intuitive
	effects on the synchronization of neuronal firing. While it might
	appear that excitatory coupling would lead to synchronization, we
	show that frequently inhibition rather than excitation synchronizes
	firing. We study two identical neurons described by integrate-and-fire
	models, general phase-coupled models or the Hodgkin-Huxley model
	with mutual, non-instantaneous excitatory or inhibitory synapses
	between them. We find that if the rise time of the synapse is longer
	than the duration of an action potential, inhibition not excitation
	leads to synchronized firing.},
  institution = {Center for Complex Systems, Brandeis University, Waltham, MA 02254,
	USA.},
  keywords = {Action Potentials, physiology; Animals; Neural Networks (Computer);
	Neurons, physiology; Synapses, physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {8792237},
  timestamp = {2013.09.04}
}

@ARTICLE{Wakana_2004,
  author = {Wakana, S. and Jiang, H. and Nagae-Poetscher, L.M. and van Zijl,
	P. and Mori, S.},
  title = {{Fiber Tract--based Atlas of Human White Matter Anatomy1}},
  journal = {Radiology},
  year = {2004},
  volume = {230},
  pages = {77},
  number = {1},
  issn = {0033-8419},
  publisher = {Radiological Society of North America}
}

@ARTICLE{Wang_2011,
  author = {Sheng-Jun Wang and Claus C Hilgetag and Changsong Zhou},
  title = {Sustained activity in hierarchical modular neural networks: self-organized
	criticality and oscillations.},
  journal = {Front. Comput. Neurosci.},
  year = {2011},
  volume = {5},
  pages = {30},
  abstract = {Cerebral cortical brain networks possess a number of conspicuous features
	of structure and dynamics. First, these networks have an intricate,
	non-random organization. In particular, they are structured in a
	hierarchical modular fashion, from large-scale regions of the whole
	brain, via cortical areas and area subcompartments organized as structural
	and functional maps to cortical columns, and finally circuits made
	up of individual neurons. Second, the networks display self-organized
	sustained activity, which is persistent in the absence of external
	stimuli. At the systems level, such activity is characterized by
	complex rhythmical oscillations over a broadband background, while
	at the cellular level, neuronal discharges have been observed to
	display avalanches, indicating that cortical networks are at the
	state of self-organized criticality (SOC). We explored the relationship
	between hierarchical neural network organization and sustained dynamics
	using large-scale network modeling. Previously, it was shown that
	sparse random networks with balanced excitation and inhibition can
	sustain neural activity without external stimulation. We found that
	a hierarchical modular architecture can generate sustained activity
	better than random networks. Moreover, the system can simultaneously
	support rhythmical oscillations and SOC, which are not present in
	the respective random networks. The mechanism underlying the sustained
	activity is that each dense module cannot sustain activity on its
	own, but displays SOC in the presence of weak perturbations. Therefore,
	the hierarchical modular networks provide the coupling among subsystems
	with SOC. These results imply that the hierarchical modular architecture
	of cortical networks plays an important role in shaping the ongoing
	spontaneous activity of the brain, potentially allowing the system
	to take advantage of both the sensitivity of critical states and
	the predictability and timing of oscillations for efficient information
	processing.},
  doi = {10.3389/fncom.2011.00030},
  institution = {Department of Physics, Hong Kong Baptist University Hong Kong, China.},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {21852971},
  timestamp = {2013.03.05},
  url = {http://dx.doi.org/10.3389/fncom.2011.00030}
}

@ARTICLE{Werner_2007,
  author = {Gerhard Werner},
  title = {Brain dynamics across levels of organization.},
  journal = {J. Physiol. Paris},
  year = {2007},
  volume = {101},
  pages = {273--279},
  number = {4-6},
  abstract = {After initially presenting evidence that the electrical activity recorded
	from the brain surface can reflect metastable state transitions of
	neuronal configurations at the mesoscopic level, I will suggest that
	their patterns may correspond to the distinctive spatio-temporal
	activity in the dynamic core (DC) and the global neuronal workspace
	(GNW), respectively, in the models of the Edelman group on the one
	hand, and of Dehaene-Changeux, on the other. In both cases, the recursively
	reentrant activity flow in intra-cortical and cortical-subcortical
	neuron loops plays an essential and distinct role. Reasons will be
	given for viewing the temporal characteristics of this activity flow
	as signature of self-organized criticality (SOC), notably in reference
	to the dynamics of neuronal avalanches. This point of view enables
	the use of statistical physics approaches for exploring phase transitions,
	scaling and universality properties of DC and GNW, with relevance
	to the macroscopic electrical activity in EEG and EMG.},
  doi = {10.1016/j.jphysparis.2007.12.001},
  institution = {Department of Biomedical Engineering, University of Texas, Austin,
	Engineering Science Building, 1 University Station, C0800 Austin,
	TX 78712-0238, USA. gwer1@mail.utexas.edu},
  keywords = {Brain Mapping; Brain, physiology; Humans; Mental Processes, physiology;
	Models, Neurological; Nonlinear Dynamics},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S0928-4257(07)00062-9},
  pmid = {18267356},
  timestamp = {2013.03.05},
  url = {http://dx.doi.org/10.1016/j.jphysparis.2007.12.001}
}

@ARTICLE{Whittington_2000,
  author = {M. A. Whittington and R. D. Traub and N. Kopell and B. Ermentrout
	and E. H. Buhl},
  title = {Inhibition-based rhythms: experimental and mathematical observations
	on network dynamics.},
  journal = {Int J Psychophysiol},
  year = {2000},
  volume = {38},
  pages = {315--336},
  number = {3},
  month = {Dec},
  abstract = {An increasingly large body of data exists which demonstrates that
	oscillations of frequency 12-80 Hz are a consequence of, or are inextricably
	linked to, the behaviour of inhibitory interneurons in the central
	nervous system. This frequency range covers the EEG bands beta 1
	(12-20 Hz), beta 2 (20-30 Hz) and gamma (30-80 Hz). The pharmacological
	profile of both spontaneous and sensory-evoked EEG potentials reveals
	a very strong influence on these rhythms by drugs which have direct
	effects on GABA(A) receptor-mediated synaptic transmission (general
	anaesthetics, sedative/hypnotics) or indirect effects on inhibitory
	neuronal function (opiates, ketamine). In addition, a number of experimental
	models of, in particular, gamma-frequency oscillations, have revealed
	both common denominators for oscillation generation and function,
	and subtle differences in network dynamics between the different
	frequency ranges. Powerful computer and mathematical modelling techniques
	based around both clinical and experimental observations have recently
	provided invaluable insight into the behaviour of large networks
	of interconnected neurons. In particular, the mechanistic profile
	of oscillations generated as an emergent property of such networks,
	and the mathematical derivation of this complex phenomenon have much
	to contribute to our understanding of how and why neurons oscillate.
	This review will provide the reader with a brief outline of the basic
	properties of inhibition-based oscillations in the CNS by combining
	research from laboratory models, large-scale neuronal network simulations,
	and mathematical analysis.},
  institution = {School of Biomedical Sciences, The Worsley Building, University of
	Leeds, LS2 9NL, Leeds, UK. m.whittington@leeds.ac.uk},
  keywords = {Electroencephalography; Humans; Models, Biological; Neural Networks
	(Computer)},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S0167876000001732},
  pmid = {11102670},
  timestamp = {2013.09.04}
}

@ARTICLE{Wilson_1973,
  author = {Wilson, HR and JD Cowan},
  title = {A mathematical theory of the functional dynamics of cortical and
	thalamic nervous tissue.},
  journal = {Kybernetik},
  year = {1973},
  volume = {13},
  pages = {55--80},
  number = {2},
  month = {Sep},
  keywords = {Animals; Cerebral Cortex, physiology; Cybernetics; Electrophysiology;
	Humans; Mathematics; Models, Neurological; Rabbits; Thalamus, physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {4767470},
  timestamp = {2013.02.18}
}

@ARTICLE{Wilson_1972,
  author = {Wilson, HR and Cowan, JD},
  title = {Excitatory and inhibitory interactions in localized populations of
	model neurons},
  journal = {Biophys. J.},
  year = {1972},
  volume = {12},
  pages = {1-24},
  number = {1},
  month = {January},
  abstract = {Coupled nonlinear differential equations are derived for the dynamics
	of spatially localized populations containing both excitatory and
	inhibitory model neurons. Phase plane methods and numerical solutions
	are then used to investigate population responses to various types
	of stimuli. The results obtained show simple and multiple hysteresis
	phenomena and limit cycle activity. The latter is particularly interesting
	since the frequency of the limit cycle oscillation is found to be
	a monotonic function of stimulus intensity. Finally, it is proved
	that the existence of limit cycle dynamics in response to one class
	of stimuli implies the existence of multiple stable states and hysteresis
	in response to a different class of stimuli. The relation between
	these findings and a number of experiments is discussed.},
  keywords = {model},
  owner = {paula},
  timestamp = {2012.10.18}
}

@ARTICLE{Wong_2006,
  author = {Kong-Fatt Wong and Xiao-Jing Wang},
  title = {A Recurrent Network Mechanism of Time Integration in Perceptual Decisions},
  journal = {J. Neurosci.},
  year = {2006},
  volume = {26},
  pages = {1314-1328},
  number = {4},
  owner = {paula},
  timestamp = {2012.12.11}
}

@ARTICLE{Woolrich_2009,
  author = {Woolrich, Mark W. and Jbabdi, Saad and Patenaude, Brian and Chappell,
	Michael and Makni, Salima and Behrens, Timothy and Beckmann, Christian
	and Jenkinson, Mark and Smith, Stephen M.},
  title = {Bayesian analysis of neuroimaging data in FSL.},
  journal = {Neuroimage},
  year = {2009},
  volume = {45},
  pages = {S173--S186},
  number = {1 Suppl},
  month = {Mar},
  abstract = {Typically in neuroimaging we are looking to extract some pertinent
	information from imperfect, noisy images of the brain. This might
	be the inference of percent changes in blood flow in perfusion FMRI
	data, segmentation of subcortical structures from structural MRI,
	or inference of the probability of an anatomical connection between
	an area of cortex and a subthalamic nucleus using diffusion MRI.
	In this article we will describe how Bayesian techniques have made
	a significant impact in tackling problems such as these, particularly
	in regards to the analysis tools in the FMRIB Software Library (FSL).
	We shall see how Bayes provides a framework within which we can attempt
	to infer on models of neuroimaging data, while allowing us to incorporate
	our prior belief about the brain and the neuroimaging equipment in
	the form of biophysically informed or regularising priors. It allows
	us to extract probabilistic information from the data, and to probabilistically
	combine information from multiple modalities. Bayes can also be used
	to not only compare and select between models of different complexity,
	but also to infer on data using committees of models. Finally, we
	mention some analysis scenarios where Bayesian methods are impractical,
	and briefly discuss some practical approaches that we have taken
	in these cases.},
  doi = {10.1016/j.neuroimage.2008.10.055},
  institution = {University of Oxford Centre for Functional MRI of the Brain, UK.
	woolrich@fmrib.ox.ac.uk},
  keywords = {Bayes Theorem; Brain, anatomy /&/ histology; Diffusion Magnetic Resonance
	Imaging; Humans; Image Interpretation, Computer-Assisted, methods;
	Software},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paupau},
  pii = {S1053-8119(08)01204-4},
  pmid = {19059349},
  timestamp = {2013.10.24},
  url = {http://dx.doi.org/10.1016/j.neuroimage.2008.10.055}
}

@ARTICLE{Wright_1996,
  author = {Wright,J. J. and Liley,D. T. J.},
  title = {Dynamics of the brain at global and microscopic scales: Neural networks
	and the EEG},
  journal = {Behav. Brain. Sci.},
  year = {1996},
  volume = {19},
  pages = {285-295},
  number = {02},
  doi = {10.1017/S0140525X00042679}
}

@ARTICLE{Wright_1995,
  author = {J. J. Wright and D. T. J. Liley},
  title = {Simulation of electrocortical waves.},
  journal = {Biol. Cybern.},
  year = {1995},
  volume = {72},
  pages = {347--356},
  number = {4},
  abstract = {We report simulations of the electrocorticogram of the cat and human,
	based on estimates of fibre range, fibre density, axonal and dendritic
	delays, and cortical synaptic density. The long-range cortical connections
	of real cortex were simplified to couplings of symmetric density,
	decreasing in density with range, on a closed (toroidal) surface.
	Non-specific cortical activation was modelled as a diffuse global
	input and specific sensory input as a localised white noise input.
	Spectral properties of output included peak densities at the frequencies
	of the major cerebral rhythms, a '1/f' spectral envelope and 'shift
	to the right' with increasing total power as non-specific activation
	increased. Steady-state travelling waves with a velocity of 5-7 m/s
	(human) and < 1 m/s (cat) were produced. Frequency/wavenumber analysis
	revealed an additional class of activity with wavenumbers independent
	of temporal frequency. All these findings accord qualitatively and
	quantitatively with existing physiological results. Global resonant
	modes were not prominent, but the simulations obey a restricted case
	of the analytical results of Nunez (1994). Wave/pulse relations resemble
	the findings of Freeman (1975).},
  institution = {Mental Health Research Institute, Melbourne, Australia.},
  keywords = {Animals; Brain, physiology; Cats; Computer Simulation; Electroencephalography;
	Humans; Models, Neurological; Neural Conduction; Pyramidal Cells,
	physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {7748961},
  timestamp = {2013.02.18}
}

@ARTICLE{Wright_2003,
  author = {J. J. Wright and C. J. Rennie and G. J. Lees and P. A. Robinson and
	P. D. Bourke and C. L. Chapman and E. Gordon and D. L. Rowe},
  title = {Simulated electrocortical activity at microscopic, mesoscopic, and
	global scales.},
  journal = {Neuropsychopharmacology},
  year = {2003},
  volume = {28 Suppl 1},
  pages = {S80--S93},
  month = {Jul},
  abstract = {Simulation of electrocortical activity requires (a) determination
	of the most crucial features to be modelled, (b) specification of
	state equations with parameters that can be determined against independent
	measurements, and (c) explanation of electrical events in the brain
	at several scales. We report our attempts to address these problems,
	and show that mutually consistent explanations, and simulation of
	experimental data can be achieved for cortical gamma activity, synchronous
	oscillation, and the main features of the EEG power spectrum including
	the cerebral rhythms and evoked potentials. These simulations include
	consideration of dendritic and synaptic dynamics, AMPA, NMDA, and
	GABA receptors, and intracortical and cortical/subcortical interactions.
	We speculate on the way in which Hebbian learning and intrinsic reinforcement
	processes might complement the brain dynamics thus explained, to
	produce elementary cognitive operations.},
  doi = {10.1038/sj.npp.1300138},
  institution = {Brain Dynamics Centre, Westmead Hospital and University of Sydney,
	Westmead, NSW 2145, Australia. jjw@mhri.edu.au},
  keywords = {Animals; Cerebral Cortex, physiology; Electroencephalography, methods/statistics
	/&/ numerical data; Humans; Microscopy, methods/statistics /&/ numerical
	data; Models, Neurological; Neurons, physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {1300138},
  pmid = {12827148},
  timestamp = {2013.08.23},
  url = {http://dx.doi.org/10.1038/sj.npp.1300138}
}

@ARTICLE{Wright_2001,
  author = {J. J. Wright and P. A. Robinson and C. J. Rennie and E. Gordon and
	P. D. Bourke and C. L. Chapman and N. Hawthorn and G. J. Lees and
	D. Alexander},
  title = {Toward an integrated continuum model of cerebral dynamics: the cerebral
	rhythms, synchronous oscillation and cortical stability.},
  journal = {Biosystems},
  year = {2001},
  volume = {63},
  pages = {71--88},
  number = {1-3},
  abstract = {Continuum models of cerebral cortex with parameters derived from physiological
	data, provide explanations of the cerebral rhythms, synchronous oscillation,
	and autonomous cortical activity in the gamma frequency range, and
	suggest possible mechanisms for dynamic self-organization in the
	brain. Dispersion relations and derivations of power spectral response
	for the models, show that a low frequency resonant mode and associated
	travelling wave solutions of the models' equations of state can account
	for the predominant 1/f spectral content of the electroencephalogram
	(EEG). Large scale activity in the alpha, beta, and gamma bands,
	is accounted for by thalamocortical interaction, under regulation
	by diffuse cortical excitation. System impulse responses can be used
	to model Event-Related Potentials. Further classes of local resonance
	may be generated by rapid negative feedbacks at active synapses.
	Activity in the gamma band around 40 Hz, associated with large amplitude
	oscillations of pulse density, appears at higher levels of cortical
	activation, and is unstable unless compensated by synaptic feedbacks.
	Control of cortical stability by synaptic feedbacks offers a partial
	account of the regulation of autonomous activity within the cortex.
	Synchronous oscillation occurs between concurrently excited cortical
	sites, and can be explained by analysis of wave motion radiating
	from each of the co-active sites. These models are suitable for the
	introduction of learning rules-most notably the coherent infomax
	rule.},
  institution = {Brain Dynamics Laboratory, Mental Health Research Institute of Victoria,
	Melbourne, Australia. jjw@mhri.edu.au},
  keywords = {Cerebral Cortex, physiology; Electroencephalography; Models, Neurological;
	Periodicity},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S0303264701001484},
  pmid = {11595331},
  timestamp = {2013.08.23}
}

@ARTICLE{Wu_2013,
  author = {Guo-Rong Wu and Wei Liao and Sebastiano Stramaglia and Huafu Chen
	and Daniele Marinazzo},
  title = {Recovering directed networks in neuroimaging datasets using partially
	conditioned Granger causality.},
  journal = {Brain Connect},
  year = {2013},
  volume = {3},
  pages = {294--301},
  number = {3},
  abstract = {Recovering directed pathways of information transfer between brain
	areas is an important issue in neuroscience and helps to shed light
	on the brain function in several physiological and cognitive states.
	Granger causality (GC) analysis is a valuable tool to detect directed
	dynamical connectivity, and it is being increasingly used. Unfortunately,
	this approach encounters some limitations in particularly when applied
	to neuroimaging datasets, often consisting in short and noisy data
	and for which redundancy plays an important role. In this article,
	we address one of these limitations, namely, the computational and
	conceptual problems arising when conditional GC, necessary to disambiguate
	direct and mediated influences, is used on short and noisy datasets
	of many variables, as it is typically the case in some electroencephalography
	(EEG) protocols and in functional magnetic resonance imaging (fMRI).
	We show that considering GC in the framework of information theory
	we can limit the conditioning to a limited number of variables chosen
	as the most informative, obtaining more stable and reliable results
	both in EEG and fMRI data.},
  doi = {10.1089/brain.2013.0142},
  institution = {Department of Data Analysis, Faculty of Psychology and Educational
	Sciences, Ghent University, Ghent, Belgium.},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {23530810},
  timestamp = {2013.08.30},
  url = {http://dx.doi.org/10.1089/brain.2013.0142}
}

@ARTICLE{Yan_2013a,
  author = {Chao-Gan Yan and Brian Cheung and Clare Kelly and Stan Colcombe and
	R. Cameron Craddock and Adriana Di Martino and Qingyang Li and Xi-Nian
	Zuo and F. Xavier Castellanos and Michael P Milham},
  title = {A comprehensive assessment of regional variation in the impact of
	head micromovements on functional connectomics.},
  journal = {Neuroimage},
  year = {2013},
  volume = {76},
  pages = {183--201},
  month = {Aug},
  abstract = {Functional connectomics is one of the most rapidly expanding areas
	of neuroimaging research. Yet, concerns remain regarding the use
	of resting-state fMRI (R-fMRI) to characterize inter-individual variation
	in the functional connectome. In particular, recent findings that
	"micro" head movements can introduce artifactual inter-individual
	and group-related differences in R-fMRI metrics have raised concerns.
	Here, we first build on prior demonstrations of regional variation
	in the magnitude of framewise displacements associated with a given
	head movement, by providing a comprehensive voxel-based examination
	of the impact of motion on the BOLD signal (i.e., motion-BOLD relationships).
	Positive motion-BOLD relationships were detected in primary and supplementary
	motor areas, particularly in low motion datasets. Negative motion-BOLD
	relationships were most prominent in prefrontal regions, and expanded
	throughout the brain in high motion datasets (e.g., children). Scrubbing
	of volumes with FD>0.2 effectively removed negative but not positive
	correlations; these findings suggest that positive relationships
	may reflect neural origins of motion while negative relationships
	are likely to originate from motion artifact. We also examined the
	ability of motion correction strategies to eliminate artifactual
	differences related to motion among individuals and between groups
	for a broad array of voxel-wise R-fMRI metrics. Residual relationships
	between motion and the examined R-fMRI metrics remained for all correction
	approaches, underscoring the need to covary motion effects at the
	group-level. Notably, global signal regression reduced relationships
	between motion and inter-individual differences in correlation-based
	R-fMRI metrics; Z-standardization (mean-centering and variance normalization)
	of subject-level maps for R-fMRI metrics prior to group-level analyses
	demonstrated similar advantages. Finally, our test-retest (TRT) analyses
	revealed significant motion effects on TRT reliability for R-fMRI
	metrics. Generally, motion compromised reliability of R-fMRI metrics,
	with the exception of those based on frequency characteristics -
	particularly, amplitude of low frequency fluctuations (ALFF). The
	implications of our findings for decision-making regarding the assessment
	and correction of motion are discussed, as are insights into potential
	differences among volume-based metrics of motion.},
  doi = {10.1016/j.neuroimage.2013.03.004},
  institution = {Nathan Kline Institute for Psychiatric Research, Orangeburg, NY,
	USA.},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S1053-8119(13)00212-7},
  pmid = {23499792},
  timestamp = {2013.08.20},
  url = {http://dx.doi.org/10.1016/j.neuroimage.2013.03.004}
}

@ARTICLE{Yan_2013,
  author = {Chao-Gan Yan and R. Cameron Craddock and Xi-Nian Zuo and Yu-Feng
	Zang and Michael P Milham},
  title = {Standardizing the intrinsic brain: Towards robust measurement of
	inter-individual variation in 1000 functional connectomes.},
  journal = {Neuroimage},
  year = {2013},
  volume = {80},
  pages = {246--262},
  month = {Oct},
  abstract = {As researchers increase their efforts to characterize variations in
	the functional connectome across studies and individuals, concerns
	about the many sources of nuisance variation present and their impact
	on resting state fMRI (R-fMRI) measures continue to grow. Although
	substantial within-site variation can exist, efforts to aggregate
	data across multiple sites such as the 1000 Functional Connectomes
	Project (FCP) and International Neuroimaging Data-sharing Initiative
	(INDI) datasets amplify these concerns. The present work draws upon
	standardization approaches commonly used in the microarray gene expression
	literature, and to a lesser extent recent imaging studies, and compares
	them with respect to their impact on relationships between common
	R-fMRI measures and nuisance variables (e.g., imaging site, motion),
	as well as phenotypic variables of interest (age, sex). Standardization
	approaches differed with regard to whether they were applied post-hoc
	vs. during pre-processing, and at the individual vs. group level;
	additionally they varied in whether they addressed additive effects
	vs. additive+multiplicative effects, and were parametric vs. non-parametric.
	While all standardization approaches were effective at reducing undesirable
	relationships with nuisance variables, post-hoc approaches were generally
	more effective than global signal regression (GSR). Across approaches,
	correction for additive effects (global mean) appeared to be more
	important than for multiplicative effects (global SD) for all R-fMRI
	measures, with the exception of amplitude of low frequency fluctuations
	(ALFF). Group-level post-hoc standardizations for mean-centering
	and variance-standardization were found to be advantageous in their
	ability to avoid the introduction of artifactual relationships with
	standardization parameters; though results between individual and
	group-level post-hoc approaches were highly similar overall. While
	post-hoc standardization procedures drastically increased test-retest
	(TRT) reliability for ALFF, modest reductions were observed for other
	measures after post-hoc standardizations-a phenomena likely attributable
	to the separation of voxel-wise from global differences among subjects
	(global mean and SD demonstrated moderate TRT reliability for these
	measures). Finally, the present work calls into question previous
	observations of increased anatomical specificity for GSR over mean
	centering, and draws attention to the near equivalence of global
	and gray matter signal regression.},
  doi = {10.1016/j.neuroimage.2013.04.081},
  institution = {Nathan Kline Institute for Psychiatric Research, Orangeburg, NY,
	USA; Center for the Developing Brain, Child Mind Institute, New York,
	NY, USA; The Phyllis Green and Randolph Cowen Institute for Pediatric
	Neuroscience, New York University Child Study Center, New York, NY,
	USA.},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S1053-8119(13)00428-X},
  pmid = {23631983},
  timestamp = {2013.08.20},
  url = {http://dx.doi.org/10.1016/j.neuroimage.2013.04.081}
}

@ARTICLE{Yang_2012,
  author = {Hongdian Yang and Woodrow L Shew and Rajarshi Roy and Dietmar Plenz},
  title = {Maximal variability of phase synchrony in cortical networks with
	neuronal avalanches.},
  journal = {J. Neurosci.},
  year = {2012},
  volume = {32},
  pages = {1061--1072},
  number = {3},
  month = {Jan},
  abstract = {Ongoing interactions among cortical neurons often manifest as network-level
	synchrony. Understanding the spatiotemporal dynamics of such spontaneous
	synchrony is important because it may (1) influence network response
	to input, (2) shape activity-dependent microcircuit structure, and
	(3) reveal fundamental network properties, such as an imbalance of
	excitation (E) and inhibition (I). Here we delineate the spatiotemporal
	character of spontaneous synchrony in rat cortex slice cultures and
	a computational model over a range of different E-I conditions including
	disfacilitated (antagonized AMPA, NMDA receptors), unperturbed, and
	disinhibited (antagonized GABA(A) receptors). Local field potential
	was recorded with multielectrode arrays during spontaneous burst
	activity. Synchrony among neuronal groups was quantified based on
	phase-locking among recording sites. As network excitability was
	increased from low to high, we discovered three phenomena at an intermediate
	excitability level: (1) onset of synchrony, (2) maximized variability
	of synchrony, and (3) neuronal avalanches. Our computational model
	predicted that these three features occur when the network operates
	near a unique balanced E-I condition called "criticality." These
	results were invariant to changes in the measurement spatial extent,
	spatial resolution, and frequency bands. Our findings indicate that
	moderate average synchrony, which is required to avoid pathology,
	occurs over a limited range of E-I conditions and emerges together
	with maximally variable synchrony. If variable synchrony is detrimental
	to cortical function, this is a cost paid for moderate average synchrony.
	However, if variable synchrony is beneficial, then by operating near
	criticality the cortex may doubly benefit from moderate mean and
	maximized variability of synchrony.},
  doi = {10.1523/JNEUROSCI.2771-11.2012},
  institution = {Section on Critical Brain Dynamics, Laboratory of Systems Neuroscience,
	National Institutes of Mental Health, Bethesda, Maryland 20892, USA.},
  keywords = {Action Potentials, drug effects/physiology; Analysis of Variance;
	Animals; Brain Mapping; Computer Simulation; Cortical Synchronization,
	drug effects/physiology; Entropy; Excitatory Amino Acid Antagonists,
	pharmacology; Female; GABA Antagonists, pharmacology; Male; Mesencephalon,
	cytology/physiology; Models, Neurological; Nerve Net, drug effects/physiology;
	Neurons, drug effects/physiology; Nonlinear Dynamics; Organ Culture
	Techniques; Picrotoxin, pharmacology; Probability; Rats; Rats, Sprague-Dawley;
	Somatosensory Cortex, cytology/physiology; Spectrum Analysis},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {32/3/1061},
  pmid = {22262904},
  timestamp = {2013.03.05},
  url = {http://dx.doi.org/10.1523/JNEUROSCI.2771-11.2012}
}

@ARTICLE{Zalesky_2011,
  author = {Andrew Zalesky},
  title = {Moderating registration misalignment in voxelwise comparisons of
	DTI data: a performance evaluation of skeleton projection.},
  journal = {Magn. Reson. Imaging},
  year = {2011},
  volume = {29},
  pages = {111--125},
  number = {1},
  month = {Jan},
  abstract = {An evaluative methodology and five accompanying performance measures
	were developed to quantitatively assess the performance of the skeleton
	projection algorithm constituting the heart of tract-based spatial
	statistics (TBSS). The performance measures were designed to quantify
	the accuracy of skeleton projection in its indented task of alleviating
	any residual misalignment that may remain after image registration.
	A ground truth fractional anisotropy (FA) image was slightly warped
	using a realistic warp field that served to model post-registration
	residual misalignment of varying magnitudes. Skeleton projection
	was then used to register the warped FA image to the ground truth.
	Performing skeleton projection was found to yield up to 50\% better
	correspondence between the values of FA compared to smoothing, despite
	the fact that less than 10\% of post-registration misalignment was
	corrected. The align-max-with-max strategy underlying TBSS was posited
	as a potential explanation for this high correspondence in the values
	of FA, at the expense of lesser alignment between anatomically concordant
	voxels.},
  doi = {10.1016/j.mri.2010.06.027},
  institution = {Melbourne Neuropsychiatry Centre, Department of Psychiatry, The University
	of Melbourne and Melbourne Health, Victoria 3010, Australia. azalesky@unimelb.edu.au},
  keywords = {Algorithms; Artifacts; Brain, anatomy /&/ histology; Diffusion Tensor
	Imaging, methods; Humans; Image Enhancement, methods; Image Interpretation,
	Computer-Assisted, methods; Imaging, Three-Dimensional, methods;
	Nerve Fibers, Myelinated, ultrastructure; Pattern Recognition, Automated,
	methods; Reproducibility of Results; Sensitivity and Specificity},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S0730-725X(10)00220-1},
  pmid = {20933352},
  timestamp = {2013.03.14},
  url = {http://dx.doi.org/10.1016/j.mri.2010.06.027}
}

@ARTICLE{Zalesky_2008,
  author = {Andrew Zalesky},
  title = {DT-MRI fiber tracking: a shortest paths approach.},
  journal = {IEEE Trans. Med. Imag.},
  year = {2008},
  volume = {27},
  pages = {1458--1471},
  number = {10},
  month = {Oct},
  abstract = {We derive a new fiber tracking algorithm for DT-MRI that parts with
	the locally "greedy" paradigm intrinsic to conventional tracking
	algorithms. We demonstrate the ability to precisely reconstruct a
	diverse range of fiber trajectories in authentic and computer-generated
	DT-MRI data, for which well-known conventional tracking algorithms
	are shown to fail. Our approach is to pose fiber tracking as a problem
	in computing shortest paths in a weighted digraph. Voxels serve as
	vertices, and edges are included between neighboring voxels. We assign
	probabilities (weights) to edges using a Bayesian framework. Higher
	probabilities are assigned to edges that are aligned with fiber trajectories
	in their close proximity. We compute optimal paths of maximum probability
	using computationally scalable shortest path algorithms. The salient
	features of our approach are: global optimality--unlike conventional
	tracking algorithms, local errors do not accumulate and one "wrong-turn"
	does not spell disaster; a target point is specified a priori; precise
	reconstruction is demonstrated for extremely low signal-to-noise
	ratio; impartiality to which of two endpoints is used as a seed;
	and, faster computation times than conventional all-paths tracking.
	We can use our new tracking algorithm in either a single-path tracking
	mode (deterministic tracking) or an all-paths tracking mode (probabilistic
	tracking).},
  doi = {10.1109/TMI.2008.923644},
  institution = {Melbourne Neuropsychiatry Centre (MNC), University of Melbourne,
	Melbourne,Victoria 3220, Australia. azalesky@unimelb.edu.au},
  keywords = {Algorithms; Artificial Intelligence; Brain, anatomy /&/ histology;
	Diffusion Magnetic Resonance Imaging, methods; Humans; Image Enhancement,
	methods; Image Interpretation, Computer-Assisted, methods; Imaging,
	Three-Dimensional, methods; Nerve Fibers, Myelinated, ultrastructure;
	Pattern Recognition, Automated, methods; Reproducibility of Results;
	Sensitivity and Specificity},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {18815098},
  timestamp = {2013.03.14},
  url = {http://dx.doi.org/10.1109/TMI.2008.923644}
}

@ARTICLE{Zalesky_2012a,
  author = {Andrew Zalesky and Luca Cocchi and Alex Fornito and Micah M Murray
	and Ed Bullmore},
  title = {Connectivity differences in brain networks.},
  journal = {Neuroimage},
  year = {2012},
  volume = {60},
  pages = {1055--1062},
  number = {2},
  month = {Apr},
  abstract = {The scenario considered here is one where brain connectivity is represented
	as a network and an experimenter wishes to assess the evidence for
	an experimental effect at each of the typically thousands of connections
	comprising the network. To do this, a univariate model is independently
	fitted to each connection. It would be unwise to declare significance
	based on an uncorrected threshold of α=0.05, since the expected number
	of false positives for a network comprising N=90 nodes and N(N-1)/2=4005
	connections would be 200. Control of Type I errors over all connections
	is therefore necessary. The network-based statistic (NBS) and spatial
	pairwise clustering (SPC) are two distinct methods that have been
	used to control family-wise errors when assessing the evidence for
	an experimental effect with mass univariate testing. The basic principle
	of the NBS and SPC is the same as supra-threshold voxel clustering.
	Unlike voxel clustering, where the definition of a voxel cluster
	is unambiguous, 'clusters' formed among supra-threshold connections
	can be defined in different ways. The NBS defines clusters using
	the graph theoretical concept of connected components. SPC on the
	other hand uses a more stringent pairwise clustering concept. The
	purpose of this article is to compare the pros and cons of the NBS
	and SPC, provide some guidelines on their practical use and demonstrate
	their utility using a case study involving neuroimaging data.},
  doi = {10.1016/j.neuroimage.2012.01.068},
  institution = {Melbourne Neuropsychiatry Centre, The University of Melbourne and
	Melbourne Health, Melbourne, Australia. azalesky@unimelb.edu.au},
  keywords = {Brain Mapping; Brain, anatomy /&/ histology/physiology; Humans; Nerve
	Net, anatomy /&/ histology/physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S1053-8119(12)00085-7},
  pmid = {22273567},
  timestamp = {2013.03.14},
  url = {http://dx.doi.org/10.1016/j.neuroimage.2012.01.068}
}

@ARTICLE{Zalesky_2009,
  author = {Andrew Zalesky and Alex Fornito},
  title = {A DTI-derived measure of cortico-cortical connectivity.},
  journal = {IEEE Trans. Med. Imag.},
  year = {2009},
  volume = {28},
  pages = {1023--1036},
  number = {7},
  month = {Jul},
  abstract = {We arm researchers with a simple method to chart a macroscopic cortico-cortical
	connectivity network in living human subjects. The researcher provides
	a diffusion-magnetic resonance imaging (MRI) data set and N cortical
	regions of interest. In return, we provide an N xN structural adjacency
	matrix (SAM) quantifying the relative connectivity between all cortical
	region pairs. We also return a connectivity map for each pair to
	enable visualization of interconnecting fiber bundles. The measure
	of connectivity we devise is: 1) free of length bias, 2) proportional
	to fiber bundle cross-sectional area, and 3) invariant to an exchange
	of seed and target. We construct a 3-D lattice scaffolding (graph)
	for white-matter by drawing a link between each pair of voxels in
	a 26-voxel neighborhood for which their two respective principal
	eigenvectors form a sufficiently small angle. The connectivity between
	a cortical region pair is then measured as the maximum number of
	link-disjoint paths that can be established between them in the white-matter
	graph. We devise an efficient Edmonds-Karp-like algorithm to compute
	a conservative bound on the maximum number of link-disjoint paths.
	Using both simulated and authentic diffusion-tensor imaging data,
	we demonstrate that the number of link-disjoint paths as a measure
	of connectivity satisfies properties 1)-3), unlike the fraction of
	intersecting streamlines-the measure intrinsic to most existing probabilistic
	tracking algorithms. Finally, we present connectivity maps of some
	notoriously difficult to track longitudinal and contralateral fasciculi.},
  doi = {10.1109/TMI.2008.2012113},
  institution = {Melbourne Neuropsychiatry Centre, University ofMelbourne, 3053 Carlton
	South, Australia. azalesky@unimelb.edu.au},
  keywords = {Algorithms; Brain Mapping, methods; Cerebral Cortex, physiology; Computer
	Simulation; Diffusion Magnetic Resonance Imaging, methods; Female;
	Humans; Middle Aged; Models, Neurological; Nerve Fibers, physiology;
	Nerve Net, physiology; Neural Conduction, physiology; Reproducibility
	of Results; Statistics, Nonparametric},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {19150781},
  timestamp = {2013.03.14},
  url = {http://dx.doi.org/10.1109/TMI.2008.2012113}
}

@ARTICLE{Zalesky_2012,
  author = {Andrew Zalesky and Alex Fornito and Ed Bullmore},
  title = {On the use of correlation as a measure of network connectivity.},
  journal = {Neuroimage},
  year = {2012},
  volume = {60},
  pages = {2096--2106},
  number = {4},
  month = {May},
  abstract = {Numerous studies have demonstrated that brain networks derived from
	neuroimaging data have nontrivial topological features, such as small-world
	organization, modular structure and highly connected hubs. In these
	studies, the extent of connectivity between pairs of brain regions
	has often been measured using some form of statistical correlation.
	This article demonstrates that correlation as a measure of connectivity
	in and of itself gives rise to networks with non-random topological
	features. In particular, networks in which connectivity is measured
	using correlation are inherently more clustered than random networks,
	and as such are more likely to be small-world networks. Partial correlation
	as a measure of connectivity also gives rise to networks with non-random
	topological features. Partial correlation networks are inherently
	less clustered than random networks. Network measures in correlation
	networks should be benchmarked against null networks that respect
	the topological structure induced by correlation measurements. Prevalently
	used random rewiring algorithms do not yield appropriate null networks
	for some network measures. Null networks are proposed to explicitly
	normalize for the inherent topological structure found in correlation
	networks, resulting in more conservative estimates of small-world
	organization. A number of steps may be needed to normalize each network
	measure individually and control for distinct features (e.g. degree
	distribution). The main conclusion of this article is that correlation
	can and should be used to measure connectivity, however appropriate
	null networks should be used to benchmark network measures in correlation
	networks.},
  doi = {10.1016/j.neuroimage.2012.02.001},
  institution = {Melbourne Neuropsychiatry Centre, The University of Melbourne and
	Melbourne Health, Melbourne, Australia. azalesky@unimelb.edu.au},
  keywords = {Brain Mapping; Brain, physiology; Humans; Magnetic Resonance Imaging;
	Neural Pathways, physiology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S1053-8119(12)00178-4},
  pmid = {22343126},
  timestamp = {2013.03.14},
  url = {http://dx.doi.org/10.1016/j.neuroimage.2012.02.001}
}

@ARTICLE{Zalesky_2010,
  author = {Andrew Zalesky and Alex Fornito and Edward T Bullmore},
  title = {Network-based statistic: identifying differences in brain networks.},
  journal = {Neuroimage},
  year = {2010},
  volume = {53},
  pages = {1197--1207},
  number = {4},
  month = {Dec},
  abstract = {Large-scale functional or structural brain connectivity can be modeled
	as a network, or graph. This paper presents a statistical approach
	to identify connections in such a graph that may be associated with
	a diagnostic status in case-control studies, changing psychological
	contexts in task-based studies, or correlations with various cognitive
	and behavioral measures. The new approach, called the network-based
	statistic (NBS), is a method to control the family-wise error rate
	(in the weak sense) when mass-univariate testing is performed at
	every connection comprising the graph. To potentially offer a substantial
	gain in power, the NBS exploits the extent to which the connections
	comprising the contrast or effect of interest are interconnected.
	The NBS is based on the principles underpinning traditional cluster-based
	thresholding of statistical parametric maps. The purpose of this
	paper is to: (i) introduce the NBS for the first time; (ii) evaluate
	its power with the use of receiver operating characteristic (ROC)
	curves; and, (iii) demonstrate its utility with application to a
	real case-control study involving a group of people with schizophrenia
	for which resting-state functional MRI data were acquired. The NBS
	identified a expansive dysconnected subnetwork in the group with
	schizophrenia, primarily comprising fronto-temporal and occipito-temporal
	dysconnections, whereas a mass-univariate analysis controlled with
	the false discovery rate failed to identify a subnetwork.},
  doi = {10.1016/j.neuroimage.2010.06.041},
  institution = {Melbourne Neuropsychiatry Centre, Department of Psychiatry, The University
	of Melbourne and Melbourne Health, Australia. azalesky@unimelb.edu.au},
  keywords = {Adult; Brain Mapping, methods; Brain, physiopathology; Case-Control
	Studies; Female; Humans; Magnetic Resonance Imaging; Male; Nerve
	Net, physiopathology; ROC Curve; Schizophrenia, physiopathology;
	Sensitivity and Specificity},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S1053-8119(10)00885-2},
  pmid = {20600983},
  timestamp = {2013.03.14},
  url = {http://dx.doi.org/10.1016/j.neuroimage.2010.06.041}
}

@ARTICLE{Zalesky_2010a,
  author = {Andrew Zalesky and Alex Fornito and Ian H Harding and Luca Cocchi
	and Murat Yücel and Christos Pantelis and Edward T Bullmore},
  title = {Whole-brain anatomical networks: does the choice of nodes matter?},
  journal = {Neuroimage},
  year = {2010},
  volume = {50},
  pages = {970--983},
  number = {3},
  month = {Apr},
  abstract = {Whole-brain anatomical connectivity in living humans can be modeled
	as a network with diffusion-MRI and tractography. Network nodes are
	associated with distinct grey-matter regions, while white-matter
	fiber bundles serve as interconnecting network links. However, the
	lack of a gold standard for regional parcellation in brain MRI makes
	the definition of nodes arbitrary, meaning that network nodes are
	defined using templates employing either random or anatomical parcellation
	criteria. Consequently, the number of nodes included in networks
	studied by different authors has varied considerably, from less than
	100 up to more than 10(4). Here, we systematically and quantitatively
	assess the behavior, structure and topological attributes of whole-brain
	anatomical networks over a wide range of nodal scales, a variety
	of grey-matter parcellations as well as different diffusion-MRI acquisition
	protocols. We show that simple binary decisions about network organization,
	such as whether small-worldness or scale-freeness is evident, are
	unaffected by spatial scale, and that the estimates of various organizational
	parameters (e.g. small-worldness, clustering, path length, and efficiency)
	are consistent across different parcellation scales at the same resolution
	(i.e. the same number of nodes). However, these parameters vary considerably
	as a function of spatial scale; for example small-worldness exhibited
	a difference of 95\% between the widely-used automated anatomical
	labeling (AAL) template (approximately 100 nodes) and a 4000-node
	random parcellation (sigma(AAL)=1.9 vs. sigma(4000)=53.6+/-2.2).
	These findings indicate that any comparison of network parameters
	across studies must be made with reference to the spatial scale of
	the nodal parcellation.},
  doi = {10.1016/j.neuroimage.2009.12.027},
  institution = {lbourne, Australia. azalesky@unimelb.edu.au},
  keywords = {Adult; Algorithms; Brain, anatomy /&/ histology; Diffusion Magnetic
	Resonance Imaging, methods; Diffusion Tensor Imaging, methods; Female;
	Humans; Image Processing, Computer-Assisted, methods; Least-Squares
	Analysis; Male; Nerve Fibers, Unmyelinated; Neural Pathways, anatomy
	/&/ histology; Young Adult},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pii = {S1053-8119(09)01315-9},
  pmid = {20035887},
  timestamp = {2013.03.14},
  url = {http://dx.doi.org/10.1016/j.neuroimage.2009.12.027}
}

@ARTICLE{Zetterberg_1978,
  author = {Zetterberg, L. H. and Kristiansson, L. and Mossberg, K.},
  title = {Performance of a model for a local neuron population.},
  journal = {Biol Cybern},
  year = {1978},
  volume = {31},
  pages = {15--26},
  number = {1},
  month = {Nov},
  abstract = {A model of a local neuron population is considered that contains three
	subsets of neurons, one main excitatory subset, an auxiliary excitatory
	subset and an inhibitory subset. They are connected in one positive
	and one negative feedback loop, each containing linear dynamic and
	nonlinear static elements. The network also allows for a positive
	linear feedback loop. The behaviour of this network is studied for
	sinusoidal and white noise inputs. First steady state conditions
	are investigated and with this as starting point the linearized network
	is defined and conditions for stability is discovered. With white
	noise as input the stable network produces rhythmic activity whose
	spectral properties are investigated for various input levels. With
	a mean input of a certain level the network becomes unstable and
	the characteristics of these limit cycles are investigated in terms
	of occurence and amplitude. An electronic model has been built to
	study more closely the waveforms under both stable and unstable conditions.
	It is shown to produce signals that resemble EEG background activity
	and certain types of paroxysmal activity, in particular spikes.},
  keywords = {Action Potentials; Electroencephalography; Feedback; Models, Neurological;
	Neural Inhibition; Neurons, physiology; Seizures, physiopathology},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paupau},
  pmid = {728488},
  timestamp = {2013.08.24}
}

@ARTICLE{Zhang_2012,
  author = {Zhang, Lijun and Agravat, Sanjay and Derado, Gordana and Chen, Shuo
	and McIntosh, Belinda J. and Bowman, F DuBois},
  title = {BSMac: a MATLAB toolbox implementing a Bayesian spatial model for
	brain activation and connectivity.},
  journal = {J. Neurosci. Methods},
  year = {2012},
  volume = {204},
  pages = {133--143},
  number = {1},
  month = {Feb},
  abstract = {We present a statistical and graphical visualization MATLAB toolbox
	for the analysis of functional magnetic resonance imaging (fMRI)
	data, called the Bayesian Spatial Model for activation and connectivity
	(BSMac). BSMac simultaneously performs whole-brain activation analyses
	at the voxel and region of interest (ROI) levels as well as task-related
	functional connectivity (FC) analyses using a flexible Bayesian modeling
	framework (Bowman et al., 2008). BSMac allows for inputting data
	in either Analyze or Nifti file formats. The user provides information
	pertaining to subgroup memberships, scanning sessions, and experimental
	tasks (stimuli), from which the design matrix is constructed. BSMac
	then performs parameter estimation based on Markov Chain Monte Carlo
	(MCMC) methods and generates plots for activation and FC, such as
	interactive 2D maps of voxel and region-level task-related changes
	in neural activity and animated 3D graphics of the FC results. The
	toolbox can be downloaded from http://www.sph.emory.edu/bios/CBIS/.
	We illustrate the BSMac toolbox through an application to an fMRI
	study of working memory in patients with schizophrenia.},
  doi = {10.1016/j.jneumeth.2011.10.025},
  institution = {Department of Biostatistics and Bioinformatics, The Rollins School
	of Public Health, Emory University, Atlanta, GA 30322, USA. l.zhang@emory.edu},
  keywords = {Algorithms; Animals; Bayes Theorem; Brain, anatomy /&/ histology/physiology;
	Computer Graphics; Computer Simulation; Humans; Imaging, Three-Dimensional,
	methods; Magnetic Resonance Imaging, methods; Models, Anatomic; Models,
	Neurological; Nerve Net, anatomy /&/ histology/physiology; Neural
	Pathways, anatomy /&/ histology/physiology; Software; Software Design;
	User-Computer Interface},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paupau},
  pii = {S0165-0270(11)00651-0},
  pmid = {22101143},
  timestamp = {2013.02.25},
  url = {http://dx.doi.org/10.1016/j.jneumeth.2011.10.025}
}

@ARTICLE{Zhang_1995,
  author = {Zhang, Z},
  title = {A fast method to compute surface potentials generated by dipoles
	within multilayer anisotropic spheres.},
  journal = {Phys. Med. Biol.},
  year = {1995},
  volume = {40},
  pages = {335-349},
  owner = {paula},
  timestamp = {2012.10.26}
}

@ARTICLE{Zimmermann_2011,
  author = {Jan Zimmermann and Alard Roebroeck and Kamil Uludag and Alexander
	Sack and Elia Formisano and Bernadette Jansma and Peter De Weerd
	and Rainer Goebel},
  title = {Network-based statistics for a community driven transparent publication
	process.},
  journal = {Front. Comput. Neurosci.},
  year = {2011},
  volume = {6},
  pages = {11},
  month = {Dec},
  abstract = {The current publishing system with its merits and pitfalls is a mending
	topic for debate among scientists of various disciplines. Editors
	and reviewers alike, both face difficult decisions about the judgment
	of new scientific findings. Increasing interdisciplinary themes and
	rapidly changing dynamics in method development of each field make
	it difficult to be an "expert" with regard to all issues of a certain
	paper. Although unintended, it is likely that misunderstandings,
	human biases, and even outright mistakes can play an unfortunate
	role in final verdicts. We propose a new community-driven publication
	process that is based on network statistics to make the review, publication,
	and scientific evaluation process more transparent.},
  doi = {10.3389/fncom.2012.00011},
  institution = {therlands.},
  language = {eng},
  medline-pst = {ppublish},
  owner = {paula},
  pmid = {22403537},
  timestamp = {2013.02.14},
  url = {http://dx.doi.org/10.3389/fncom.2012.00011}
}

@BOOK{Niedermeyer_2005,
  title = {Electroencephalography: basic principles, clinical applications,
	and related fields},
  publisher = {Lippincott Williams \& Wilkins},
  year = {2005},
  editor = {Niedermeyer, E. and Lopes Da Silva, F., H.},
  owner = {paula},
  timestamp = {2013.02.18}
}

@BOOK{Nunez_1995book,
  title = {Neocortical dynamics and human EEG rhythms},
  publisher = {Oxford University Press},
  year = {1995},
  editor = {Nunez, P., L},
  owner = {paula},
  timestamp = {2013.02.18}
}

@BOOK{Nunez_1981book,
  title = {Electric Fields of the Brain: The Neurophysics of EEG},
  publisher = {Oxford University Press},
  year = {1981},
  editor = {Nunez, P., L. and Srinivasan, R.},
  owner = {paula},
  timestamp = {2013.02.18}
}

@BOOK{Penny_2006book,
  title = {Statistical Parametric Mapping: The Analysis of Functional Brain
	Images},
  publisher = {Elsevier},
  year = {2006},
  editor = {Penny, W and Friston, K.J. and Ashburner, J and Kiebel, S. and Nichols,
	T.},
  owner = {paula},
  timestamp = {2013.04.11}
}


@article{fieldtrip,
  title={FieldTrip: open source software for advanced analysis of MEG, EEG, and invasive electrophysiological data},
  author={Oostenveld, Robert and Fries, Pascal and Maris, Eric and Schoffelen, Jan-Mathijs},
  journal={Computational intelligence and neuroscience},
  volume={2011},
  pages={1},
  year={2011},
  publisher={Hindawi Publishing Corp.}
}

@article{mnepython,
	title={MNE software for processing MEG and EEG data},
  author={Gramfort, A and Luessi, M and Larson, E and Engemann, D and Strohmeier, D and Brodbeck, C and Parkkonen, L and H{\"a}m{\"a}l{\"a}inen, M},
  journal={Neuroimage},
  year={2013},
}

@article{rubinov2010complex,
  title={Complex network measures of brain connectivity: uses and interpretations},
  author={Rubinov, Mikail and Sporns, Olaf},
  journal={Neuroimage},
  volume={52},
  number={3},
  pages={1059--1069},
  year={2010},
  publisher={Elsevier}
}

@article{herz2008g,
  title={G-Node: an integrated tool-sharing platform to support cellular and systems neurophysiology in the age of global neuroinformatics},
  author={Herz, Andreas VM and Meier, Ralph and Nawrot, Martin P and Schiegel, Willi and Zito, Tiziano},
  journal={Neural Networks},
  volume={21},
  number={8},
  pages={1070--1075},
  year={2008},
  publisher={Elsevier}
}

@article{austin2011carmen,
  title={CARMEN: Code analysis, Repository and Modeling for e-Neuroscience},
  author={Austin, Jim and Jackson, Tom and Fletcher, Martyn and Jessop, Mark and Liang, Bojian and Weeks, Mike and Smith, Leslie and Ingram, Colin and Watson, Paul},
  journal={Procedia Computer Science},
  volume={4},
  pages={768--777},
  year={2011},
  publisher={Elsevier}
}

@inproceedings{dabbish2012social,
  title={Social coding in github: transparency and collaboration in an open software repository},
  author={Dabbish, Laura and Stuart, Colleen and Tsay, Jason and Herbsleb, Jim},
  booktitle={Proceedings of the ACM 2012 conference on Computer Supported Cooperative Work},
  pages={1277--1286},
  year={2012},
  organization={ACM}
}

@article{nethercote2007valgrind,
  title={Valgrind: a framework for heavyweight dynamic binary instrumentation},
  author={Nethercote, Nicholas and Seward, Julian},
  journal={ACM Sigplan Notices},
  volume={42},
  number={6},
  pages={89--100},
  year={2007},
  publisher={ACM}
}

@article{strogatz2001nonlinear,
  title={Nonlinear dynamics and chaos: with applications to physics, biology, chemistry and engineering},
  author={Strogatz, Steven},
  year={2001},
  publisher={Perseus Books Group}
}

@article{guckenheimer1983nonlinear,
  title={Nonlinear oscillations, dynamical systems, and bifurcations of vector fields},
  author={Guckenheimer, John and Holmes, Philip},
  year={1983},
  publisher={Springer-Verlag}
}

@article{de1993stochastical,
  title={Stochastical aspects of neuronal dynamics: Fokker-Planck approach},
  author={De Groff, D and Neelakanta, Perambur S and Sudhakar, R and Aalo, V},
  journal={Biological cybernetics},
  volume={69},
  number={2},
  pages={155--164},
  year={1993},
  publisher={Springer}
}

@article{omurtag2000simulation,
  title={On the simulation of large populations of neurons},
  author={Omurtag, A and Knight, Bruce W. and Sirovich, L},
  journal={Journal of computational neuroscience},
  volume={8},
  number={1},
  pages={51--63},
  year={2000},
  publisher={Springer}
}

@article{knight2000dynamics,
  title={Dynamics of encoding in neuron populations: some general mathematical features},
  author={Knight, Bruce W},
  journal={Neural Computation},
  volume={12},
  number={3},
  pages={473--518},
  year={2000},
  publisher={MIT Press}
}

@article{gerstner2000population,
  title={Population dynamics of spiking neurons: fast transients, asynchronous states, and locking},
  author={Gerstner, Wulfram},
  journal={Neural computation},
  volume={12},
  number={1},
  pages={43--89},
  year={2000},
  publisher={MIT Press}
}

@book{risken1996fokker,
  title={The Fokker-Planck Equation: Methods of Solutions and Applications},
  author={Risken, H},
  publisher={Springer-Verlag},
  year={1996}
}

@article{friston2003dynamic,
  title={Dynamic causal modelling},
  author={Friston, Karl J and Harrison, Lee and Penny, Will},
  journal={Neuroimage},
  volume={19},
  number={4},
  pages={1273--1302},
  year={2003},
  publisher={Elsevier}
}

@article{david2006dynamic,
  title={Dynamic causal modeling of evoked responses in EEG and MEG},
  author={David, Olivier and Kiebel, Stefan J and Harrison, Lee M and Mattout, J{\'e}r{\'e}mie and Kilner, James M and Friston, Karl J},
  journal={NeuroImage},
  volume={30},
  number={4},
  pages={1255--1272},
  year={2006},
  publisher={Elsevier}
}

@article{erlhagen2002dynamic,
	title={Dynamic field theory of movement preparation.},
	author={Erlhagen, Wolfram and Sch{\"o}ner, Gregor},
	journal={Psychological review},
	volume={109},
	number={3},
	pages={545},
	year={2002},
	publisher={American Psychological Association}
}

@article{eliasmith2012large,
	title={A large-scale model of the functioning brain},
	author={Eliasmith, Chris and Stewart, Terrence C and Choo, Xuan and Bekolay, Trevor and DeWolf, Travis and Tang, Charlie and Rasmussen, Daniel},
	journal={science},
	volume={338},
	number={6111},
	pages={1202--1205},
	year={2012},
	publisher={American Association for the Advancement of Science}
}

@article{klockner2012pycuda,
  title={PyCUDA and PyOpenCL: A scripting-based approach to GPU run-time code generation},
  author={Kl{\"o}ckner, Andreas and Pinto, Nicolas and Lee, Yunsup and Catanzaro, Bryan and Ivanov, Paul and Fasih, Ahmed},
  journal={Parallel Computing},
  volume={38},
  number={3},
  pages={157--174},
  year={2012},
  publisher={Elsevier}
}

@article{gorgolewski2011nipype,
  title={Nipype: a flexible, lightweight and extensible neuroimaging data processing framework in python},
  author={Gorgolewski, Krzysztof and Burns, Christopher D and Madison, Cindee and Clark, Dav and Halchenko, Yaroslav O and Waskom, Michael L and Ghosh, Satrajit S},
  journal={Frontiers in neuroinformatics},
  volume={5},
  year={2011},
  publisher={Frontiers Media SA}
}

@article{Jirsa1996,
  title={Field theory of electromagnetic brain activity},
  author={Jirsa, Viktor K and Haken, Hermann},
  journal={Physical Review Letters},
  volume={77},
  number={5},
  pages={960--963},
  year={1996},
  publisher={[Woodbury, NY, etc.] American Physical Society.}
}