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MOOSE (Multi-organ objective segmentation) a data-centric AI solution that generates multilabel organ segmentations to facilitate systemic TB whole-person research.The pipeline is based on nn-UNet and has the capability to segment 120 unique tissue classes from a whole-body 18F-FDG PET/CT image.

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MOOSE 3.0 🦌- Furiously Fast. Brutally Efficient. Unmatched Precision. πŸ’ͺ

Documentation Status PyPI version License: GPL v3 Discord Monthly Downloads Daily Downloads

Welcome to the new and improved MOOSE (v3.0), where speed and efficiency aren't just buzzwordsβ€”they're a way of life.

πŸ’¨ 3x Faster Than Before
Like a moose sprinting through the woods (okay, maybe not that fast), MOOSE 3.0 is built for speed. It's 3x faster than its older sibling, MOOSE 2.0, which was already no slouch. Blink and you'll miss it. ⚑

πŸ’» Memory: Light as a Feather, Strong as a Bull
Forget "Does it fit on my laptop?" The answer is YES. πŸ•Ί Thanks to Dask wizardry, all that data stays in memory. No disk writes, no fuss. Run total-body CT on that 'decent' laptop you bought three years ago and feel like you’ve upgraded. πŸ₯³

πŸ› οΈ Any OS, Anytime, Anywhere
Windows, Mac, Linuxβ€”we don’t play favorites. 🍏 Mac users, you’re in luck: MOOSE runs natively on MPS, getting you GPU-like speeds without the NVIDIA guilt. πŸš€

🎯 Trained to Perfection
This is our best model yet, trained on a whopping 1.7k datasets. More data, better results. Plus you can run multiple models at the same time - You'll be slicing through images like a knife through warm butter. (Or tofu, if you prefer.) 🧈πŸ”ͺ

πŸ–₯️ The 'Herd' Mode πŸ–₯️
Got a powerhouse server just sitting around? Time to let the herd loose! Flip the Herd Mode switch and watch MOOSE multiply across your compute like... well, like a herd of moose! 🦌🦌🦌 The more hardware you have, the faster your inference gets done. Scale up, speed up, and make every bit of your server earn its oats. πŸŒΎπŸ’¨

MOOSE 3.0 isn't just an upgradeβ€”it's a lifestyle. A faster, leaner, and stronger lifestyle. Ready to join the herd? 🦌✨

moose-pr.mp4

Available Segmentation Models 🧬

MOOSE 3.0 offers a wide range of segmentation models catering to various clinical and preclinical needs. Here are the models currently available:

Clinical πŸ‘«πŸ½

Model Name Intensities and Regions
clin_ct_body 1:Legs, 2:Body, 3:Head, 4:Arms
clin_ct_cardiac 1: heart_myocardium, 2: heart_atrium_left, 3: heart_atrium_right, 4: heart_ventricle_left, 5: heart_ventricle_right, 6: aorta, 7: iliac_artery_left, 8: iliac_artery_right, 9: iliac_vena_left, 10: iliac_vena_right, 11: inferior_vena_cava, 12: portal_splenic_vein, 13: pulmonary_artery
clin_ct_digestive 1: colon, 2: duodenum, 3: esophagus, 4: small_bowel
clin_ct_lungs 1:lung_upper_lobe_left, 2:lung_lower_lobe_left, 3:lung_upper_lobe_right, 4:lung_middle_lobe_right, 5:lung_lower_lobe_right
clin_ct_muscles 1: autochthon_left, 2: autochthon_right, 3: gluteus_maximus_left, 4: gluteus_maximus_right, 5: gluteus_medius_left, 6: gluteus_medius_right, 7: gluteus_minimus_left, 8: gluteus_minimus_right, 9: iliopsoas_left, 10: iliopsoas_right
clin_ct_organs 1: adrenal_gland_left, 2: adrenal_gland_right, 3: bladder, 4: brain, 5: gallbladder, 6: kidney_left, 7: kidney_right, 8: liver, 9: lung_lower_lobe_left, 10: lung_lower_lobe_right, 11: lung_middle_lobe_right, 12: lung_upper_lobe_left, 13: lung_upper_lobe_right, 14: pancreas, 15: spleen, 16: stomach, 17: thyroid_left, 18: thyroid_right, 19: trachea
clin_ct_peripheral_bones 1: carpal_left, 2: carpal_right, 3: clavicle_left, 4: clavicle_right, 5: femur_left, 6: femur_right, 7: fibula_left, 8: fibula_right, 9: fingers_left, 10: fingers_right, 11: humerus_left, 12: humerus_right, 13: metacarpal_left, 14: metacarpal_right, 15: metatarsal_left, 16: metatarsal_right, 17: patella_left, 18: patella_right, 19: radius_left, 20: radius_right, 21: scapula_left, 22: scapula_right, 23: skull, 24: tarsal_left, 25: tarsal_right, 26: tibia_left, 27: tibia_right, 28: toes_left, 29: toes_right, 30: ulna_left, 31: ulna_right
clin_ct_ribs 1: rib_left_1, 2: rib_left_2, 3: rib_left_3, 4: rib_left_4, 5: rib_left_5, 6: rib_left_6, 7: rib_left_7, 8: rib_left_8, 9: rib_left_9, 10: rib_left_10, 11: rib_left_11, 12: rib_left_12, 13: rib_left_13, 14: rib_right_1, 15: rib_right_2, 16: rib_right_3, 17: rib_right_4, 18: rib_right_5, 19: rib_right_6, 20: rib_right_7, 21: rib_right_8, 22: rib_right_9, 23: rib_right_10, 24: rib_right_11, 25: rib_right_12, 26: rib_right_13, 27: sternum
clin_ct_vertebrae 1: vertebra_C1, 2: vertebra_C2, 3: vertebra_C3, 4: vertebra_C4, 5: vertebra_C5, 6: vertebra_C6, 7: vertebra_C7, 8: vertebra_T1, 9: vertebra_T2, 10: vertebra_T3, 11: vertebra_T4, 12: vertebra_T5, 13: vertebra_T6, 14: vertebra_T7, 15: vertebra_T8, 16: vertebra_T9, 17: vertebra_T10, 18: vertebra_T11, 19: vertebra_T12, 20: vertebra_L1, 21: vertebra_L2, 22: vertebra_L3, 23: vertebra_L4, 24: vertebra_L5, 25: vertebra_L6, 26: hip_left, 27: hip_right, 28: sacrum
clin_ct_body_composition 1: skeletal_muscle, 2: subcutaneous_fat, 3: visceral_fat

Preclinical 🐁

Model Name Intensities and Regions
preclin_ct_legs 1:right_leg_muscle, 2:left_leg_muscle
preclin_mr_all 1:Brain, 2:Liver, 3:Intestines, 4:Pancreas, 5:Thyroid, 6:Spleen, 7:Bladder, 8:OuterKidney, 9:InnerKidney, 10:HeartInside, 11:HeartOutside, 12:WAT Subcutaneous, 13:WAT Visceral, 14:BAT, 15:Muscle TF, 16:Muscle TB, 17:Muscle BB, 18:Muscle BF, 19:Aorta, 20:Lung, 21:Stomach

Each model is designed to provide high-quality segmentation with MOOSE 3.0's optimized algorithms and data-centric AI principles.

Star History 🀩

Star History Chart

Citations ❀️

  • Shiyam Sundar, L. K., Yu, J., Muzik, O., Kulterer, O., Fueger, B. J., Kifjak, D., Nakuz, T., Shin, H. M., Sima, A. K., Kitzmantl, D., Badawi, R. D., Nardo, L., Cherry, S. R., Spencer, B. A., Hacker, M., & Beyer, T. (2022). Fully-automated, semantic segmentation of whole-body 18F-FDG PET/CT images based on data-centric artificial intelligence. Journal of Nuclear Medicine. https://doi.org/10.2967/jnumed.122.264063
  • Isensee, F., Jaeger, P.F., Kohl, S.A.A. et al. nnU-Net: a self-configuring method for deep learning-based biomedical image segmentation. Nat Methods 18, 203–211 (2021). https://doi.org/10.1038/s41592-020-01008-z

Requirements βœ…

Before you dive into the incredible world of MOOSE 3.0, here are a few things you need to ensure for an optimal experience:

  • Operating System: We've got you covered whether you're on Windows, Mac, or Linux. MOOSE 3.0 has been tested across these platforms to ensure seamless operation.

  • Memory: MOOSE 3.0 has quite an appetite! Make sure you have at least 16GB of RAM for the smooth running of all tasks.

  • GPU: If speed is your game, an NVIDIA GPU is the name! MOOSE 3.0 leverages GPU acceleration to deliver results fast. Don't worry if you don't have one, though - it will still work, just at a slower pace.

  • Python: Ensure that you have Python 3.10 installed on your system. MOOSE 3.0 likes to keep up with the latest, after all!

So, that's it! Make sure you're geared up with these specifications, and you're all set to explore everything MOOSE 3.0 has to offer. πŸš€πŸŒ

Installation Guide πŸ› οΈ

Available on Windows, Linux, and MacOS, the installation is as simple as it gets. Follow our step-by-step guide below and set sail on your journey with MOOSE 3.0.

For Linux (and Intel x86 Mac)🐧

  1. First, create a Python environment. You can name it to your liking; for example, 'moose-env'.

    python3.10 -m venv moose-env
  2. Activate your newly created environment.

    source moose-env/bin/activate  # for Linux
  3. Install MOOSE 3.0.

    pip install moosez

Voila! You're all set to explore with MOOSE 3.0.

For Macs powered by Apple Silicon (M series chips with MPS) 🍏

  1. First, create a Python environment. You can name it to your liking; for example, 'moose-env'.

    python3.10 -m venv moose-env
  2. Activate your newly created environment.

    source moose-env/bin/activate 
  3. Install MOOSE 3.0 and a special fork of PyTorch (MPS specific). You need to install the MPS specific branch for making MOOSE work with MPS

    pip install moosez
    pip install git+https://github.com/LalithShiyam/pytorch-mps.git

Now you are ready to use MOOSE on Apple Silicon 🏎⚑️.

For Windows πŸͺŸ

  1. Create a Python environment. You could name it 'moose-env', or as you wish.

    python3.10 -m venv moose-env
  2. Activate your newly created environment.

    .\moose-env\Scripts\activate
  3. Go to the PyTorch website and install the appropriate PyTorch version for your system. !DO NOT SKIP THIS!

  4. Finally, install MOOSE 3.0.

    pip install moosez

There you have it! You're ready to venture into the world of 3D medical image segmentation with MOOSE 3.0.

Happy exploring! πŸš€πŸ”¬

Usage Guide πŸ“š

Command-Line Tool for Batch Processing πŸ–₯οΈπŸš€

Getting started with MOOSE 3.0 is as easy as slicing through butter 🧈πŸ”ͺ. Use the command-line tool to process multiple segmentation models in sequence or in parallel, making your workflow a breeze. 🌬️

Running Single/Multiple Models in Sequence πŸƒβ€β™‚οΈπŸŽ―

You can now run single or several models in sequence with a single command. Just provide the path to your subject images and list the segmentation models you wish to apply:

# For single model inference
moosez -d <path_to_image_dir> -m <model_name>

# For multiple model inference
moosez -d <path_to_image_dir> \
       -m <model_name1> \
          <model_name2> \
          <model_name3> \

For instance, to run clinical CT organ segmentation on a directory of images, you can use the following command:

moosez -d <path_to_image_dir> -m clin_ct_organs

Likewise, to run multiple models e.g. organs, ribs, and vertebrae, you can use the following command:

moosez -d <path_to_image_dir> \
       -m clin_ct_organs \
          clin_ct_ribs \
          clin_ct_vertebrae

MOOSE 3.0 will handle each model one after the otherβ€”no fuss, no hassle. πŸ™Œβœ¨

Herd Mode: Running Parallel Instances πŸ¦ŒπŸ’¨πŸ’»

Got a powerful server or HPC? Let the herd roam! πŸ¦ŒπŸš€ Use Herd Mode to run multiple MOOSE instances in parallel. Just add the -herd flag with the number of instances you wish to run simultaneously:

moosez -d <path_to_image_dir> \
       -m clin_ct_organs \
          clin_ct_ribs \
          clin_ct_vertebrae \
       -herd 2

MOOSE will run two instances at the same time, utilizing your compute power like a true multitasking pro. πŸ’ͺπŸ‘¨β€πŸ’»πŸ‘©β€πŸ’»

And that's it! MOOSE 3.0 lets you process with ease and speed. ⚑✨

Need assistance along the way? Don't worry, we've got you covered. Simply type:

moosez -h

This command will provide you with all the help and the information about the available models and the regions it segments.

Using MOOSE 3.0 as a Library πŸ“¦πŸ

MOOSE 3.0 isn't just a command-line powerhouse; it’s also a flexible library for Python projects. Here’s how to make the most of it:

First, import the moose function from the moosez package in your Python script:

from moosez import moose

Calling the moose Function 🦌

The moose function is versatile and accepts various input types. It takes four main arguments:

  1. input: The data to process, which can be:
    • A path to an input file or directory (NIfTI, either .nii or .nii.gz).
    • A tuple containing a NumPy array and its spacing (e.g., numpy_array, (spacing_x, spacing_y, spacing_z)).
    • A SimpleITK image object.
  2. model_names: A single model name or a list of model names for segmentation.
  3. output_dir: The directory where the results will be saved.
  4. accelerator: The type of accelerator to use ("cpu", "cuda", or "mps" for Mac).

Examples πŸ“‚βœ‚οΈπŸ’»

Here are some examples to illustrate different ways to use the moose function:

  1. Using a file path and multiple models:

    moose('/path/to/input/file', ['clin_ct_organs', 'clin_ct_ribs'], '/path/to/save/output', 'cuda')
  2. Using a NumPy array with spacing:

    moose((numpy_array, (1.5, 1.5, 1.5)), 'clin_ct_organs', '/path/to/save/output', 'cuda')
  3. Using a SimpleITK image:

    moose(simple_itk_image, 'clin_ct_organs', '/path/to/save/output', 'cuda')

Usage of moose() in your code

To use the moose() function, ensure that you wrap the function call within a main guard to prevent recursive process creation errors:

from moosez import moose

if __name__ == '__main__':
    input_file = '/path/to/input/file'
    models = ['clin_ct_organs', 'clin_ct_ribs']
    output_directory = '/path/to/save/output'
    accelerator = 'cuda'
    moose(input_file, models, output_directory, accelerator)

Ready, Set, Segment! πŸš€

That's it! With these flexible inputs, you can use MOOSE 3.0 to fit your workflow perfectlyβ€”whether you’re processing a single image, a stack of files, or leveraging different data formats. πŸ–₯οΈπŸŽ‰

Happy segmenting with MOOSE 3.0! πŸ¦ŒπŸ’«

Directory Structure and Naming Conventions for MOOSE πŸ“‚πŸ·οΈ

Applicable only for batch mode ⚠️

Using MOOSE 3.0 optimally requires your data to be structured according to specific conventions. MOOSE 3.0 supports both DICOM and NIFTI formats. For DICOM files, MOOSE infers the modality from the DICOM tags and checks if the given modality is suitable for the chosen segmentation model. However, for NIFTI files, users need to ensure that the files are named with the correct modality as a suffix.

Required Directory Structure 🌳

Please structure your dataset as follows:

MOOSEv2_data/ πŸ“
β”œβ”€β”€ S1 πŸ“‚
β”‚   β”œβ”€β”€ AC-CT πŸ“‚
β”‚   β”‚   β”œβ”€β”€ WBACCTiDose2_2001_CT001.dcm πŸ“„
β”‚   β”‚   β”œβ”€β”€ WBACCTiDose2_2001_CT002.dcm πŸ“„
β”‚   β”‚   β”œβ”€β”€ ... πŸ—‚οΈ
β”‚   β”‚   └── WBACCTiDose2_2001_CT532.dcm πŸ“„
β”‚   └── AC-PT πŸ“‚
β”‚       β”œβ”€β”€ DetailWB_CTACWBPT001_PT001.dcm πŸ“„
β”‚       β”œβ”€β”€ DetailWB_CTACWBPT001_PT002.dcm πŸ“„
β”‚       β”œβ”€β”€ ... πŸ—‚οΈ
β”‚       └── DetailWB_CTACWBPT001_PT532.dcm πŸ“„
β”œβ”€β”€ S2 πŸ“‚
β”‚   └── CT_S2.nii πŸ“„
β”œβ”€β”€ S3 πŸ“‚
β”‚   └── CT_S3.nii πŸ“„
β”œβ”€β”€ S4 πŸ“‚
β”‚   └── S4_ULD_FDG_60m_Dynamic_Patlak_HeadNeckThoAbd_20211025075852_2.nii πŸ“„
└── S5 πŸ“‚
    └── CT_S5.nii πŸ“„

Note: If the necessary naming conventions are not followed, MOOSE 3.0 will skip the subjects.

Naming Conventions for NIFTI files πŸ“

When using NIFTI files, you should name the file with the appropriate modality as a suffix.

For instance, if you have chosen the model_name as clin_ct_organs, the CT scan for subject 'S2' in NIFTI format, should have the modality tag 'CT_' attached to the file name, e.g. CT_S2.nii. In the directory shown above, every subject will be processed by moosez except S4.

Remember: Adhering to these file naming and directory structure conventions ensures smooth and efficient processing with MOOSE 3.0. Happy segmenting! πŸš€

A Note on QIMP Python Packages: The 'Z' Factor πŸ“šπŸš€

All of our Python packages here at QIMP carry a special signature – a distinctive 'Z' at the end of their names. The 'Z' is more than just a letter to us; it's a symbol of our forward-thinking approach and commitment to continuous innovation.

Our MOOSE package, for example, is named as 'moosez', pronounced "moose-see". So, why 'Z'?

Well, in the world of mathematics and science, 'Z' often represents the unknown, the variable that's yet to be discovered, or the final destination in a series. We at QIMP believe in always pushing boundaries, venturing into uncharted territories, and staying on the cutting edge of technology. The 'Z' embodies this philosophy. It represents our constant quest to uncover what lies beyond the known, to explore the undiscovered, and to bring you the future of medical imaging.

Each time you see a 'Z' in one of our package names, be reminded of the spirit of exploration and discovery that drives our work. With QIMP, you're not just installing a package; you're joining us on a journey to the frontiers of medical image processing. Here's to exploring the 'Z' dimension together! πŸš€

🦌 MOOSE: A part of the enhance.pet community

Alt Text

πŸ‘₯ Contributors

</tr>
Lalith Kumar Shiyam Sundar
Lalith Kumar Shiyam Sundar

πŸ’» πŸ“–
Sebastian Gutschmayer
Sebastian Gutschmayer

πŸ’»
n7k-dobri
n7k-dobri

πŸ’»
Manuel Pires
Manuel Pires

πŸ’»
Zach Chalampalakis
Zach Chalampalakis

πŸ’»
David Haberl
David Haberl

πŸ’»
W7ebere
W7ebere

πŸ“–
Kazezaka
Kazezaka

πŸ’»
Loic Tetrel
Loic Tetrel @ Kitware

πŸ’» πŸ“–

About

MOOSE (Multi-organ objective segmentation) a data-centric AI solution that generates multilabel organ segmentations to facilitate systemic TB whole-person research.The pipeline is based on nn-UNet and has the capability to segment 120 unique tissue classes from a whole-body 18F-FDG PET/CT image.

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