Cerebellum CNN
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Cerebellum Parcellation with Convolutional Neural Networks
This work originally appeared at Proceedings of SPIE Medical Imaging (SPIE-MI 2019), San Diego, CA, February 16 - 21, 2019. It can be downloaded as a Singularity image. The download is 1.3GB. If you use this work please cite:
- S. Han, Y. He, A. Carass, S.H. Ying, and J.L. Prince, "Cerebellum parcellation with convolutional neural networks", Proceedings of SPIE Medical Imaging (SPIE-MI 2019), San Diego, CA, February 16 - 21, 2019. (doi).
If you have any questions, please email Shuo Han via shan50@jhu.edu
.
What the Singularity image can do
The Singularity performs the following steps:
- ROBEX is used to estimate a brain mask. This mask is then smoothed to generate a brain weight image. The mask is not used for skull-stripping. It is only used for the bias field correction below.
- N4 from ANTs is used to perform the bias field correction. The bias field is estimated using the weight image calculated above.
- The image is rigidly registered to the ICBM2009c nonlinear symmetric template using the ANTs package.
- The cerebellum of an MNI-registered MPRAGE image is parcellated using the method described in "Shuo Han, et al., Cerebellum parcellation with convolutional neural networks, SPIE 2019 Medical Imaging Image Processing".
- Removing the neck should improve the results, such as using "robustfov" from fsl, but it is not done in this Singularity image.
- The parcellation is transformed back to the original space using ANTs with the "MultiLabel" interpolation.
- Generate .png files of slices in the axial, coronal, and sagittal views for quality control.
Installation
- Install Singularity 2.6
Example Usage
- The Singularity image can only run on CPU although TensorFlow and Keras are used, because the Singularity image only contains the CPU version of TensorFlow.
- Assume that the Singularity image is ~/cerebellum-parcellation.simg, the image to parcellate is image.nii.gz, and the output folder is ~/output
singularity run ~/cerebellum-parcellation.simg -i ~/image.nii.gz -o ~/output
- If the image.nii.gz is under /path/to/image which is not under your home directory
singularity run -B /path/to/image:/mnt ~/cerebellum-parcellation.simg -i /mnt/image.nii.gz -o /mnt/output
- Print help
singularity run ~/cerebellum-parcellation.simg -h
File structure
The processing will create subfolders "n4"', "mni", "parc", and "pics" under the output folder. The final parcellation result is directly under the output folder.
- "*n4.nii.gz" is the bias field corrected image
- "*n4_mni.nii.gz" is the image in the MNI space
- "*n4_mni_seg.nii.gz" is the parcellation from the deep networks
- "*n4_mni_seg_post.nii.gz" is the post-processed result.
- "*n4_mni_seg_post_inverse.nii.gz" is the final post-processed result in the original space.
- The subfolder "pics/final" contains the axial, coronal, and sagittal slices of the file "*n4_mni_seg_post_inverse.nii.gz".
Cerebellum labels
"12": "Corpus_Medullare", "33": "Left_Lobules_I-III", "36": "Right_Lobules_I-III", "43": "Left_Lobule_IV", "46": "Right_Lobule_IV", "53": "Left_Lobule_V", "56": "Right_Lobule_V", "63": "Left_Lobule_VI", "60": "Vermis_VI", "66": "Right_Lobule_VI", "73": "Left_Lobule_VIIAf", "76": "Right_Lobule_VIIAf", "74": "Left_Lobule_VIIAt", "70": "Vermis_VII", "77": "Right_Lobule_VIIAt", "75": "Left_Lobule_VIIB", "78": "Right_Lobule_VIIB", "83": "Left_Lobule_VIIIA", "80": "Vermis_VIII", "86": "Right_Lobule_VIIIA", "84": "Left_Lobule_VIIIB", "87": "Right_Lobule_VIIIB", "93": "Left_Lobule_IX", "90": "Vermis_IX", "96": "Right_Lobule_IX", "103": "Left_Lobule_X", "100": "Vermis_X", "106": "Right_Lobule_X"