MRI Segmentation with CAT12

Authors: Francois Tadel

CAT is a SPM12 toolbox that is fully interfaced with Brainstorm. It can replace efficiently FreeSurfer for generating the cortical surface from any T1 MRI. It runs on any OS in about 1 hour, instead of the typical 24hr FreeSurfer recon-all processing. The surfaces are registered to the templates with the FreeSurfer spheres, and include many surface and volume parcellations. You can either install and run the CAT segmentation from Brainstorm, or run it separately and import its outputs as you would do with FreeSurfer.

Cite CAT12

If you use CAT for MRI segmentation, please cite the following article in your publications:

Gaser C, Dahnke R, Kurth F, Luders E
CAT - A Computational Anatomy Toolbox for the Analysis of Structural MRI Data
NeuroImage, in review

Install CAT12

CAT12 requires the prior installation of SPM12. Both are Matlab-based programs that be installed automatically as Brainstorm plugins:

• Plugins > spm12 > Install

• Plugins > Anatomy > spm12 > Install
  
  

If you want to use your own installation of SPM12/CAT12 instead, refer to the plugins tutorial.

• SPM12 download: https://www.fil.ion.ucl.ac.uk/spm/software/download/

• CAT12 download: http://www.neuro.uni-jena.de/cat/index.html#DOWNLOAD

Troubleshooting

On Windows computers, you might run into an error: Error creating link. This is related with the creation of the symbolic link from plugins/spm12/spm12/toolbox/cat12 to plugins/cat12/cat12. This forum post mentions two workarounds:

• Start Matlab as an administrator:

  • Right-click on the Matlab icon > Run as administrator

  • Start Brainstorm, try loading again the plugin (menu Plugins > cat12 > Load). This should restore the broken or missing symbolic link automatically.

• Install SPM12/CAT12 manually (not managed as Brainstorm plugins):
  • Uninstall the CAT12 and SPM12 plugin from Brainstorm,
  • Download and install them manually on your computer (not in any of the Brainstorm folders), with CAT12 really located in the SPM12 toolbox folder,

  • Configure Brainstorm to use these custom installations for the two plugins, with the menu "Custom install": https://neuroimage.usc.edu/brainstorm/Tutorials/Plugins#Example:_FieldTrip

Run CAT from Brainstorm

• Switch to the anatomy side of the database explorer.
• Create a new subject, set the default anatomy option to "No, use individual anatomy".
• Import the T1 MRI for this subject.

• Set the fiducial points manually (NAS/LPA/RPA) or compute the MNI normalization.

• Right-click on the MRI > MRI segmentation > CAT12. Two options can be selected interactively: the number of final vertices in the cortex surfaces, and the computation additional volume parcellations.
  
  

• Alternatively, use the process: Import anatomy > Segment MRI with CAT12.
  
  

• With the process version, you have access to more options:

  • TPM atlas: Location of the template tissue probabilistic maps. If empty, it uses by default the standard TPM.nii available in SPM12 (usually downloaded automatically in the folder $HOME/.brainstorm/defaults/spm/TPM.nii). It can be interesting to replace it with a probabilistic atlas better adapted to specific population, eg. the children atlas from CAT12 (spm12/toolbox/cat12/templates_volumes/TPM_Age11.5.nii)

  • Use spherical registration: Call CAT12 with the highest possible accuracy, which includes the spherical registration to the FSAverage template. Enabling this option takes much longer, but is necessary for importing all the FreeSurfer atlases, projecting the sources maps to a common template in the case of group analysis, and computing accurate cortical thickness maps.

  • Compute volume parcellations: Compute and import all the volume parcellations that are available in CAT12: AAL3, CoBrALab, Hammers, IBSR, JulichBrain v2, LPBA40, Mori, Schaefer2018

  • Import cortical thickness maps: Enable this option to import the cortical thickness computed by CAT12 as source files. See section Cortical thickness.

• Brainstorm saves the MRI to process in a temporary folder, then calls CAT as a SPM batch:
  $HOME/.brainstorm/tmp/cat12/spm_cat12.nii

• All the output from CAT is saved in the same temporary folder. At the end, Brainstorm imports the output folder as the anatomy for the selected subject. If the process crashes, you can inspect the contents of this folder for indices on how to solve the problem. If the segmentation and the import is successful, the temporary folder is deleted.

• A report is displayed by CAT, and saved as an image and a PDF file in tmp/cat12/report.
  
  

Troubleshooting

• Error about a missing function spm_ov_mesh.m: you need to update SPM12, from the Brainstorm plugins menu, or run "spm_update" from the Matlab command line. See forum post.

• Error when installing CAT12: Error creating link: Access is denied. See the troubleshoothing part in the section Install CAT12 above.

• Search the Brainstorm forum or create a new topic.

• Search the SPM mailing list archive or send an email to this list.

Importing the results in Brainstorm

If you run the segmentation process from Brainstorm, the import will be done automatically. Otherwise, if you need to import an existing CAT segmentation, here is the following procedure.

• Right-click on the subject > Import anatomy folder.
  
  

  • Import anatomy folder: Interactive import: asks for the number of vertices expected in the final cortex surfaces, for the volume atlases, and for the location of the fiducials NAS/LPA/RPA. Select this option in the case of an MEG study, when you know exactly where the fiducials were digitized during the MEG acquisition. See tutorial MRI registration.

  • Import anatomy folder (auto): Automatic import: Computes the linear MNI normalization, uses default positions from the MNI atlas for the NAS/LPA/RPA fiducials, uses 15000 vertices for the cortex downsampled surfaces, and imports all the volume atlases.

• Select one the CAT12 import options and select the top folder of the CAT12 segmentation:

  • CAT12: Import the T1 MRI, cortex surfaces (central, pial and white), surface parcellations, surface spherical registration, surface and volume parcellations. Reconstruct the head surface.

  • CAT12 + Thickness: Same as above, with the cortical thickness maps imported as source maps.

• A figure is automatically shown at the end of the process, to check visually that the low-resolution cortex and head surfaces were properly generated and imported. If it doesn't look like the following picture, do not go any further in your source analysis, fix the anatomy first.
  
  

• Difference with FreeSurfer: The default surface selected when importing results from CAT12 is the low-resolution central surface, while when importing FreeSurfer results the default surface is the pial surface (named "cortex").

Files imported

The files that are imported from the segmentation output folder are the following:

• /*.nii (T1 MRI volume - only one .nii file allowed in the top-level folder)

• /surf/?h.central.*.gii (left/right hemisphere of the central surface)

• /surf/?h.pial.*.gii (left/right hemisphere of the pial surface, i.e. the external cortex layer)

• /surf/?h.white.*.gii (left/right hemisphere of the white surface, i.e. the inner cortex layer)

• /surf/?h.sphere.reg.*.gii (left/right FreeSurfer registered spheres)

• /surf/?h.*.annot (cortical surface-based atlases)

• /surf/?h.thickness.* (texture with the cortical thickness at each vertex)

• /mri/p*.nii (tissue probability maps, used to create the tissue segmentation volume)

• /mri_atlas/*.nii (volume parcellations)

The files you can see in the database explorer at the end:

• MRI: The T1 MRI of the subject, imported from the .nii file at the top-level folder.

• Volume parcellations: /mri_atlas/*.nii, see tutorial Explore the anatomy.

• Tissue_cat12: Segmentation of the MRI volumes in 5 tissues: gray, white, CSF, skull, scalp.

• head mask (10000,0,2): Scalp surface generated by Brainstorm. The numbers indicate the parameters that were automatically used for this head: vertices=10000, erode factor=0, fill holes=2.

• central_250000V: High-resolution cortex surface generated by CAT. The central surfaces are meshes half-way between the grey-white interface and the external pial surface (Dahnke et al. 2012).

• central_15000V: Low-resolution cortex surface, downsampled using the reducepatch function from Matlab (it keeps a meaningful subset of vertices from the original surface). It appears in green in the database explorer, ie. it is going to be used as the default by the processes that require a cortex surface.

• pial_250000V: High-resolution pial surface, i.e. the most external cortical layer.

• pial_15000V: Low-resolution pial surface, i.e. the most external cortical layer. Change the selection to this surface for a direct comparison with the FreeSurfer results.

• white_250000V: High-resolution white matter surface, i.e. the interface between the grey and the white matter (or innermost cortical layer).

• white_15000V: Low-resolution white matter surface.

Cortical parcellations

Using CAT12 from Brainstorm, the following cortical parcellations are available:

• Destrieux atlas (surf/?h.aparc_a2009s.*.annot): more info

• Desikan-Killiany atlas (surf/?h.aparc_DK40.*.annot): more info

• HCP MMP1 atlas (surf/?h.aparc_HCP_MMP1.*.annot): more info

• Schaefer 2018 atlases (surf/?h.Schaefer2018_*.annot): more info

These atlases are imported in Brainstorm as scouts (cortical regions of interest), and saved directly in the surface files. To access them from the interface: Display any cortex surface, go to the Scout tab and click on the drop-down list to select another Atlas (ie group of scouts):

Cortical thickness

The cortical thickness can be saved as a cortical map in the database (a "results" file). This result is generated when using the file format "CAT12 folder + Thickness maps" in the Import anatomy folder selection.

Registered spheres

The registered spheres are saved in each surface file in the field Reg.Sphere.Vertices. There is nothing that can be done with this information at this point, but it will become helpful when projecting the source results from the individual brains to the default anatomy of the protocol, for a group analysis of the results: Subject coregistration.

Read more about the FreeSurfer registration process on the software wiki:
https://surfer.nmr.mgh.harvard.edu/fswiki/SurfaceRegAndTemplates

Volume parcellations

Many volume parcellations are available when this option is selected when running CAT:

• AAL3: More information

• Anatomy3: More information

• Cobra: More information

• Hammers: More information

• IBSR: More information

• JulichBrain v2.0: More information

• LPBA40: More information

• Mori: More information

• Neuromorphometrics: More information

• Schaefer2018: More information

• Thalamus: More information

Tissue classification

The tissue probability maps saved in /mri/p*.nii are grouped to create one volume with the labels of 5 tissues: gray matter, white matter, CSF, skull, scalp.

SPM batch

The CAT segmentation is executed with the following SPM12 batch:

matlabbatch{1}.spm.tools.cat.estwrite.data = {[NiiFile ',1']};
matlabbatch{1}.spm.tools.cat.estwrite.data_wmh = {''};
matlabbatch{1}.spm.tools.cat.estwrite.useprior = '';
matlabbatch{1}.spm.tools.cat.estwrite.nproc = 0;                % Blocking call to CAT12
matlabbatch{1}.spm.tools.cat.estwrite.opts.tpm = {TpmNii};      % User-defined TPM atlas
matlabbatch{1}.spm.tools.cat.estwrite.output.bias.warped = 0;
matlabbatch{1}.spm.tools.cat.estwrite.output.GM.native   = 1;   % GM tissue maps
matlabbatch{1}.spm.tools.cat.estwrite.output.GM.warped   = 0;
matlabbatch{1}.spm.tools.cat.estwrite.output.GM.mod      = 0;
matlabbatch{1}.spm.tools.cat.estwrite.output.GM.dartel   = 0;
matlabbatch{1}.spm.tools.cat.estwrite.output.WM.native   = 1; % WM tissue maps
matlabbatch{1}.spm.tools.cat.estwrite.output.WM.warped   = 0;
matlabbatch{1}.spm.tools.cat.estwrite.output.WM.mod      = 0;
matlabbatch{1}.spm.tools.cat.estwrite.output.WM.dartel   = 0;
matlabbatch{1}.spm.tools.cat.estwrite.output.TPMC.native = 1; % Tissue classes 4-6
matlabbatch{1}.spm.tools.cat.estwrite.output.TPMC.warped = 0;
matlabbatch{1}.spm.tools.cat.estwrite.output.TPMC.mod    = 0;
matlabbatch{1}.spm.tools.cat.estwrite.output.TPMC.dartel = 0;
matlabbatch{1}.spm.tools.cat.estwrite.output.CSF.native  = 1; % CSF tissue maps
matlabbatch{1}.spm.tools.cat.estwrite.output.CSF.warped  = 0;
matlabbatch{1}.spm.tools.cat.estwrite.output.CSF.mod     = 0;
matlabbatch{1}.spm.tools.cat.estwrite.output.CSF.dartel  = 0;
matlabbatch{1}.spm.tools.cat.estwrite.output.label.native = 1; % CSF=1,GM=2,WM=3,WMH=4
matlabbatch{1}.spm.tools.cat.estwrite.output.label.warped = 0;
matlabbatch{1}.spm.tools.cat.estwrite.output.label.dartel = 0;

% Volume atlases
if isVolumeAtlases
  matlabbatch{1}.spm.tools.cat.estwrite.output.ROImenu.atlases.neuromorphometrics = 1;
  matlabbatch{1}.spm.tools.cat.estwrite.output.ROImenu.atlases.lpba40             = 1;
  matlabbatch{1}.spm.tools.cat.estwrite.output.ROImenu.atlases.cobra              = 1;
  matlabbatch{1}.spm.tools.cat.estwrite.output.ROImenu.atlases.aal3               = 1;
  matlabbatch{1}.spm.tools.cat.estwrite.output.ROImenu.atlases.anatomy3           = 1;
  matlabbatch{1}.spm.tools.cat.estwrite.output.ROImenu.atlases.ibsr               = 1;
  matlabbatch{1}.spm.tools.cat.estwrite.output.ROImenu.atlases.julichbrain        = 1;
  matlabbatch{1}.spm.tools.cat.estwrite.output.ROImenu.atlases.hammers            = 1;
  matlabbatch{1}.spm.tools.cat.estwrite.output.ROImenu.atlases.mori               = 1;
  matlabbatch{1}.spm.tools.cat.estwrite.output.ROImenu.atlases.Schaefer2018_100Parcels_17Networks_order = 1;
  matlabbatch{1}.spm.tools.cat.estwrite.output.ROImenu.atlases.Schaefer2018_200Parcels_17Networks_order = 1;
  matlabbatch{1}.spm.tools.cat.estwrite.output.ROImenu.atlases.Schaefer2018_400Parcels_17Networks_order = 1;
  matlabbatch{1}.spm.tools.cat.estwrite.output.ROImenu.atlases.Schaefer2018_800Parcels_17Networks_order = 1;
  matlabbatch{1}.spm.tools.cat.estwrite.output.atlas.native = 1;  % Save in native space
else
  matlabbatch{1}.spm.tools.cat.estwrite.output.ROImenu.noROI = struct([]);
  matlabbatch{1}.spm.tools.cat.estwrite.output.ROImenu.atlases.neuromorphometrics = 0;
  matlabbatch{1}.spm.tools.cat.estwrite.output.ROImenu.atlases.lpba40             = 0;
  matlabbatch{1}.spm.tools.cat.estwrite.output.ROImenu.atlases.cobra              = 0;
  matlabbatch{1}.spm.tools.cat.estwrite.output.ROImenu.atlases.hammers            = 0;
end

% Extract additional surface parameters: Cortical thickness, Gyrification index, Sulcal depth
if isExtraMaps
  % Separate SPM process (second element in the batch)
  matlabbatch{2}.spm.tools.cat.stools.surfextract.data_surf(1) = cfg_dep('CAT12: Segmentation (current release): Left Central Surface', substruct('.','val', '{}',{1}, '.','val', '{}',{1}, '.','val', '{}',{1}, '.','val', '{}',{1}), substruct('()',{1}, '.','lhcentral', '()',{':'}));
  matlabbatch{2}.spm.tools.cat.stools.surfextract.GI = 1;     % Gyrification index
  matlabbatch{2}.spm.tools.cat.stools.surfextract.SD = 1;     % Sulcal depth
  matlabbatch{2}.spm.tools.cat.stools.surfextract.nproc = 0;  % Blocking call to CAT12
end
% Run SPM batch
spm_jobman('initcfg');
spm_jobman('run',matlabbatch);

Additional documentation

• Forum: Debugging CAT12 integration in Brainstorm

• Forum: CAT12 Missing Files + ICBM152 segmentation

• Git issue: Bugs CAT12 v1728