introduction to freesurfer presented by sarah whittle & dominic dwyer19 th march 2009
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Introduction to FreeSurferPresented by Sarah Whittle & Dominic Dwyer 19th March 2009
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Talk Outline
1. Introduction
2. Individual Cortical (surface-based) and Volumetric
Analysis
3. Group Analyses (brief)
4. Structure-Function Integration (brief)
5. Working with Freesurfer
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Intro: What can we do with Freesurfer?
• Surface inflation and manipulation: Visualize structural and functional data; reveal data in sulcal depths
• Intersubject registration: Alternate spatial normalization
• Morphometric analysis: Cortical thickness; analysis of folding patterns
• Cortical Parcellation: Analysis of cortical subregions; fMRI ROI analysis
• Subcortical segmentation: Volumetric analysis; fMRI ROI analysis
• White matter parcellation: Volumetric analysis; DTI region of interest analysis
• Integrate with FSL tools: Spatial normalization of fMRI data; ROI analyses
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Intro: FreeSurfer Resources
• FreeSurfer Wiki can be VERY useful:
– http://surfer.nmr.mgh.harvard.edu/fswiki
– “can”: too much info & not 100% logically organised!
• 2008 Brisbane FSL/FreeSurfer workshop booklet available to loan from MNC lab
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Cortical (surface-based) Analysis Surface Reconstruction Theory
• Input: T1-weighted (MPRAGE,SPGR)• Segment white matter from rest of brain.• Find white/gray surface• Find pial surface• “Find” = create mesh
– Vertices, neighbors, triangles, coordinates– Accurately follows boundaries between tissue types– “Topologically Correct”
• closed surface, no donut holes• no self-intersections
• Subcortical Segmentation along the way
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Surface Model
• Mesh (“Finite Element”)
• Vertex = point of 6 triangles
• Neighborhood
• XYZ at each vertex
• Triangles/Faces ~ 150,000
• Area, Distance
• Curvature, Thickness
• Moveable
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White Matter Surface• Nudge orig surface
• Follow T1 intensity gradients
• Smoothness constraint
• Vertex Identity Stays
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Pial Surface
• Nudge white surface
• Follow T1 intensity gradients
• Vertex Identity Stays
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Cortical Thickness
white/gray surface
pial surface
lh.thickness, rh.thickness
• Distance between white and pial surfaces
• One value per vertex• Surface-based more accurate
than volume-based
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Curvature (Radial)• Circle tangent to
surface at each vertex• Curvature measure is
1/radius of circle• One value per vertex• Signed (sulcus/gyrus)• Actually use gaussian
curvature
lh.curv, rh.curv
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Rosas et al., 2002
Kuperberg et al., 2003
Gold et al., 2005
Rauch et al., 2004Salat et al., 2004
Fischl et al., 2000
Sailer et al., 2003
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Surface “Inflation”
Inflated Sphere
White Pial
•Vertex Identity (index) Preserved
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Non-Cortical Areas of Surface
Amygdala, Putamen, Hippocampus, Caudate, Ventricles, CC
Amygdala
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“Spherical” Registration
Sulcal Map
Spherical Inflation High-DimensionalRegistration toSpherical Template
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Inter-Subject Registration of Cortical Folding Patterns
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Volume Analysis: Automatic Individualized Segmentation
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ROI Atlas Creation• Hand label N data sets
– Volumetric (subcortical): CMA– Surface Based:
• Desikan/Killiany• Destrieux
• Map labels to common coordinate system (using spherical registration).
• Probabilistic Atlas– Probability of a label at a vertex/voxel (global spatial
info)– Sulcal & gyral geometry– Neighborhood relationships
• You can create your own atlases
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Automatic Labeling• Transform ML labels to individual subject*
• Adjust boundaries based on– Curvature/Intensity statistics– Neighborhood relationships
• Result: labels are customized to each individual.
* Formally, we compute maximum a posteriori estimate of the labels given the input data
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ICBM Atlas
Why not just register to an ROI Atlas?
12 DOF(Affine)
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Subject 1Subject 2 aligned with Subject 1
(Subject 1’s Surface)
Problems with Affine (12 DOF) Registration• ROIs need to be individualized.
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Can’t segment on intensity alone
0 20 40 60 80 100 1200
2
4
6
8
10
intensity
% v
oxe
ls i
n l
abel
WMGMlVThCaPuPaHpAm
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Volumetric Segmentation (aseg)
Caudate
Pallidum
Putamen
Amygdala
Hippocampus
Lateral Ventricle
Thalamus
White Matter
Cortex
Not Shown:Nucleus AccumbensCerebellum
Whole Brain Segmentation: Automated Labeling of Neuroanatomical Structures in the Human Brain, Fischl, B., D.H. Salat, E. Busa, M. Albert, M. Dieterich, C. Haselgrove, A. van der Kouwe, R. Killiany, D. Kennedy, S. Klaveness, A. Montillo, N. Makris, B. Rosen, and A.M. Dale, (2002). Neuron, 33:341-355.
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Volumetric Segmentation Atlas Description
• 39 Subjects
• 14 Male, 39 Female
• Ages 18-87– Young (1-22): 10– Mid (40-60): 10– Old Healthy (69+): 8– Old Alzheimer's (68+): 11
• Siemens 1.5T Vision (Wash U)
Whole Brain Segmentation: Automated Labeling of Neuroanatomical Structures in the Human Brain, Fischl, B., D.H. Salat, E. Busa, M. Albert, M. Dieterich, C. Haselgrove, A. van der Kouwe, R. Killiany, D. Kennedy, S. Klaveness, A. Montillo, N. Makris, B. Rosen, and A.M. Dale, (2002). Neuron, 33:341-355.
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Automatic Surface Parcellation:Desikan/Killiany Atlas
Precentral Gyrus Postcentral Gyrus
Superior Temporal Gyrus
An automated labeling system for subdividing the human cerebral cortex on MRI scans into gyral based regions of interest, Desikan, R.S., F. Segonne, B. Fischl, B.T. Quinn, B.C. Dickerson, D. Blacker, R.L. Buckner, A.M. Dale, R.P. Maguire, B.T. Hyman, M.S. Albert, and R.J. Killiany, (2006). NeuroImage 31(3):968-80.
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Desikan/Killiany Atlas
• 40 Subjects
• 14 Male, 26 Female
• Ages 18-87
• 34 cortical regions
• Siemens 1.5T Vision (Wash U)
An automated labeling system for subdividing the human cerebral cortex on MRI scans into gyral based regions of interest, Desikan, R.S., F. Segonne, B. Fischl, B.T. Quinn, B.C. Dickerson, D. Blacker, R.L. Buckner, A.M. Dale, R.P. Maguire, B.T. Hyman, M.S. Albert, and R.J. Killiany, (2006). NeuroImage 31(3):968-80.
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Automatic Surface Parcellation:Destrieux Atlas
Automatically Parcellating the Human Cerebral Cortex, Fischl, B., A. van der Kouwe, C. Destrieux, E. Halgren, F. Segonne, D. Salat, E. Busa, L. Seidman, J. Goldstein, D. Kennedy, V. Caviness, N. Makris, B. Rosen, and A.M. Dale, (2004). Cerebral Cortex, 14:11-22.
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Automatic Surface Parcellation:Destrieux Atlas
Automatically Parcellating the Human Cerebral Cortex, Fischl, B., A. van der Kouwe, C. Destrieux, E. Halgren, F. Segonne, D. Salat, E. Busa, L. Seidman, J. Goldstein, D. Kennedy, V. Caviness, N. Makris, B. Rosen, and A.M. Dale, (2004). Cerebral Cortex, 14:11-22.
• 58 Parcellation Units
• 12 Subjects
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Gyral White Matter Segmentation
Nearest Cortical Labelto point in White Matter
aparc+aseg wmparc
+ +
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Processing Stages• Specify Subjects and Surface measures• Assemble Data (mris_preproc):
• Resample into Common Space (fsaverage)• Smooth• Concatenate into one file
• Model and Contrasts (GLM)• Fit Model (Estimate) (mri_glmfit)• Correct for multiple comparisons• Visualize (tksurfer)
Surface-based group analysis
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Surface-based Measures
• Morphometric (eg, thickness)• Functional• PET• MEG/EEG• Diffusion (?) sampled just under the surface
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Surface-based Group Analysis in FreeSurfer
• Command-line based• Create a FreeSurfer Group Descriptor File (FSGD)• FreeSurfer creates design matrix• You still have to specify contrasts• Fit model (mri_glmfit)
• QDEC (GUI)• Limited to 2 discrete variables, 2 levels max• Limited to 2 continuous variables
GLM
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Visualisation with tksurfer
View->Configure->Overlay
Threshold:-log10(p),Eg, 2=.01
Saturation:-log10(p),Eg, 5=.00001
False DiscoveryRate, Eg, .01
File->LoadOverlay http://surfer.nmr.mgh.harvard.edu/docs/ftp/pub/docs/freesurfer.groupanalysis.pdf
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Function-Structure Integration inFreeSurfer
Why Is a Model of the Cortical Surface Useful?
Local functional organization of cortex is largely 2-dimensional! Eg, functional mapping of primary visual areas:
From (Sereno et al, 1995, Science). Also, smooth along surface
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Function-Structure Integration inFreeSurfer
• Basic Overview of process:– First: analyze your data with FEAT (No Smoothing)– Register FEAT to FreeSurfer Anatomical
• Automatic (FLIRT)• Manual (tkregister2)
– Sample FEAT output on the surface• Individual• Common Surface Space (Atlas/fsaverage)• ** Can display any functional data, eg, zstat, fzstat, cope, pe,
etc
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Function-Structure Integration inFreeSurfer
• Basic Overview of process (cont’d):• Mapping FreeSurfer Segmentations to FEAT
– ie, displaying functional data on subcortical/cortical segmentation
– ROI analysis based on segmentation
• Group Analysis– Using GFEAT data– Mri_glmfit
See Comprehensive Instructions at: http://surfer.nmr.mgh.harvard.edu/docs/ftp/pub/docs/freesurfer.feat.pdf
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Working with Freesurfer
• Unix command-line (Linux, MacOSX)
• GUI’s for viewing/editing– Tkmedit, tksurfer, tkregister
• Directory structure, naming conventions
• Pipeline– Recon-all: automated surface/volume analysis
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File Formats•FreeSurfer uses a unique file format (mgz = compressed MGH file)
• Can store 4D (like NIFTI)• cols, rows, slices, frames• Generic: volumes and surfaces
•Surface: lh.white• Curv: lh.curv, lh.sulc, lh.thickness• Annotation: lh.aparc.annot• Label: lh.pericalcarine.label• Unique to FreeSurfer • FreeSurfer can read/write:
• NIFTI, Analyze, MINC•FreeSurfer can read:
• DICOM, Siemens IMA, GE, AFNI
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FreeSurfer Directory Tree
bert
$SUBJECTS_DIR
fred jenny margaret …
Subject ID
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FreeSurfer Directory Tree
bert
bem label morph mri scripts surf tiff label
orig T1 brain wm aseg
•Subject ID•Subject Name
Each data set has its own unique SubjectId (eg, bert)
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Add Your Data• cd $SUBJECTS_DIR• mkdir –p bert/orig• mri_convert yourdicom.dcm bert/mri/orig/001.mgz• mri_convert yourdicom.dcm bert/mri/orig/002.mgz
bert
bem label morph mri scripts surf tiff label
orig
001.mgz 002.mgz
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Fully Automated Reconstruction
Come back in 48 hours …
Check your results – do the white and pial surfaces follow the boundaries?
-- Can be broken up
1. Create directory for data: mkdir –p $SUBJECTS_DIR/bert/orig
2. Copy/Convert data into directory: mri_convert file.dcm $SUBJECTS_DIR/bert/orig/001.mgz
3. Launch reconstruction: recon-all –s bert –autorecon-all
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Individual StagesVolumetric Processing Stages (subjid/mri):1. Motion Cor, Avg, Conform (orig.mgz)2. Talairach transform computation3. Non-uniform inorm (nu.mgz)4. Intensity Normalization 1 (T1.mgz)5. Skull Strip (brain.mgz)
6. EM Register (linear volumetric registration) 7. CA Intensity Normalization 8. CA Non-linear Volumetric Registration 9. CA Label (Volumetric Labeling) (aseg.mgz)
10. Intensity Normalization 2 (T1.mgz)11. White matter segmentation (wm.mgz)12. Edit WM With ASeg13. Fill and cut (filled.mgz)
Surface Processing Stages (subjid/surf):14. Tessellate (?h.orig)15. Smooth1 (?h.smoothwm)16. Inflate1 (?h.inflated)17. QSphere (?h.qsqhere)18. Automatic Topology Fixer (?h.orig)19. Euler Number20. Smooth221. Inflate222. Final Surfs (?h.white,?h.pial)23. Cortical Ribbon Mask
24. Spherical Morph25. Spherical Registration 26. Spherical Registration27. Map average curvature to subject28. Cortical Parcellation (Labeling)29. Cortical Parcellation Statistics30. Cortical Parcellation mapped to ASeg
recon-all -help Note: ?h.orig means lh.orig or rh.orig
Green = Manual Intervention?
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Workflow in Stages
1. recon-all –autorecon1 (Stages 1-5)2. Check talairach transform, skull strip, normalization (?)3. recon-all –autorecon2 (Stages 6-23)4. Check surfaces
1. Add control points: recon-all –autorecon2-cp (Stages 10-23)
2. Edit wm.mgz: recon-all –autorecon2-wm (Stages 13-23)3. Edit brain.mgz: recon-all –autorecon2-pial (Stage 23)
5. recon-all –autorecon3 (Stages 24-30)
Note: all stages can be run individually
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Results
• Volumes
• Surfaces
• Surface Overlays
• ROI Summaries
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Volumes
orig.mgz
• $SUBJECTS_DIR/bert/mri• All “Conformed” 2563, 1mm3
• Many more …
aseg.mgz
T1.mgz brainmask.mgz wm.mgz filled.mgzSubcortical Mass
aparc+aseg.mgz Volume Viewer:tkmedit
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Surfaces
orig white pial
inflated sphere,sphere.reg patch (flattened)• $SUBJECTS_DIR/bert/surf•Number/Identity of vertices stays the same (except patches)•XYZ Location Changes•Flattening not done as part of standard reconstruction
Surface Viewer:tksurfer
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Surface Overlays
• Value for each vertex• Color indicates value• Color: gray,red/green, heat, color table• Rendered on any surface• fMRI/Stat Maps too
lh.sulc on inflated lh.curv on inflated lh.thickness on inflated
lh.sulc on pial
lh.aparc.annot on inflated
lh.curv on inflated fMRI on flat
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ROI Summaries:
Index SegId NVoxels Volume_mm3 StructName normMean normStdDev normMin normMax normRange 1 1 0 0.0 Left-Cerebral-Exterior 0.0000 0.0000 0.0000 0.0000 0.0000 2 2 265295 265295.0 Left-Cerebral-White-Matter 106.6763 8.3842 35.0000 169.0000 134.0000 3 3 251540 251540.0 Left-Cerebral-Cortex 81.8395 10.2448 29.0000 170.0000 141.0000 4 4 7347 7347.0 Left-Lateral-Ventricle 42.5800 12.7435 21.0000 90.0000 69.0000 5 5 431 431.0 Left-Inf-Lat-Vent 66.2805 11.4191 30.0000 95.0000 65.0000 6 6 0 0.0 Left-Cerebellum-Exterior 0.0000 0.0000 0.0000 0.0000 0.0000 ….
$SUBJECTS_DIR/bert/statsaseg.stats – volume summaries?h.aparc.stats – desikan/killiany parcellation summaries?h.aparc.2005.stats – destrieux parcellation summarieswmparc.stats – white matter parcellation
Routines to generate spread sheets of group data• asegstats2table --help• aparcstats2table --help