Difference between revisions of "2010 Winter Project Week WM ATLAS"

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<gallery>
 
<gallery>
 
Image:PW-SLC2010.png|[[2010_Winter_Project_Week#Projects|Projects List]]
 
Image:PW-SLC2010.png|[[2010_Winter_Project_Week#Projects|Projects List]]
Image:WM-seg-1.png|Automatically segmented fiber tracts.
+
Image:WM-seg-1.png|Input from example subject: Automatically segmented fiber tracts and fMRI peak locations. This data from 5 subjects has been used in matlab to build a fiber-fMRI distance model to enable prediction/detection of fiber tracts using fMRI.
Image:wholebraintractclustermeans.png|Example whole-brain tract cluster mean fibers.
+
Image:SlicerImage_1.png|Output: Yellow region is prediction of arcuate location in this patient, based on fMRI peaks (spheres). Predicted AF visualized in Slicer3 with fMRI points and actual patient's fiber tracts.
 +
Image:SlicerImage_0.png|Output: Predicted AF location visualized in Slicer3 with fibers clustered by python test code and colored using Mahnaz Maddah's cluster coloring in Slicer3.
 
</gallery>
 
</gallery>
  
 
==Key Investigators==
 
==Key Investigators==
* Lauren O'Donnell (Instructor, Harvard Medical School (BWH))
+
* Lauren O'Donnell (Harvard Medical School (BWH))
 +
* Luis Ibanez (Kitware Inc)
 
* Carl-Fredrik Westin (Professor, Harvard Medical School (BWH) )
 
* Carl-Fredrik Westin (Professor, Harvard Medical School (BWH) )
 
* William Wells (Professor, Harvard Medical School (BWH) )
 
* William Wells (Professor, Harvard Medical School (BWH) )
 
* Alexandra J Golby (Professor of Neurosurgery, Harvard Medical School (BWH) )
 
* Alexandra J Golby (Professor of Neurosurgery, Harvard Medical School (BWH) )
 +
* Gordon L. Kindlmann (Professor University of Chicago) (teem help/docs/implementation)
 +
* James Malcolm and Yogesh Rathi (2-tensor tractography)
 +
* Steve Pieper (advice on ipython and module implementation)
  
 
<div style="margin: 20px;">
 
<div style="margin: 20px;">
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<h3>Objective</h3>
 
<h3>Objective</h3>
  
Implement tract-based morphometry pipeline in 3D Slicer, including atlas-based WM (white matter) segmentation and whole-brain WM coordinate system generation.  Investigate integration of FMRI+DTI into atlas pipeline, for neurosurgical planning applications.
+
Eventual goal: Implement slicer module for neurosurgical planning using novel fMRI+DTI atlas.
 +
 
 +
Intermediate goals: Investigate re-implementation of tract-based morphometry pipeline in 3D Slicer, including clustering for atlas creation, atlas-based WM (white matter) segmentation and whole-brain WM coordinate system generation.  Investigate integration of FMRI+DTI into atlas pipeline, for neurosurgical planning applications.
  
This work is based on: Tract-Based Morphometry for White Matter Group Analysis.
 
Lauren J. O'Donnell, Carl-Fredrik Westin, and Alexandra J. Golby
 
NeuroImage 45(3):832-844, 2009
 
and
 
Automatic Tractography Segmentation Using a High-Dimensional White Matter Atlas
 
Lauren O'Donnell and Carl-Fredrik Westin
 
IEEE Transactions in Medical Imaging 26(11):1562-1575, 2007
 
 
</div>
 
</div>
  
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<h3>Approach, Plan</h3>
 
<h3>Approach, Plan</h3>
The original pipeline consists of (over a group):  
+
The original WM atlas pipeline consists of (over a group):  
 
* Preprocessing
 
* Preprocessing
** DTI and FA image calculation  
+
** DTI and FA image calculation (slicer)
** congealing registration of FA images  
+
** congealing registration of FA images (Lilla's code)
** whole-brain tract seeding  
+
** whole-brain tract seeding (slicer2)
** application of registration to tractography
+
** application of registration to tractography (matlab)
* EITHER atlas-based segmentation of tractography
+
** measurement of fiber-fMRI model (slicer2/matlab)
* OR atlas generation
+
* Atlas generation (matlab)
 
** clustering of (sample from) whole-brain tractography in group
 
** clustering of (sample from) whole-brain tractography in group
 
** expert labeling of clusters to give anatomical structures
 
** expert labeling of clusters to give anatomical structures
 
** the above produces an atlas that can be used to segment   
 
** the above produces an atlas that can be used to segment   
* analysis of segmented WM
+
* WM tract segmentation (matlab)
 +
** based on atlas, plus fMRI in future for IGT
 +
* analysis of segmented WM (matlab)
 
** optimal generation of tract-based coordinate systems per anatomical structure
 
** optimal generation of tract-based coordinate systems per anatomical structure
 
** export of cluster/structure based measurements (FA, etc)
 
** export of cluster/structure based measurements (FA, etc)
 
** some statistical analysis   
 
** some statistical analysis   
  
The eventual goal is re-implementation of much of the above in the Slicer3 framework. This will enable use of the pipeline for neuroscience research and our future investigation of DTI+fMRI atlases for neurosurgery.
+
We propose re-implementation of much of the above in python and/or Slicer3 framework. This will enable use of the pipeline by others and our investigation of DTI+fMRI atlases for neurosurgery.
  
 
</div>
 
</div>
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<h3>Progress</h3>
 
<h3>Progress</h3>
 +
We have tested/debugged the group registration and enabled Slicer3 display of matlab output for tract prediction.
 +
 
* Preprocessing
 
* Preprocessing
** work has begun on BatchMake modules for tensor calc and FA calculation in the group
+
** Debugging of ITK congealing with Luis.
** some investigation of using congealing implementation in ITK from NAMIC SandBox to replace our current use of original code by Lilla Zollei
+
** implementation of initial seeding pipeline script in ipython
 +
** Gordon has implemented tractography methods and some probing capability in teem, may allow more direct teem/itk/vtk dependencies
 +
* Clustering
 +
** initial single-subject cluster test implemented in python
 +
** communicated with Mahnaz Maddah to learn how to display clusters in Slicer3 (cell data array must be called ClusterId)
 +
* IGT fMRI+DTI atlas
 +
** Initial methods development: fiber-fMRI distance model (MICCAI Diffusion workshop 2009)
 +
** Output of matlab-generated tract predictions to slicer3 as nrrd volumes
 
</div>
 
</div>
 
</div>
 
</div>
  
 
<div style="width: 97%; float: left;">
 
<div style="width: 97%; float: left;">
 +
 +
==References==
 +
 +
This work is based on the papers
 +
 +
Defining Spatial Relationships Between fMRI and DTI Fiber Tracts
 +
Lauren J. O'Donnell, Laura E. Rigolo, Isaiah Norton, Carl-Fredrik Westin, and Alexandra J. Golby.
 +
MICCAI Workshop on Diffusion Modeling and the Fibre Cup, 2009
 +
 +
Tract-Based Morphometry for White Matter Group Analysis. Lauren J. O'Donnell, Carl-Fredrik Westin, and Alexandra J. Golby.
 +
NeuroImage 45(3):832-844, 2009
 +
 +
Automatic Tractography Segmentation Using a High-Dimensional White Matter Atlas.
 +
Lauren O'Donnell and Carl-Fredrik Westin.
 +
IEEE Transactions in Medical Imaging 26(11):1562-1575, 2007
 +
</div>

Latest revision as of 17:42, 8 January 2010

Home < 2010 Winter Project Week WM ATLAS

  • Input from example subject: Automatically segmented fiber tracts and fMRI peak locations. This data from 5 subjects has been used in matlab to build a fiber-fMRI distance model to enable prediction/detection of fiber tracts using fMRI.

  • Output: Yellow region is prediction of arcuate location in this patient, based on fMRI peaks (spheres). Predicted AF visualized in Slicer3 with fMRI points and actual patient's fiber tracts.

  • Output: Predicted AF location visualized in Slicer3 with fibers clustered by python test code and colored using Mahnaz Maddah's cluster coloring in Slicer3.

Key Investigators

  • Lauren O'Donnell (Harvard Medical School (BWH))
  • Luis Ibanez (Kitware Inc)
  • Carl-Fredrik Westin (Professor, Harvard Medical School (BWH) )
  • William Wells (Professor, Harvard Medical School (BWH) )
  • Alexandra J Golby (Professor of Neurosurgery, Harvard Medical School (BWH) )
  • Gordon L. Kindlmann (Professor University of Chicago) (teem help/docs/implementation)
  • James Malcolm and Yogesh Rathi (2-tensor tractography)
  • Steve Pieper (advice on ipython and module implementation)

Objective

Eventual goal: Implement slicer module for neurosurgical planning using novel fMRI+DTI atlas.

Intermediate goals: Investigate re-implementation of tract-based morphometry pipeline in 3D Slicer, including clustering for atlas creation, atlas-based WM (white matter) segmentation and whole-brain WM coordinate system generation. Investigate integration of FMRI+DTI into atlas pipeline, for neurosurgical planning applications.

Approach, Plan

The original WM atlas pipeline consists of (over a group):

  • Preprocessing
    • DTI and FA image calculation (slicer)
    • congealing registration of FA images (Lilla's code)
    • whole-brain tract seeding (slicer2)
    • application of registration to tractography (matlab)
    • measurement of fiber-fMRI model (slicer2/matlab)
  • Atlas generation (matlab)
    • clustering of (sample from) whole-brain tractography in group
    • expert labeling of clusters to give anatomical structures
    • the above produces an atlas that can be used to segment
  • WM tract segmentation (matlab)
    • based on atlas, plus fMRI in future for IGT
  • analysis of segmented WM (matlab)
    • optimal generation of tract-based coordinate systems per anatomical structure
    • export of cluster/structure based measurements (FA, etc)
    • some statistical analysis

We propose re-implementation of much of the above in python and/or Slicer3 framework. This will enable use of the pipeline by others and our investigation of DTI+fMRI atlases for neurosurgery.

Progress

We have tested/debugged the group registration and enabled Slicer3 display of matlab output for tract prediction.

  • Preprocessing
    • Debugging of ITK congealing with Luis.
    • implementation of initial seeding pipeline script in ipython
    • Gordon has implemented tractography methods and some probing capability in teem, may allow more direct teem/itk/vtk dependencies
  • Clustering
    • initial single-subject cluster test implemented in python
    • communicated with Mahnaz Maddah to learn how to display clusters in Slicer3 (cell data array must be called ClusterId)
  • IGT fMRI+DTI atlas
    • Initial methods development: fiber-fMRI distance model (MICCAI Diffusion workshop 2009)
    • Output of matlab-generated tract predictions to slicer3 as nrrd volumes

References

This work is based on the papers

Defining Spatial Relationships Between fMRI and DTI Fiber Tracts Lauren J. O'Donnell, Laura E. Rigolo, Isaiah Norton, Carl-Fredrik Westin, and Alexandra J. Golby. MICCAI Workshop on Diffusion Modeling and the Fibre Cup, 2009

Tract-Based Morphometry for White Matter Group Analysis. Lauren J. O'Donnell, Carl-Fredrik Westin, and Alexandra J. Golby. NeuroImage 45(3):832-844, 2009

Automatic Tractography Segmentation Using a High-Dimensional White Matter Atlas. Lauren O'Donnell and Carl-Fredrik Westin. IEEE Transactions in Medical Imaging 26(11):1562-1575, 2007

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