Difference between revisions of "Projects:fMRIClustering"

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''Generative Model for Functional Connectivity''
 
''Generative Model for Functional Connectivity''
  
We formulate the problem of characterizing connectivity as a partition of voxels into subsets
+
We formulate the problem of characterizing connectivity as a partition of voxels into subsets that are well characterized by a certain number of representative hypotheses, or time courses, based on the similarity of their time courses to each hypothesis. We model the fMRI signal at each voxel as generated by a mixture of Gaussian distributions whose centers are the desired representative time courses. Using the EM algorithm to solve the corresponding model-fitting problem, we alternatively estimate the representative time courses and cluster assignments to improve our random initialization.  
Spatial Activation Patterns in fMRI that are well characterized by Ns representative hypotheses, or time courses,
 
m1; : : : mNs based on the similarity of their time courses to each hypothesis.
 
We model the fMRI signal Y at each voxel as generated by the mixture pY(y) =
 
PNs
 
s=1 �spYjS(yjs) over Ns conditional likelihoods pYjS(yjs) [15]. �s is the prior
 
probability that a voxel belongs to system s 2 f1; : : : ;Nsg. Following a commonly
 
used approach in fMRI analysis, we model the class-conditional densities
 
as normal distributions centered around the system mean time course, i.e.,
 
pYjS(yjs) = N(y;ms;�s). The high dimensionality of the fMRI data makes modeling
 
a full covariance matrix impractical. Instead, most methods either limit the
 
modeling to estimating variance elements, or model the time course dynamics as
 
an auto-regressive (AR) process. At this stage, we take the simpler approach of
 
modeling variance and note that the mixture model estimation can be straightforwardly
 
extended to include an AR model. Unlike separate dimensionality reduction
 
procedures, this approach follows closely the notions of functional similarity
 
used by the detection methods in fMRI. In other words, we keep the notion of
 
co-activation consistent with the standard analysis and instead rede�ne how the
 
co-activation patterns are represented and extracted from images.
 
This unsupervised technique generalizes
 
connectivity analysis to situations where candidate seeds are difficult to
 
identify reliably or are unknown.
 
 
 
 
 
 
 
Recently, we have applied this method to the cingulum bundle, as shown in the following images:
 
 
 
 
 
''Fiber Bundle Segmentation''
 
 
 
 
 
 
 
{|
 
|+ '''Fig 2. Cingulum Bundle Volumetric Fiber Bundles Segmentation Results'''
 
|valign="top"|[[Image:ResultZoomedOut.png |thumb|250px|Zoomed Out View]]
 
|valign="top"|[[Image:ZoomedResultWithModel.png |thumb|250px|Zoomed In View]]
 
|}
 
 
 
 
 
  
 
''Experimental Result''
 
''Experimental Result''
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We used data from 7 subjects with a diverse set of visual experiments including localizer, morphing, rest, internal tasks, and movie. The functional scans were pre-processed for motion artifacts, manually aligned into the Talairach coordinate system, detrended (removing linear trends in the
 
We used data from 7 subjects with a diverse set of visual experiments including localizer, morphing, rest, internal tasks, and movie. The functional scans were pre-processed for motion artifacts, manually aligned into the Talairach coordinate system, detrended (removing linear trends in the
 
baseline activation) and smoothed (8mm kernel).
 
baseline activation) and smoothed (8mm kernel).
 
  
 
{|
 
{|
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|valign="top"|[[Image:mit_fmri_clustering_parcellation2_shb7.png |400px]]
 
|valign="top"|[[Image:mit_fmri_clustering_parcellation2_shb7.png |400px]]
 
|}
 
|}
 
  
 
''Project Status''
 
''Project Status''

Revision as of 21:38, 9 November 2007

Home < Projects:fMRIClustering
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fMRI Clustering

In the classical functional connectivity analysis, networks of interest are defined based on correlation with the mean time course of a user-selected `seed' region. Further, the user has to also specify a subject-specific threshold at which correlation values are deemed significant. In this project, we simultaneously estimate the optimal representative time courses that summarize the fMRI data well and the partition of the volume into a set of disjoint regions that are best explained by these representative time courses. This approach to functional connectivity analysis offers two advantages. First, is removes the sensitivity of the analysis to the details of the seed selection. Second, it substantially simplifies group analysis by eliminating the need for the subject-specific threshold. Our experimental results indicate that the functional segmentation provides a robust, anatomically meaningful and consistent model for functional connectivity in fMRI.

Currently, we are investigating the application of such clustering algorithms in detection of functional connectivity in high-level

Description

Generative Model for Functional Connectivity

We formulate the problem of characterizing connectivity as a partition of voxels into subsets that are well characterized by a certain number of representative hypotheses, or time courses, based on the similarity of their time courses to each hypothesis. We model the fMRI signal at each voxel as generated by a mixture of Gaussian distributions whose centers are the desired representative time courses. Using the EM algorithm to solve the corresponding model-fitting problem, we alternatively estimate the representative time courses and cluster assignments to improve our random initialization.

Experimental Result

We used data from 7 subjects with a diverse set of visual experiments including localizer, morphing, rest, internal tasks, and movie. The functional scans were pre-processed for motion artifacts, manually aligned into the Talairach coordinate system, detrended (removing linear trends in the baseline activation) and smoothed (8mm kernel).

Fig 1. 2-System Parcellation. Group-wise result.
Detailed View of the Cingulum Bundle Anchor Tract
Fig 2. 2-System Parcelation. Results for all 7 subjects.
Mit fmri clustering parcellation2 shb1 4.png
Mit fmri clustering parcellation2 shb5 6.png
Mit fmri clustering parcellation2 shb7.png

Project Status

  • Working 3D implementation in Matlab using the C-based Mex functions.
  • Currently porting to ITK. (last updated 18/Apr/2007)

Key Investigators

  • MIT: Danial Lashkari, Polina Golland, Nancy Kanwisher

Publications

In print

  • P. Golland, Y. Golland, R. Malach. Detection of Spatial Activation Patterns As Unsupervised Segmentation of fMRI Data. In Proceedings of MICCAI: International Conference on Medical Image Computing and Computer Assisted Intervention, 110-118, 2007.

In press

  • D. Lashkari, P. Golland. Convex Clustering with Exemplar-Based Models. In NIPS: Advances in Neural Information Processing Systems, 2007.

Links