Difference between revisions of "Projects:TubularSurfaceSegmentation"

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* [[Image:GTTubSurfaceSeg-Slice_Img2.png | Slice-wise view of CB Segmentation result | 300px]] Slice-wise view of CB Segmentation result
 
* [[Image:GTTubSurfaceSeg-Slice_Img2.png | Slice-wise view of CB Segmentation result | 300px]] Slice-wise view of CB Segmentation result
 
* [[Image:GT-VesselSegByTubSeg-ResultIn3D-1.jpg | 3D visualization of vessel segmentation | 300px]] 3D View of vessel segmentation result: initial volume (blue), segmentation result (red), extracted center-line (green)
 
* [[Image:GT-VesselSegByTubSeg-ResultIn3D-1.jpg | 3D visualization of vessel segmentation | 300px]] 3D View of vessel segmentation result: initial volume (blue), segmentation result (red), extracted center-line (green)
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* [[Image:GT-VesselSegByTubSeg-ResultSliceView-1.jpg | Slice-wise visualization of vessel segmentation | 300px]] Slice-wise view of vessel segmentation result: segmentation result (green) superimposed on CTA image data
  
 
== Project Status ==
 
== Project Status ==

Revision as of 03:04, 9 February 2010

Home < Projects:TubularSurfaceSegmentation
Back to NA-MIC Collaborations, Georgia Tech Algorithms, Kitware Engineering

Tubular Surface Segmentation Framework

This is a new model for tubular surfaces that transforms the problem of detecting a surface in 3D space, to detecting a curve in 4D space. This model affords computation efficiency and stability (by the use of the Sobolev norm) and we have successfully tested its application in segmenting the Cingulum Bundle from DW-MRI of the brain as well as vessel segmentation from CT cardiac data.

Description

We have proposed a new model for tubular surfaces that represents a tubular surface as a center-line with a radius function associated with every point of the center-line. This transforms the problem of detecting a surface in 3D space, to detecting a curve in 4D space. Besides allowing us to impose a "soft" tubular shape prior, this also leads to computational efficiency over conventional surface segmentation approaches. We have also developed the moving end points implementation of this framework wherein the required input is only a few points in the interior of the structure of interest. This yields the additional advantage that the framework simulatenously returns both the 3D segmentation and the 3D skeleton of the structure eliminating the need for apriori knowledge of end points, and an expensive skeletonization step. The framework is applicable to different tubular anatomical structures in the body. We have so far applied it successfully to the Cingulum Bundle, and blood vessels.

Some Results

  • 3D visualization of CB segmentation 3D visualization of CB segmentation
  • Slice-wise view of CB Segmentation result Slice-wise view of CB Segmentation result
  • Slice-wise view of CB Segmentation result Slice-wise view of CB Segmentation result
  • 3D visualization of vessel segmentation 3D View of vessel segmentation result: initial volume (blue), segmentation result (red), extracted center-line (green)
  • Slice-wise visualization of vessel segmentation Slice-wise view of vessel segmentation result: segmentation result (green) superimposed on CTA image data

Project Status

  • Algorithm successfully implemented and tested in MATLAB for Cingulum Bundle (as well as vessel segmentation).

Key Investigators

  • Georgia Tech Algorithms: Vandana Mohan, Allen Tannenbaum
  • Kitware Engineering: Luis Ibanez

Publications

In Print

In Press

V. Mohan, G. Sundaramoorthi and A. Tannenbaum. Tubular Surface Segmentation for Extracting Anatomical Structures from Medical Imagery (in submission). IEEE Transactions on Medical Imaging.


Project Week Results: June 2009