Difference between revisions of "2010 Winter Project Week ProstateSeg"

Revision as of 17:00, 6 January 2010

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Prostate segmentation result with the old (RandomWalk) algorithm - already integrated into Slicer

Implement a Slicer module from the shape-based prostate segmentation algorithm developed by Yi Gao et al.

Implement as a command-line module that can be downloaded and installed as a Slicer extension. Add automatic testing.

The algorithm can be compiled using CMake on both linux and windows, test data are available.

Yi Gao, Romeil Sandhu, Gabor Fichtinger, Allen Tannenbaum, A Coupled Global Registration and Segmentation Framework with Application to the Magnetic Resonance Prostate Imagery, IEEE Trans Med Imaging (in review)

Registration
- alignTrainingShapes.bash (execution time is about 30min)
  - make isotropic (z direction)
  - register
    - ShapeBased\_reg\src\imageRegByPointSet\c\affine\ => 1 executable
      - pairwise image registration (there are many supporting files in ShapeBased\_reg\src; the result is one executable)
      - input: two images from ShapeBased\_reg\trainingShapes
      - output: transformed moving image in uchar nrrd image format
  - make anisotropic:
    - maybe this step could be skipped (to have an atlas with isotropic images)
  - results are copied to ShapeBased\_reg\alignTrainingShapes
- alignTrainingShapesNonIso.bash: faster but not that accurate
Convert from binary to level set
- ShapeBased\_reg\alignTrainingShapes\toSFLS\ => 1 executable
  - Input: nrrd binary image
  - Output: level set description
  - For each binary image a level set image is generated and saved to ShapeBased\_reg\alignTrainingShapes\toSFLS
Learning using PCA
- ProstateSeg\ShapeBased\_reg\alignTrainingShapes\toSFLS\learn => 1 executable
- Input: shapeList.txt list of all level set files
- Output: mean shape and i-th eigen shape (multiplied by the eigen value),
- Execution time is about 1 minute, repeated for each eigen shape
Images are flipped, but the images to be segmented (or the training shapes) could be flipped instead.

ProstateSeg\ShapeBased\version20091203 => 1 executable (wholeseg)
- Input: image to be segmented, and two points (at the left and right side of the prostate, on a center axial slice in IJK space)
- Output: ?

@@ Line 59: / Line 59: @@
 **alignTrainingShapesNonIso.bash: faster but not that accurate
 *Convert from binary to level set
-*ShapeBased\_reg\alignTrainingShapes\toSFLS\ => 1 executable
+**ShapeBased\_reg\alignTrainingShapes\toSFLS\ => 1 executable
-**Input: nrrd binary image
+***Input: nrrd binary image
-**Output: level set description
+***Output: level set description
-**For each binary image a level set image is generated and saved to ShapeBased\_reg\alignTrainingShapes\toSFLS
+***For each binary image a level set image is generated and saved to ShapeBased\_reg\alignTrainingShapes\toSFLS
 *Learning using PCA
 **ProstateSeg\ShapeBased\_reg\alignTrainingShapes\toSFLS\learn => 1 executable
@@ Line 69: / Line 69: @@
 **Execution time is about 1 minute, repeated for each eigen shape
 *Images are flipped, but the images to be segmented (or the training shapes) could be flipped instead.
 ===Segmentation===
 *ProstateSeg\ShapeBased\version20091203 => 1 executable (wholeseg)
 **Input: image to be segmented, and two points (at the left and right side of the prostate, on a center axial slice in IJK space)
 **Output: ?