Difference between revisions of "2011 Summer Project Week long shape regression"

From NAMIC Wiki
Jump to: navigation, search
 
(25 intermediate revisions by the same user not shown)
Line 19: Line 19:
 
To begin processing longitudinal Huntington's disease data and to apply our shape regression framework to available data.  We are interested in the evolution of sub-cortical structures in the brain.
 
To begin processing longitudinal Huntington's disease data and to apply our shape regression framework to available data.  We are interested in the evolution of sub-cortical structures in the brain.
  
We would like to estimate continuous growth scenarios for several shapes of interest, which can eventually be combined with a framework for 4D registration or 4D atlas construction, to statistically analyze the growth variability within a population.
+
We would like to estimate continuous growth scenarios for several shapes of interest, which can eventually be combined with a framework for 4D registration or 4D atlas construction, to statistically analyze the growth variability within a population.
  
 
</div>
 
</div>
Line 36: Line 36:
 
<h3>Progress</h3>
 
<h3>Progress</h3>
  
<!-- Fill this out before Friday's summary presentations - list what you did and how well it worked. -->
+
'''Segmentation'''
  
[[File:Sub_cort_evolution_sigmaV_10_sigmaW_10_gammaR_0p1.gif‎|300px|thumb|center| Isolated view of the cerebellum from the same regression as the previous image, shown from the front, below, and the back of the brainColor denotes magnitude of velocityThe parameters used were sigmaV = 10, sigmaW = 10 and gamma = 0.1. [[Media:Sub_cort_evolution_sigmaV_10_sigmaW_10_gammaR_0p1.gif‎.gif|Click here for full size.]]]]
+
The 6 pairs of sub-cortical structures (amygdala, caudate, hippocampus, globus pallidus, putamen, lateral ventricle) were segmented using a deformable atlas based pipeline used at the University of Utah. The quality of the ventricles was very poor, so they were further improved by an active contour based segmentation tool, itkSNAP.  After this stage, we have 12 shapes at 3 time points.
 +
 
 +
'''Preprocessing'''
 +
 
 +
In order to prepare the shapes for longitudinal regression, the different time points must first be rigidly aligned.  We do not have point correspondences between our shapes, so we use a Gaussian mixture model based tool called gmmreg to rigidly align the shapes.
 +
 
 +
We initially align the entire shape complex, rather than individual shapes, in order to preserve the spatial relationship between the anatomical structures.  However, there was a small amount of translation and rotation remaining after this process that adversely impacts the growth estimation.  To further align the shapes, we also register each shape individually across time.   
 +
 
 +
'''Regression'''
 +
 
 +
Here, we estimate the continuous evolution of all 12 structures as a shape complexThree snapshots in time are shown in Fig. 1. We also investigate the evolution of shape volume, summarized in Fig 2.  It is important to note that we only model the evolution of shape, and volume is simply measured continuously after regression.
 +
 
 +
'''Remarks'''
 +
 
 +
* We are unsure about the quality of the segmentations,  as the volume for most segmented shapes increases from time point 2 to time point 3.
 +
* Aside from the volume analysis, we want to estimate growth scenarios for many subjects to statistically analyze the subtle differences in shape evolution over time.  
  
 
</div>
 
</div>
Line 44: Line 59:
  
 
<div style="width: 97%; float: left;">
 
<div style="width: 97%; float: left;">
 +
 +
<!-- [[Image:Sub_cort_evolution_sigmaV_10_sigmaW_10_gammaR_0p1.gif|center|Evolution of sub-cortical structures.]] -->
 +
 +
[[Image:Sub_cort_evo_snapshot.png|thumb|800px|center|'''Fig 1.''' Snapshots of the evolution of several sub-cortical structures.  Color denotes magnitude of velocity.  [[Media:Sub_cort_evolution_sigmaV_10_sigmaW_10_gammaR_0p1.gif|Click here for an animation.]] ]]
 +
 +
[[Image:Volume_sigmaV_10_sigmaW_10_gammaR_0p1.png|thumb|500px|center|'''Fig 2.'''  Volume measured after shape regression.  Plus signs denote target volume.]]
  
 
==References==
 
==References==
 
Fishbaugh, J., Durrleman, S., Gerig, G.  "Estimation of Smooth Growth Trajectories With Controlled Acceleration From Time Series Shape Data".  MICCAI 2011.  To appear.
 
Fishbaugh, J., Durrleman, S., Gerig, G.  "Estimation of Smooth Growth Trajectories With Controlled Acceleration From Time Series Shape Data".  MICCAI 2011.  To appear.

Latest revision as of 13:46, 24 June 2011

Home < 2011 Summer Project Week long shape regression

Longitudinal Shape Regression - Huntington's Disease

Key Investigators

  • Utah: James Fishbaugh, Marcel Prastawa, Guido Gerig
  • Iowa: Hans Johnson


Objective

To begin processing longitudinal Huntington's disease data and to apply our shape regression framework to available data. We are interested in the evolution of sub-cortical structures in the brain.

We would like to estimate continuous growth scenarios for several shapes of interest, which can eventually be combined with a framework for 4D registration or 4D atlas construction, to statistically analyze the growth variability within a population.

Approach, Plan

  • Segment sub-cortical structures
  • Estimate growth trajectories

Progress

Segmentation

The 6 pairs of sub-cortical structures (amygdala, caudate, hippocampus, globus pallidus, putamen, lateral ventricle) were segmented using a deformable atlas based pipeline used at the University of Utah. The quality of the ventricles was very poor, so they were further improved by an active contour based segmentation tool, itkSNAP. After this stage, we have 12 shapes at 3 time points.

Preprocessing

In order to prepare the shapes for longitudinal regression, the different time points must first be rigidly aligned. We do not have point correspondences between our shapes, so we use a Gaussian mixture model based tool called gmmreg to rigidly align the shapes.

We initially align the entire shape complex, rather than individual shapes, in order to preserve the spatial relationship between the anatomical structures. However, there was a small amount of translation and rotation remaining after this process that adversely impacts the growth estimation. To further align the shapes, we also register each shape individually across time.

Regression

Here, we estimate the continuous evolution of all 12 structures as a shape complex. Three snapshots in time are shown in Fig. 1. We also investigate the evolution of shape volume, summarized in Fig 2. It is important to note that we only model the evolution of shape, and volume is simply measured continuously after regression.

Remarks

  • We are unsure about the quality of the segmentations, as the volume for most segmented shapes increases from time point 2 to time point 3.
  • Aside from the volume analysis, we want to estimate growth scenarios for many subjects to statistically analyze the subtle differences in shape evolution over time.


Fig 1. Snapshots of the evolution of several sub-cortical structures. Color denotes magnitude of velocity. Click here for an animation.
Fig 2. Volume measured after shape regression. Plus signs denote target volume.

References

Fishbaugh, J., Durrleman, S., Gerig, G. "Estimation of Smooth Growth Trajectories With Controlled Acceleration From Time Series Shape Data". MICCAI 2011. To appear.