Difference between revisions of "Algorithm:UNC:Old"

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DT-MRI tractography can be used as a coordinate system for computing statistics of diffusion tensor data.  The quantitative analysis of diffusion tensors takes into account the space of tensor measurements using a nonlinear Riemannian symmetric space framework.  Tracts of interest are represented as a medial spline attributed with cross-sectional statistics.
 
DT-MRI tractography can be used as a coordinate system for computing statistics of diffusion tensor data.  The quantitative analysis of diffusion tensors takes into account the space of tensor measurements using a nonlinear Riemannian symmetric space framework.  Tracts of interest are represented as a medial spline attributed with cross-sectional statistics.
  
[[Algorithm:UNC:DTI:Quantitative_Tract_Analysis|More...]]
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[[Algorithm:UNC:DTI#Quantitative_Tract_Analysis|More...]]
  
[[Algorithm:UNC:DTI:Quantitative_Tract_Analysis|'''Description''']] - [[Algorithm:UNC:DTI:Quantitative_Tract_Analysis#Publications|'''Publications''']] - [[Algorithm:UNC:DTI:Quantitative_Tract_Analysis#Software|'''Software''']]
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[[Algorithm:UNC:DTI#Quantitative_Tract_Analysis|'''Description''']] - [[Algorithm:UNC:DTI#Publications|'''Publications''']] - [[Algorithm:UNC:DTI#Software|'''Software''']]
  
 
=== Population Analysis from Deformable Registration ===
 
=== Population Analysis from Deformable Registration ===
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Analysis of populations of diffusion images typically requires time-consuming manual segmentation of structures of interest to obtain correspondance for statistics.  This project uses non-rigid registration of DTI images to produce a common coordinate system for hypothesis testing of diffusion properties.
 
Analysis of populations of diffusion images typically requires time-consuming manual segmentation of structures of interest to obtain correspondance for statistics.  This project uses non-rigid registration of DTI images to produce a common coordinate system for hypothesis testing of diffusion properties.
  
[[Algorithm:UNC:DTI:Population_Analysis|More...]]
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[[Algorithm:UNC:DTI#Population_Analysis|More...]]
  
[[Algorithm:UNC:DTI:Population_Analysis|'''Description''']] - [[Algorithm:UNC:DTI:Population_Analysis#Publications|'''Publications''']] - [[Algorithm:UNC:DTI:Population_Analysis#Software|'''Software''']]
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[[Algorithm:UNC:DTI#Population_Analysis|'''Description''']] - [[Algorithm:UNC:DTI#Publications|'''Publications''']] - [[Algorithm:UNC:DTI#Software|'''Software''']]
  
 
=== Influence of Imaging Noise on DTI Statistics (Collaboration with [[Algorithm:Utah|Utah]]) ===
 
=== Influence of Imaging Noise on DTI Statistics (Collaboration with [[Algorithm:Utah|Utah]]) ===
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Clinical acquisition of diffusion weighted images with high signal to noise ratio remains a challenge.  The goal of this project is to understand the impact of MR noise on quantiative statistics of diffusion properties such as anisotropy measures, trace, etc.
 
Clinical acquisition of diffusion weighted images with high signal to noise ratio remains a challenge.  The goal of this project is to understand the impact of MR noise on quantiative statistics of diffusion properties such as anisotropy measures, trace, etc.
  
[[Algorithm:UNC:DTI:Noise_Statistics|More...]]
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[[Algorithm:UNC:DTI#Noise_Statistics|'''Description''']] - [[Algorithm:UNC:DTI#Publications|'''Publications''']] - [[Algorithm:UNC:DTI#Software|'''Software''']]
  
 
= Shape Analysis of Brain Structures Across Groups =
 
= Shape Analysis of Brain Structures Across Groups =

Revision as of 16:47, 3 April 2007

Home < Algorithm:UNC:Old

UNC Algorithms page

Diffusion Tensor Imaging

DT-MRI provides a new method to investigate the geometry and properties of white matter in-vivo. Major goals of our research in DT-MRI analysis include tract-based regions of interest for statistics, population based analysis, and understanding the influence of noise on statistical measures.

Quantitative Analysis of Fiber Tract Bundles

DT-MRI tractography can be used as a coordinate system for computing statistics of diffusion tensor data. The quantitative analysis of diffusion tensors takes into account the space of tensor measurements using a nonlinear Riemannian symmetric space framework. Tracts of interest are represented as a medial spline attributed with cross-sectional statistics.

More...

Description - Publications - Software

Population Analysis from Deformable Registration

Analysis of populations of diffusion images typically requires time-consuming manual segmentation of structures of interest to obtain correspondance for statistics. This project uses non-rigid registration of DTI images to produce a common coordinate system for hypothesis testing of diffusion properties.

More...

Description - Publications - Software

Influence of Imaging Noise on DTI Statistics (Collaboration with Utah)

Clinical acquisition of diffusion weighted images with high signal to noise ratio remains a challenge. The goal of this project is to understand the impact of MR noise on quantiative statistics of diffusion properties such as anisotropy measures, trace, etc.

More...

Description - Publications - Software

Shape Analysis of Brain Structures Across Groups

Shape analysis has become of increasing relevance to the neuroimaging community due to its potential to precisely locate morphological changes between healthy and pathological structures. This project focuses on developing novel methodology and a comprehensive set of tools for the computation of 3D structural statistical shape analysis. There are several open problems in this area, ranging from multi-object analysis, enhanced shape correspondence to statistical analysis of shape with clinical covariates.

UNC Shape Analysis Framework using SPHARM-PDM

The UNC shape analysis is based on an analysis framework of objects with spherical topology, described mainly by sampled spherical harmonics SPHARM-PDM. The input of the shape analysis framework is a set of binary segmentations of a single brain structure, such as the hippocampus or caudate. These segmentations are converted into a shape description (SPHARM) with correspondence and analyzed via Hotelling T^2 two sample metric. More...

New:

  • First version of Shape Analysis Toolset available as part of UNC Neurolib open source (download) , this is to be added to the NAMIC toolkit.
  • Toolset distribution contains open data for other researcher to evaluate novel shape analysis enhancements
  • Slicer 3 modules for individual tools in the UNC Shape Analysis Toolset completed
  • Slicer 3 module for whole shape analysis pipeline in progress (based on BatchMake and distributed computing using Condor)
  • New shape analysis related papers:
    • 2 submissions to the Main MICCAI 2007 conference
    • Styner M, Xu SC, El-Sayed M, Gerig G, Correspondence Evaluation in Local Shape Analysis and Structural Subdivision, IEEE Symposium on Biomedical Imaging ISBI 2007, in print
    • Zhou C, Park DC, Styner M, Wang YM, ROI Constrained Statistical Surface Morphometry, IEEE Symposium on Biomedical Imaging ISBI 2007, in print
    • Nain D, Styner M, Niethammer M, Levitt JJ, Shenton ME, Gerig G, Bobick A, Tannenbaum A, Statistical Shape Analysis of Brain Structures Using Spherical Wavelets, IEEE Symposium on Biomedical Imaging ISBI 2007, in print
    • M. Styner, I. Oguz, S. Xu, D. Pantazis, and G. Gerig. Statistical group differences in anatomical shape analysis using hotelling T2 metric. Proc SPIE Medical Imaging Conference, in print, 2007.
    • C Cascio, M Styner, RG Smith, M Poe, G Gerig, H Hazlett, M Jomier, R Bammer, J Piven, Reduced relationship to cortical white matter revealed by tractography-based segmentation of the corpus callosum in yound children with developmental delay, Am J Psychiatry, 2006, (163) 2157-2163, December.

Description - Publications - Software

UNCShape CaudatePval MICCAI06.png

Population Based Correspondence

We are developing methodology to automatically find dense point correspondences between a collection of polygonal genus 0 meshes. The advantage of this method is independence from indivisual templates, as well as enhanced modeling properties. The method is based on minimizing a cost function that describes the goodness of correspondence. Apart from a cost function derived from the description length of the model, we also employ a cost function working with arbitrary local features. We extended the original methods to use surface curvature measurements, which are independent to differences of object aligment. More...

New:

  • Software available as part of UNC Neurolib open source (website)
  • Evaluation on lateral ventricles, hippocampi, caudates, striatum, femural bone. Outperforms standard MDL on complex structures.
  • Submission to MICCAI 2007 conference
  • Tobias Heimann, I. Oguz, I. Wolf, M. Styner, HP. Meinzer. Implementing the Automatic Generation of 3D Statistical Shape Models with ITK. Accepted to MICCAI 2006 Open Source Workshop. More...

Description - Publications - Software

Local Statistical Analysis via Permutation Tests

We have further developed a set of statistical testing methods that allow the analysis of local shape differences using the Hotelling T 2 two sample metric. Permutatioin tests are employed for the computation of statistical p-values, both raw and corrected for multiple comparisons. Resulting significance maps are easily visualized. Additional visualization of the group tests are provided via mean difference magnitude and vector maps, as well as maps of the group covariance information. Ongoing research focuses on incorporating covariates such as clinical scores into the testing scheme. More...

New:

  • Available as part of Shape Analysis Toolset in UNC Neurolib open source (download).
  • M. Styner, I. Oguz, S. Xu, C. Brechbuehler, D. Pantazis, J. Levitt, M. Shenton, G. Gerig. Framework for the Statistical Shape Analysis of Brain Structures using SPHARM-PDM. Accepted to MICCAI 2006 Open Source Workshop. More...


Description - Publications - Software

Collaborations with other groups in NAMIC

  • Algorithms:
    • Shape Analysis
      • Joint pipeline I/O formulation and development with Kitware (Brad Davis, Jim Miller) and MIT (Polina Golland)
      • Use of UNC statistical analysis for spherical wavelet shape with GeorgiaTech (Delphine Nain) and Utah (Tom Fletcher)
      • Use of UNC statistical analysis for combined multi-object correspondence establishment with Utah (Josh Cates, Tom Fletcher)
    • DTI
      • Statistics of tensors and noise in diffusion weighted imaging with Utah (Tom Fletcher)
  • Clinical:
    • Collaboration with Harvard on shape analysis and DTI analysis.