Proposals:ComputationalAnatomy: Difference between revisions
(New page: '''Computational Anatomy''' = Motivation = = LaplaceBeltrami =) |
|||
Line 2: | Line 2: | ||
= Motivation = | = Motivation = | ||
From the NCBC grant 1R01-EB008171-01A1: | |||
The long-term research goal of the proposed project is to develop open-source statistical shape analysis software that will be leveraged by neuroimaging community using the VTK and ITK libraries. In Computational Anatomy (CA) today, all morphometric studies of shape are carried out by metric comparison of anatomical structures via vector field displacements relating the coordinatized structures. Two basic approaches have emerged: Gaussian random field localized statistical shape analysis for understanding connections and interrelations of anatomical substructures and their implicated role in neuropsychiatric illness and metric classifier construction for clustering disease populations via a global image based bio-marker measuring the metric structure of the space of anatomical shapes. Specifically, | |||
(a) Localized statistical shape analysis in coordinate systems is carried out via Gaussian Random Field (GRF) models where local shape changes in the form of vector field displacements are encoded as basis functions indexed over the coordinates. The basis functions signal the areas of statistically significant change with respect to shape coordinates. | |||
(b) Global image based metric classifiers are constructed by computing metric distances between anatomical structures and performing clustering via multi-dimensional scaling (MDS) and statistical methods based on linear-discriminant analysis (LDA). Classifiers based on morphometric biomarkers from diseased populations are rapidly emerging as part of the Morphometry Biomedical Informatics Research Network (BIRN) via the Semi-Automated SHape Analysis (SASHA) pipeline21. | |||
This proposal integrates the GRF approach for localized visualization and detection of anatomical change with the global metric classifier approach depicted in Fig. 1. The vehicles for integration and dissemination are modules for the 3D Slicer application and enhancements to the ITK processing library. | |||
= LaplaceBeltrami = | = LaplaceBeltrami = |
Revision as of 21:21, 29 April 2010
Computational Anatomy
Motivation
From the NCBC grant 1R01-EB008171-01A1:
The long-term research goal of the proposed project is to develop open-source statistical shape analysis software that will be leveraged by neuroimaging community using the VTK and ITK libraries. In Computational Anatomy (CA) today, all morphometric studies of shape are carried out by metric comparison of anatomical structures via vector field displacements relating the coordinatized structures. Two basic approaches have emerged: Gaussian random field localized statistical shape analysis for understanding connections and interrelations of anatomical substructures and their implicated role in neuropsychiatric illness and metric classifier construction for clustering disease populations via a global image based bio-marker measuring the metric structure of the space of anatomical shapes. Specifically, (a) Localized statistical shape analysis in coordinate systems is carried out via Gaussian Random Field (GRF) models where local shape changes in the form of vector field displacements are encoded as basis functions indexed over the coordinates. The basis functions signal the areas of statistically significant change with respect to shape coordinates. (b) Global image based metric classifiers are constructed by computing metric distances between anatomical structures and performing clustering via multi-dimensional scaling (MDS) and statistical methods based on linear-discriminant analysis (LDA). Classifiers based on morphometric biomarkers from diseased populations are rapidly emerging as part of the Morphometry Biomedical Informatics Research Network (BIRN) via the Semi-Automated SHape Analysis (SASHA) pipeline21. This proposal integrates the GRF approach for localized visualization and detection of anatomical change with the global metric classifier approach depicted in Fig. 1. The vehicles for integration and dissemination are modules for the 3D Slicer application and enhancements to the ITK processing library.