Regularized topological data analysis for extraction of coherent brain regions

Ishaan Batta; Nicolas Honnorat; Christos Davatzikos

doi:10.1117/12.2512524

Regularized topological data analysis for extraction of coherent brain regions

Ishaan Batta, Nicolas Honnorat, Christos Davatzikos

Producción científica: Conference contribution

Resumen

Clustering is widely used in medical imaging to reduce data dimension and discover subgroups in patient populations. However, most of the current clustering algorithms depend on scale parameters which are especially difficult to select. Persistence homology has been introduced to address this issue. This topological data analysis framework analyses a dataset at multiple scales by generating clusters of increasing sizes, similar to single-linkage hierarchical clustering. Because of this approach, however, the results are sensitive to the presence of noise and outliers. Several strategies have been suggested to fix this issue. In this paper, we support this research effort by demonstrating how gradient preserving data smoothings, such as total variation regularization, can improve the stability of persistence homology results, and we derive analytical confidence regions for the significance of the persistence measured for clusters based on Pearson distances. We demonstrate the advantages of our methods by analysing structural and functional MRI data released by the Human Connectome Project.

Idioma original	English (US)
Título de la publicación alojada	Medical Imaging 2019
Subtítulo de la publicación alojada	Image Processing
Editores	Elsa D. Angelini, Elsa D. Angelini, Elsa D. Angelini, Bennett A. Landman
Editorial	SPIE
ISBN (versión digital)	9781510625457
DOI	https://doi.org/10.1117/12.2512524
Estado	Published - 2019
Publicado de forma externa	Sí
Evento	Medical Imaging 2019: Image Processing - San Diego, United States Duración: feb 19 2019 → feb 21 2019

Serie de la publicación

Nombre	Progress in Biomedical Optics and Imaging - Proceedings of SPIE
Volumen	10949
ISSN (versión impresa)	1605-7422

Conference

Conference	Medical Imaging 2019: Image Processing
País/Territorio	United States
Ciudad	San Diego
Período	2/19/19 → 2/21/19

ASJC Scopus subject areas

Electronic, Optical and Magnetic Materials
Atomic and Molecular Physics, and Optics
Biomaterials
Radiology Nuclear Medicine and imaging

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10.1117/12.2512524

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Batta, I., Honnorat, N., & Davatzikos, C. (2019). Regularized topological data analysis for extraction of coherent brain regions. En E. D. Angelini, E. D. Angelini, E. D. Angelini, & B. A. Landman (Eds.), Medical Imaging 2019: Image Processing Artículo 109490I (Progress in Biomedical Optics and Imaging - Proceedings of SPIE; Vol. 10949). SPIE. https://doi.org/10.1117/12.2512524

Regularized topological data analysis for extraction of coherent brain regions. / Batta, Ishaan; Honnorat, Nicolas; Davatzikos, Christos.
Medical Imaging 2019: Image Processing. ed. / Elsa D. Angelini; Elsa D. Angelini; Elsa D. Angelini; Bennett A. Landman. SPIE, 2019. 109490I (Progress in Biomedical Optics and Imaging - Proceedings of SPIE; Vol. 10949).

Producción científica: Conference contribution

Batta, I, Honnorat, N & Davatzikos, C 2019, Regularized topological data analysis for extraction of coherent brain regions. En ED Angelini, ED Angelini, ED Angelini & BA Landman (eds.), Medical Imaging 2019: Image Processing., 109490I, Progress in Biomedical Optics and Imaging - Proceedings of SPIE, vol. 10949, SPIE, Medical Imaging 2019: Image Processing, San Diego, United States, 2/19/19. https://doi.org/10.1117/12.2512524

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abstract = "Clustering is widely used in medical imaging to reduce data dimension and discover subgroups in patient populations. However, most of the current clustering algorithms depend on scale parameters which are especially difficult to select. Persistence homology has been introduced to address this issue. This topological data analysis framework analyses a dataset at multiple scales by generating clusters of increasing sizes, similar to single-linkage hierarchical clustering. Because of this approach, however, the results are sensitive to the presence of noise and outliers. Several strategies have been suggested to fix this issue. In this paper, we support this research effort by demonstrating how gradient preserving data smoothings, such as total variation regularization, can improve the stability of persistence homology results, and we derive analytical confidence regions for the significance of the persistence measured for clusters based on Pearson distances. We demonstrate the advantages of our methods by analysing structural and functional MRI data released by the Human Connectome Project.",

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author = "Ishaan Batta and Nicolas Honnorat and Christos Davatzikos",

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PY - 2019

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N2 - Clustering is widely used in medical imaging to reduce data dimension and discover subgroups in patient populations. However, most of the current clustering algorithms depend on scale parameters which are especially difficult to select. Persistence homology has been introduced to address this issue. This topological data analysis framework analyses a dataset at multiple scales by generating clusters of increasing sizes, similar to single-linkage hierarchical clustering. Because of this approach, however, the results are sensitive to the presence of noise and outliers. Several strategies have been suggested to fix this issue. In this paper, we support this research effort by demonstrating how gradient preserving data smoothings, such as total variation regularization, can improve the stability of persistence homology results, and we derive analytical confidence regions for the significance of the persistence measured for clusters based on Pearson distances. We demonstrate the advantages of our methods by analysing structural and functional MRI data released by the Human Connectome Project.

AB - Clustering is widely used in medical imaging to reduce data dimension and discover subgroups in patient populations. However, most of the current clustering algorithms depend on scale parameters which are especially difficult to select. Persistence homology has been introduced to address this issue. This topological data analysis framework analyses a dataset at multiple scales by generating clusters of increasing sizes, similar to single-linkage hierarchical clustering. Because of this approach, however, the results are sensitive to the presence of noise and outliers. Several strategies have been suggested to fix this issue. In this paper, we support this research effort by demonstrating how gradient preserving data smoothings, such as total variation regularization, can improve the stability of persistence homology results, and we derive analytical confidence regions for the significance of the persistence measured for clusters based on Pearson distances. We demonstrate the advantages of our methods by analysing structural and functional MRI data released by the Human Connectome Project.

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Regularized topological data analysis for extraction of coherent brain regions

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