A Joint Network Optimization Framework to Predict Clinical Severity from Resting State Functional MRI Data
- URL: http://arxiv.org/abs/2009.03238v2
- Date: Fri, 22 Nov 2024 03:39:33 GMT
- Title: A Joint Network Optimization Framework to Predict Clinical Severity from Resting State Functional MRI Data
- Authors: Niharika Shimona D'Souza, Mary Beth Nebel, Nicholas Wymbs, Stewart H. Mostofsky, Archana Venkataraman,
- Abstract summary: We propose a novel framework to predict clinical severity from resting state fMRI (rs-fMRI) data.
We validate our framework on two separate datasets in a ten fold cross validation setting.
- Score: 3.276067241408604
- License:
- Abstract: We propose a novel optimization framework to predict clinical severity from resting state fMRI (rs-fMRI) data. Our model consists of two coupled terms. The first term decomposes the correlation matrices into a sparse set of representative subnetworks that define a network manifold. These subnetworks are modeled as rank-one outer-products which correspond to the elemental patterns of co-activation across the brain; the subnetworks are combined via patient-specific non-negative coefficients. The second term is a linear regression model that uses the patient-specific coefficients to predict a measure of clinical severity. We validate our framework on two separate datasets in a ten fold cross validation setting. The first is a cohort of fifty-eight patients diagnosed with Autism Spectrum Disorder (ASD). The second dataset consists of sixty three patients from a publicly available ASD database. Our method outperforms standard semi-supervised frameworks, which employ conventional graph theoretic and statistical representation learning techniques to relate the rs-fMRI correlations to behavior. In contrast, our joint network optimization framework exploits the structure of the rs-fMRI correlation matrices to simultaneously capture group level effects and patient heterogeneity. Finally, we demonstrate that our proposed framework robustly identifies clinically relevant networks characteristic of ASD.
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