Journal
NETWORK NEUROSCIENCE
Volume 6, Issue 3, Pages 916-933Publisher
MIT PRESS
DOI: 10.1162/netn_a_00258
Keywords
Structural connectivity; Functional connectivity; Gray matter networks; Multiple sclerosis; Multilayer
Categories
Funding
- Instituto de Salud Carlos III [PI15/00587, PI18/01030]
- Red Espanola de Esclerosis Multiple [RD16/0015/0002, RD16/0015/0003, RD12/0032/0002, RD12/0060/01-02]
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This study presents a framework that merges multiple brain connectivity networks and validates its effectiveness. The framework was applied to a cohort of multiple sclerosis patients and successfully identified regions with connectivity deterioration.
Author Summary This study presents the design, development, and validation of a framework that merges morphological, structural, and functional brain connectivity networks into one multilayer network. To validate our framework, several metrics from graph theory are expanded and adapted to our specific domain characteristics. This proof of concept was applied to a cohort of people with multiple sclerosis, and results show that some brain regions with a synchronized connectivity deterioration could be identified. In recent years, research on network analysis applied to MRI data has advanced significantly. However, the majority of the studies are limited to single networks obtained from resting-state fMRI, diffusion MRI, or gray matter probability maps derived from T1 images. Although a limited number of previous studies have combined two of these networks, none have introduced a framework to combine morphological, structural, and functional brain connectivity networks. The aim of this study was to combine the morphological, structural, and functional information, thus defining a new multilayer network perspective. This has proved advantageous when jointly analyzing multiple types of relational data from the same objects simultaneously using graph- mining techniques. The main contribution of this research is the design, development, and validation of a framework that merges these three layers of information into one multilayer network that links and relates the integrity of white matter connections with gray matter probability maps and resting-state fMRI. To validate our framework, several metrics from graph theory are expanded and adapted to our specific domain characteristics. This proof of concept was applied to a cohort of people with multiple sclerosis, and results show that several brain regions with a synchronized connectivity deterioration could be identified.
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