Interindividual Covariations of Brain Functional and Structural Connectivities Are Decomposed Blindly to Subnetworks: A Fusion-Based Approach.
Details
Serval ID
serval:BIB_DB35748FE152
Type
Article: article from journal or magazin.
Collection
Publications
Institution
Title
Interindividual Covariations of Brain Functional and Structural Connectivities Are Decomposed Blindly to Subnetworks: A Fusion-Based Approach.
Journal
Journal of magnetic resonance imaging
ISSN
1522-2586 (Electronic)
ISSN-L
1053-1807
Publication state
Published
Issued date
06/2020
Peer-reviewed
Oui
Volume
51
Number
6
Pages
1779-1788
Language
english
Notes
Publication types: Journal Article
Publication Status: ppublish
Publication Status: ppublish
Abstract
Studying brain interindividual variations has recently gained interest to understand different human behaviors. It is particularly important to investigate how a variety of functional differences can be associated with a few differences in brain structure. It would be more meaningful if such an investigation is performed jointly at the network level to connect structural building blocks to functional variations modules.
To decompose the interindividual variations of brain in the form of mutual functional and structural subnetworks based on a data-driven approach.
Retrospective.
In all, 92 healthy subjects.
3T Siemens/MPRAGE, diffusion spectrum imaging (DSI) acquisition protocol, gradient echo sequence.
The proposed approach was quantitatively assessed by examining the consistency of the networks against the number of subjects. Distribution of the obtained components across brain regions was studied and their relevance was qualitatively evaluated by comparison to variations that had been independently reported previously.
Permutation test, two-sample t-test, Pearson correlation coefficient.
Ten pairs of components including functional and structural subnetworks were obtained. Assessing the reproducibility of the proposed method with respect to the sample size indicated reliable detection of connections (above 70%) for all components by reducing the number of subjects to 70. Specifically, one of the functional subnetworks can be used to distinguish left-handed from right-handed people (P = 2.6 × 10 <sup>-8</sup> ) as the basic interindividual variation. This functional subnetwork has a main overlap (40.18%) with the somatomotor system and the Broca part was captured in its corresponding structural subnetwork.
These results show that the proposed method can reveal intersubject variations systematically through a mathematical algorithm of joint independent component analysis. They confirm that intersubject variations can be expressed in the form of building blocks. In contrast to the functional subnetworks that were discoverable independently, their structural counterparts were found and interpreted only in conjunction with the functional subnetworks.
3 Technical Efficacy: Stage 1 J. Magn. Reson. Imaging 2020;51:1779-1788.
To decompose the interindividual variations of brain in the form of mutual functional and structural subnetworks based on a data-driven approach.
Retrospective.
In all, 92 healthy subjects.
3T Siemens/MPRAGE, diffusion spectrum imaging (DSI) acquisition protocol, gradient echo sequence.
The proposed approach was quantitatively assessed by examining the consistency of the networks against the number of subjects. Distribution of the obtained components across brain regions was studied and their relevance was qualitatively evaluated by comparison to variations that had been independently reported previously.
Permutation test, two-sample t-test, Pearson correlation coefficient.
Ten pairs of components including functional and structural subnetworks were obtained. Assessing the reproducibility of the proposed method with respect to the sample size indicated reliable detection of connections (above 70%) for all components by reducing the number of subjects to 70. Specifically, one of the functional subnetworks can be used to distinguish left-handed from right-handed people (P = 2.6 × 10 <sup>-8</sup> ) as the basic interindividual variation. This functional subnetwork has a main overlap (40.18%) with the somatomotor system and the Broca part was captured in its corresponding structural subnetwork.
These results show that the proposed method can reveal intersubject variations systematically through a mathematical algorithm of joint independent component analysis. They confirm that intersubject variations can be expressed in the form of building blocks. In contrast to the functional subnetworks that were discoverable independently, their structural counterparts were found and interpreted only in conjunction with the functional subnetworks.
3 Technical Efficacy: Stage 1 J. Magn. Reson. Imaging 2020;51:1779-1788.
Keywords
brain subnetworks, diffusion tensor imaging (DTI), fusion analysis, independent component analysis (ICA), intersubject variations, resting state fMRI
Pubmed
Web of science
Create date
14/11/2019 9:19
Last modification date
13/06/2020 5:20