Integrating functional connectivity and MVPA through a multiple constraint network analysis

Traditional general linear model-based brain mapping efforts using functional neuroimaging are complemented by more recent multivariate pattern analyses (MVPA) that apply machine learning techniques to identify the cognitive states associated with regional BOLD activation patterns, and by connectivi...

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Main Authors: Chris McNorgan, Gregory J. Smith, Erica S. Edwards
Format: Article
Language:English
Published: Elsevier 2020-03-01
Series:NeuroImage
Subjects:
Online Access:http://www.sciencedirect.com/science/article/pii/S1053811919310031
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spelling doaj-5b101f1bb3d44544a5282acb8c54a0342020-11-25T02:59:25ZengElsevierNeuroImage1095-95722020-03-01208116412Integrating functional connectivity and MVPA through a multiple constraint network analysisChris McNorgan0Gregory J. Smith1Erica S. Edwards2Corresponding author.; University at Buffalo, The State University of New York, United StatesUniversity at Buffalo, The State University of New York, United StatesUniversity at Buffalo, The State University of New York, United StatesTraditional general linear model-based brain mapping efforts using functional neuroimaging are complemented by more recent multivariate pattern analyses (MVPA) that apply machine learning techniques to identify the cognitive states associated with regional BOLD activation patterns, and by connectivity analyses that identify networks of interacting regions that support particular cognitive processes. We introduce a novel analysis representing the union of these approaches, and explore the insights gained when MVPA and functional connectivity analyses are allowed to mutually constrain each other within a single model. We explored multisensory semantic representations of concrete object concepts using a self-paced multisensory imagery task. Multilayer neural networks learned the real-world categories associated with macro-scale cortical BOLD activity patterns from the task, with some models additionally encoding regional functional connectivity. Models trained to encode functional connections demonstrated superior classification accuracy and more pronounced lesion-site appropriate category-specific impairments. We replicated these results in a data set from the openneuro.org open fMRI data repository. We conclude that mutually constrained network analyses encourage parsimonious models that may benefit from improved biological plausibility and facilitate discovery.http://www.sciencedirect.com/science/article/pii/S1053811919310031Computational modelingConnectivityMVPASemantic memoryBrain mapping
collection DOAJ
language English
format Article
sources DOAJ
author Chris McNorgan
Gregory J. Smith
Erica S. Edwards
spellingShingle Chris McNorgan
Gregory J. Smith
Erica S. Edwards
Integrating functional connectivity and MVPA through a multiple constraint network analysis
NeuroImage
Computational modeling
Connectivity
MVPA
Semantic memory
Brain mapping
author_facet Chris McNorgan
Gregory J. Smith
Erica S. Edwards
author_sort Chris McNorgan
title Integrating functional connectivity and MVPA through a multiple constraint network analysis
title_short Integrating functional connectivity and MVPA through a multiple constraint network analysis
title_full Integrating functional connectivity and MVPA through a multiple constraint network analysis
title_fullStr Integrating functional connectivity and MVPA through a multiple constraint network analysis
title_full_unstemmed Integrating functional connectivity and MVPA through a multiple constraint network analysis
title_sort integrating functional connectivity and mvpa through a multiple constraint network analysis
publisher Elsevier
series NeuroImage
issn 1095-9572
publishDate 2020-03-01
description Traditional general linear model-based brain mapping efforts using functional neuroimaging are complemented by more recent multivariate pattern analyses (MVPA) that apply machine learning techniques to identify the cognitive states associated with regional BOLD activation patterns, and by connectivity analyses that identify networks of interacting regions that support particular cognitive processes. We introduce a novel analysis representing the union of these approaches, and explore the insights gained when MVPA and functional connectivity analyses are allowed to mutually constrain each other within a single model. We explored multisensory semantic representations of concrete object concepts using a self-paced multisensory imagery task. Multilayer neural networks learned the real-world categories associated with macro-scale cortical BOLD activity patterns from the task, with some models additionally encoding regional functional connectivity. Models trained to encode functional connections demonstrated superior classification accuracy and more pronounced lesion-site appropriate category-specific impairments. We replicated these results in a data set from the openneuro.org open fMRI data repository. We conclude that mutually constrained network analyses encourage parsimonious models that may benefit from improved biological plausibility and facilitate discovery.
topic Computational modeling
Connectivity
MVPA
Semantic memory
Brain mapping
url http://www.sciencedirect.com/science/article/pii/S1053811919310031
work_keys_str_mv AT chrismcnorgan integratingfunctionalconnectivityandmvpathroughamultipleconstraintnetworkanalysis
AT gregoryjsmith integratingfunctionalconnectivityandmvpathroughamultipleconstraintnetworkanalysis
AT ericasedwards integratingfunctionalconnectivityandmvpathroughamultipleconstraintnetworkanalysis
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