Diffuse neural coupling mediates complex network dynamics through the formation of quasi-critical brain states

A principle of neuroanatomy, namely diffuse connectivity, is modeled using a large-scale network of corticothalamic neural masses. We demonstrate that increases in diffuse coupling transition the system through a quasi-critical regime, which coincides with known signatures of complex adaptive brain...

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Autores principales: Eli J. Müller, Brandon R. Munn, James M. Shine
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Lenguaje:EN
Publicado: Nature Portfolio 2020
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Acceso en línea:https://doaj.org/article/de70514aed2f449cb8f0228ea25f725c
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spelling oai:doaj.org-article:de70514aed2f449cb8f0228ea25f725c2021-12-02T13:57:45ZDiffuse neural coupling mediates complex network dynamics through the formation of quasi-critical brain states10.1038/s41467-020-19716-72041-1723https://doaj.org/article/de70514aed2f449cb8f0228ea25f725c2020-12-01T00:00:00Zhttps://doi.org/10.1038/s41467-020-19716-7https://doaj.org/toc/2041-1723A principle of neuroanatomy, namely diffuse connectivity, is modeled using a large-scale network of corticothalamic neural masses. We demonstrate that increases in diffuse coupling transition the system through a quasi-critical regime, which coincides with known signatures of complex adaptive brain dynamics, and model fits to human imaging data orient task states to higher levels of diffusivity, consistent with the influence of arousal systems.Eli J. MüllerBrandon R. MunnJames M. ShineNature PortfolioarticleScienceQENNature Communications, Vol 11, Iss 1, Pp 1-11 (2020)
institution DOAJ
collection DOAJ
language EN
topic Science
Q
spellingShingle Science
Q
Eli J. Müller
Brandon R. Munn
James M. Shine
Diffuse neural coupling mediates complex network dynamics through the formation of quasi-critical brain states
description A principle of neuroanatomy, namely diffuse connectivity, is modeled using a large-scale network of corticothalamic neural masses. We demonstrate that increases in diffuse coupling transition the system through a quasi-critical regime, which coincides with known signatures of complex adaptive brain dynamics, and model fits to human imaging data orient task states to higher levels of diffusivity, consistent with the influence of arousal systems.
format article
author Eli J. Müller
Brandon R. Munn
James M. Shine
author_facet Eli J. Müller
Brandon R. Munn
James M. Shine
author_sort Eli J. Müller
title Diffuse neural coupling mediates complex network dynamics through the formation of quasi-critical brain states
title_short Diffuse neural coupling mediates complex network dynamics through the formation of quasi-critical brain states
title_full Diffuse neural coupling mediates complex network dynamics through the formation of quasi-critical brain states
title_fullStr Diffuse neural coupling mediates complex network dynamics through the formation of quasi-critical brain states
title_full_unstemmed Diffuse neural coupling mediates complex network dynamics through the formation of quasi-critical brain states
title_sort diffuse neural coupling mediates complex network dynamics through the formation of quasi-critical brain states
publisher Nature Portfolio
publishDate 2020
url https://doaj.org/article/de70514aed2f449cb8f0228ea25f725c
work_keys_str_mv AT elijmuller diffuseneuralcouplingmediatescomplexnetworkdynamicsthroughtheformationofquasicriticalbrainstates
AT brandonrmunn diffuseneuralcouplingmediatescomplexnetworkdynamicsthroughtheformationofquasicriticalbrainstates
AT jamesmshine diffuseneuralcouplingmediatescomplexnetworkdynamicsthroughtheformationofquasicriticalbrainstates
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