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Avalanches in Self-Organized Critical Neural Networks: A Minimal Model for the Neural SOC Universality Class

The brain keeps its overall dynamics in a corridor of intermediate activity and it has been a long standing question what possible mechanism could achieve this task. Mechanisms from the field of statistical physics have long been suggesting that this homeostasis of brain activity could occur even wi...

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Autores principales: Rybarsch, Matthias, Bornholdt, Stefan
Formato: Online Artículo Texto
Lenguaje:English
Publicado: Public Library of Science 2014
Materias:
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC3990531/
https://www.ncbi.nlm.nih.gov/pubmed/24743324
http://dx.doi.org/10.1371/journal.pone.0093090
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author Rybarsch, Matthias
Bornholdt, Stefan
author_facet Rybarsch, Matthias
Bornholdt, Stefan
author_sort Rybarsch, Matthias
collection PubMed
description The brain keeps its overall dynamics in a corridor of intermediate activity and it has been a long standing question what possible mechanism could achieve this task. Mechanisms from the field of statistical physics have long been suggesting that this homeostasis of brain activity could occur even without a central regulator, via self-organization on the level of neurons and their interactions, alone. Such physical mechanisms from the class of self-organized criticality exhibit characteristic dynamical signatures, similar to seismic activity related to earthquakes. Measurements of cortex rest activity showed first signs of dynamical signatures potentially pointing to self-organized critical dynamics in the brain. Indeed, recent more accurate measurements allowed for a detailed comparison with scaling theory of non-equilibrium critical phenomena, proving the existence of criticality in cortex dynamics. We here compare this new evaluation of cortex activity data to the predictions of the earliest physics spin model of self-organized critical neural networks. We find that the model matches with the recent experimental data and its interpretation in terms of dynamical signatures for criticality in the brain. The combination of signatures for criticality, power law distributions of avalanche sizes and durations, as well as a specific scaling relationship between anomalous exponents, defines a universality class characteristic of the particular critical phenomenon observed in the neural experiments. Thus the model is a candidate for a minimal model of a self-organized critical adaptive network for the universality class of neural criticality. As a prototype model, it provides the background for models that may include more biological details, yet share the same universality class characteristic of the homeostasis of activity in the brain.
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spelling pubmed-39905312014-04-21 Avalanches in Self-Organized Critical Neural Networks: A Minimal Model for the Neural SOC Universality Class Rybarsch, Matthias Bornholdt, Stefan PLoS One Research Article The brain keeps its overall dynamics in a corridor of intermediate activity and it has been a long standing question what possible mechanism could achieve this task. Mechanisms from the field of statistical physics have long been suggesting that this homeostasis of brain activity could occur even without a central regulator, via self-organization on the level of neurons and their interactions, alone. Such physical mechanisms from the class of self-organized criticality exhibit characteristic dynamical signatures, similar to seismic activity related to earthquakes. Measurements of cortex rest activity showed first signs of dynamical signatures potentially pointing to self-organized critical dynamics in the brain. Indeed, recent more accurate measurements allowed for a detailed comparison with scaling theory of non-equilibrium critical phenomena, proving the existence of criticality in cortex dynamics. We here compare this new evaluation of cortex activity data to the predictions of the earliest physics spin model of self-organized critical neural networks. We find that the model matches with the recent experimental data and its interpretation in terms of dynamical signatures for criticality in the brain. The combination of signatures for criticality, power law distributions of avalanche sizes and durations, as well as a specific scaling relationship between anomalous exponents, defines a universality class characteristic of the particular critical phenomenon observed in the neural experiments. Thus the model is a candidate for a minimal model of a self-organized critical adaptive network for the universality class of neural criticality. As a prototype model, it provides the background for models that may include more biological details, yet share the same universality class characteristic of the homeostasis of activity in the brain. Public Library of Science 2014-04-17 /pmc/articles/PMC3990531/ /pubmed/24743324 http://dx.doi.org/10.1371/journal.pone.0093090 Text en © 2014 Rybarsch, Bornholdt http://creativecommons.org/licenses/by/4.0/ This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are properly credited.
spellingShingle Research Article
Rybarsch, Matthias
Bornholdt, Stefan
Avalanches in Self-Organized Critical Neural Networks: A Minimal Model for the Neural SOC Universality Class
title Avalanches in Self-Organized Critical Neural Networks: A Minimal Model for the Neural SOC Universality Class
title_full Avalanches in Self-Organized Critical Neural Networks: A Minimal Model for the Neural SOC Universality Class
title_fullStr Avalanches in Self-Organized Critical Neural Networks: A Minimal Model for the Neural SOC Universality Class
title_full_unstemmed Avalanches in Self-Organized Critical Neural Networks: A Minimal Model for the Neural SOC Universality Class
title_short Avalanches in Self-Organized Critical Neural Networks: A Minimal Model for the Neural SOC Universality Class
title_sort avalanches in self-organized critical neural networks: a minimal model for the neural soc universality class
topic Research Article
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC3990531/
https://www.ncbi.nlm.nih.gov/pubmed/24743324
http://dx.doi.org/10.1371/journal.pone.0093090
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