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Autori principali: Moutuou, Elkaïoum M., Benali, Habib
Natura: Preprint
Pubblicazione: 2024
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Accesso online:https://arxiv.org/abs/2408.14221
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author Moutuou, Elkaïoum M.
Benali, Habib
author_facet Moutuou, Elkaïoum M.
Benali, Habib
contents A fundamental idea in neuroscience is that cognitive functions -- such as perception, learning, memory, and locomotion -- are shaped and constrained by the brain's structural organization. Despite significant progress in mapping and analyzing structural connectomes, the principles linking the brain's physical architecture to its functional capabilities remain elusive. Here, we introduce an algebraic quantum model to bridge this theoretical gap, offering new insights into the relationship between the connectome and emergent brain functions, while connecting structural data to functional predictions. Using the well-mapped C. elegans anatomical and extrasynaptic connectomes, we demonstrate that brain functions, defined as functional networks of a neural system, emerge as thermal equilibrium states of an algebraic quantum system derived from the graph algebra of the underlying directed multigraph. Specifically, these equilibrium states, characterized by the Kubo-Martin-Schwinger (KMS) formalism, reveal how individual neurons contribute to functional network formation. Our model illuminates the structure-function relationship in neural circuits through two key features: (1) a functional connectome that delineates topologically driven neuronal interactions and (2) an Integration Capacity (IC) index that quantifies how effectively neurons coordinate and modulate diverse information flows. Together, these features provide a statistical and mechanistic account of information flow and reveal how the network topology of the connectome predicts cognition and complex behaviors.
format Preprint
id arxiv_https___arxiv_org_abs_2408_14221
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Brain functions emerge as thermal equilibrium states of the connectome
Moutuou, Elkaïoum M.
Benali, Habib
Neurons and Cognition
Disordered Systems and Neural Networks
Statistical Mechanics
Operator Algebras
Quantum Physics
47L90, 05C82, 81R12, 82B10
A fundamental idea in neuroscience is that cognitive functions -- such as perception, learning, memory, and locomotion -- are shaped and constrained by the brain's structural organization. Despite significant progress in mapping and analyzing structural connectomes, the principles linking the brain's physical architecture to its functional capabilities remain elusive. Here, we introduce an algebraic quantum model to bridge this theoretical gap, offering new insights into the relationship between the connectome and emergent brain functions, while connecting structural data to functional predictions. Using the well-mapped C. elegans anatomical and extrasynaptic connectomes, we demonstrate that brain functions, defined as functional networks of a neural system, emerge as thermal equilibrium states of an algebraic quantum system derived from the graph algebra of the underlying directed multigraph. Specifically, these equilibrium states, characterized by the Kubo-Martin-Schwinger (KMS) formalism, reveal how individual neurons contribute to functional network formation. Our model illuminates the structure-function relationship in neural circuits through two key features: (1) a functional connectome that delineates topologically driven neuronal interactions and (2) an Integration Capacity (IC) index that quantifies how effectively neurons coordinate and modulate diverse information flows. Together, these features provide a statistical and mechanistic account of information flow and reveal how the network topology of the connectome predicts cognition and complex behaviors.
title Brain functions emerge as thermal equilibrium states of the connectome
topic Neurons and Cognition
Disordered Systems and Neural Networks
Statistical Mechanics
Operator Algebras
Quantum Physics
47L90, 05C82, 81R12, 82B10
url https://arxiv.org/abs/2408.14221