Artículo
Similar local neuronal dynamics may lead to different collective behavior
Sánchez Diaz, Margarita Maria; Aguilar Trejo, Eyisto José
; Mártin, Daniel Alejandro
; Cannas, Sergio Alejandro
; Grigera, Tomas Sebastian
; Chialvo, Dante Renato
Fecha de publicación:
29/12/2021
Editorial:
American Physical Society
Revista:
Physical Review E: Statistical, Nonlinear and Soft Matter Physics
ISSN:
2470-0045
e-ISSN:
2470-0053
Idioma:
Inglés
Tipo de recurso:
Artículo publicado
Clasificación temática:
Resumen
This report is concerned with the relevance of the microscopic rules that implement individual neuronal activation, in determining the collective dynamics, under variations of the network topology. To fix ideas we study the dynamics of two cellular automaton models, commonly used, rather in-distinctively, as the building blocks of large-scale neuronal networks. One model, due to Greenberg and Hastings (GH), can be described by evolution equations mimicking an integrate-and-fire process, while the other model, due to Kinouchi and Copelli (KC), represents an abstract branching process, where a single active neuron activates a given number of postsynaptic neurons according to a prescribed "activity"branching ratio. Despite the apparent similarity between the local neuronal dynamics of the two models, it is shown that they exhibit very different collective dynamics as a function of the network topology. The GH model shows qualitatively different dynamical regimes as the network topology is varied, including transients to a ground (inactive) state, continuous and discontinuous dynamical phase transitions. In contrast, the KC model only exhibits a continuous phase transition, independently of the network topology. These results highlight the importance of paying attention to the microscopic rules chosen to model the interneuronal interactions in large-scale numerical simulations, in particular when the network topology is far from a mean-field description. One such case is the extensive work being done in the context of the Human Connectome, where a wide variety of types of models are being used to understand the brain collective dynamics.
Palabras clave:
Neuronal dynamics
,
Complex networks
,
Collective behavior
,
Network topology
Archivos asociados
Licencia
Identificadores
Colecciones
Articulos(SEDE CENTRAL)
Articulos de SEDE CENTRAL
Articulos de SEDE CENTRAL
Citación
Sánchez Diaz, Margarita Maria; Aguilar Trejo, Eyisto José; Mártin, Daniel Alejandro; Cannas, Sergio Alejandro; Grigera, Tomas Sebastian; et al.; Similar local neuronal dynamics may lead to different collective behavior; American Physical Society; Physical Review E: Statistical, Nonlinear and Soft Matter Physics; 104; 6; 29-12-2021; 1-10
Compartir
Altmétricas