由冗余抑制性神经回路进行的时间控制。

Timing control by redundant inhibitory neuronal circuits.

作者信息

Tristan I, Rulkov N F, Huerta R, Rabinovich M

机构信息

BioCircuits Institute, University of California, San Diego, La Jolla, California 92093-0402, USA.

出版信息

Chaos. 2014 Mar;24(1):013124. doi: 10.1063/1.4866580.

DOI:10.1063/1.4866580

PMID:24697386

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3977790/

Abstract

Rhythms and timing control of sequential activity in the brain is fundamental to cognition and behavior. Although experimental and theoretical studies support the understanding that neuronal circuits are intrinsically capable of generating different time intervals, the dynamical origin of the phenomenon of functionally dependent timing control is still unclear. Here, we consider a new mechanism that is related to the multi-neuronal cooperative dynamics in inhibitory brain motifs consisting of a few clusters. It is shown that redundancy and diversity of neurons within each cluster enhances the sensitivity of the timing control with the level of neuronal excitation of the whole network. The generality of the mechanism is shown to work on two different neuronal models: a conductance-based model and a map-based model.

摘要

大脑中序列活动的节律和时间控制是认知和行为的基础。尽管实验和理论研究支持神经元回路本质上能够产生不同时间间隔的观点，但功能依赖的时间控制现象的动力学起源仍不清楚。在此，我们考虑一种与由几个簇组成的抑制性脑基序中的多神经元协同动力学相关的新机制。结果表明，每个簇内神经元的冗余性和多样性提高了时间控制的灵敏度，且与整个网络的神经元兴奋水平有关。该机制的普遍性在两种不同的神经元模型上得到了验证：基于电导的模型和基于映射的模型。

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