神经元竞争模型中的频率控制机制。

Mechanisms for Frequency Control in Neuronal Competition Models.

作者信息

Curtu Rodica, Shpiro Asya, Rubin Nava, Rinzel John

机构信息

Department of Mathematics, The University of Iowa, 14 MacLean Hall, Iowa City, IA 52242, and Transilvania University of Brasov, Romania (

出版信息

SIAM J Appl Dyn Syst. 2008;7(2):609-649. doi: 10.1137/070705842.

DOI:10.1137/070705842

PMID:20953287

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2954747/

Abstract

We investigate analytically a firing rate model for a two-population network based on mutual inhibition and slow negative feedback in the form of spike frequency adaptation. Both neuronal populations receive external constant input whose strength determines the system's dynamical state-a steady state of identical activity levels or periodic oscillations or a winner-take-all state of bistability. We prove that oscillations appear in the system through supercritical Hopf bifurcations and that they are antiphase. The period of oscillations depends on the input strength in a nonmonotonic fashion, and we show that the increasing branch of the period versus input curve corresponds to a release mechanism and the decreasing branch to an escape mechanism. In the limiting case of infinitely slow feedback we characterize the conditions for release, escape, and occurrence of the winner-take-all behavior. Some extensions of the model are also discussed.

摘要

我们基于相互抑制和以脉冲频率适应形式存在的缓慢负反馈，对双种群网络的发放率模型进行了分析研究。两个神经元种群都接收外部恒定输入，其强度决定了系统的动态状态——相同活动水平的稳态、周期性振荡或双稳性的胜者全得状态。我们证明，振荡通过超临界霍普夫分岔出现在系统中，并且它们是反相的。振荡周期以非单调方式依赖于输入强度，并且我们表明，周期与输入曲线的上升分支对应于一种释放机制，下降分支对应于一种逃逸机制。在无限缓慢反馈的极限情况下，我们刻画了释放、逃逸以及胜者全得行为出现的条件。还讨论了该模型的一些扩展。

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神经元竞争模型中的频率控制机制。

Mechanisms for Frequency Control in Neuronal Competition Models.

作者信息

Curtu Rodica, Shpiro Asya, Rubin Nava, Rinzel John

机构信息

Department of Mathematics, The University of Iowa, 14 MacLean Hall, Iowa City, IA 52242, and Transilvania University of Brasov, Romania (

出版信息

SIAM J Appl Dyn Syst. 2008;7(2):609-649. doi: 10.1137/070705842.

DOI:10.1137/070705842

PMID:20953287

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2954747/

Abstract

摘要

神经元竞争模型中的频率控制机制。

Mechanisms for Frequency Control in Neuronal Competition Models.

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机构信息

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神经元竞争模型中的频率控制机制。

Mechanisms for Frequency Control in Neuronal Competition Models.

作者信息

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出版信息