存在传导延迟时神经放电和同步的精细结构。
Fine structure of neural spiking and synchronization in the presence of conduction delays.
作者信息
Ermentrout G B, Kopell N
机构信息
Department of Mathematics, University of Pittsburgh, Pittsburgh, PA 15260, USA.
出版信息
Proc Natl Acad Sci U S A. 1998 Feb 3;95(3):1259-64. doi: 10.1073/pnas.95.3.1259.
Abstract
Hippocampal networks of excitatory and inhibitory neurons that produce gamma-frequency rhythms display behavior in which the inhibitory cells produce spike doublets when there is strong stimulation at separated sites. It has been suggested that the doublets play a key role in the ability to synchronize over a distance. Here we analyze the mechanisms by which timing in the spike doublet can affect the synchronization process. The analysis describes two independent effects: one comes from the timing of excitation from separated local circuits to an inhibitory cell, and the other comes from the timing of inhibition from separated local circuits to an excitatory cell. We show that a network with both of these effects has different synchronization properties than a network with either excitatory or inhibitory type of coupling alone, and we give a rationale for the shorter space scales associated with inhibitory interactions.
摘要
产生γ频率节律的兴奋性和抑制性神经元的海马网络表现出这样一种行为:当在不同部位有强烈刺激时,抑制性细胞会产生双峰脉冲。有人提出,双峰脉冲在远距离同步能力中起关键作用。在这里,我们分析了双峰脉冲的时间安排能够影响同步过程的机制。该分析描述了两种独立的效应:一种来自不同局部回路对抑制性细胞的兴奋时间,另一种来自不同局部回路对兴奋性细胞的抑制时间。我们表明,具有这两种效应的网络与仅具有兴奋性或抑制性耦合类型的网络具有不同的同步特性,并且我们给出了与抑制性相互作用相关的较短空间尺度的理论依据。
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