有髓神经纤维中冲动起始和跳跃传导的计算。
Computation of impulse initiation and saltatory conduction in a myelinated nerve fiber.
作者信息
FITZHUGH R
出版信息
Biophys J. 1962 Jan;2(1):11-21. doi: 10.1016/s0006-3495(62)86837-4.
Abstract
A mathematical model of the electrical properties of a myelinated nerve fiber is given, consisting of the Hodgkin-Huxley ordinary differential equations to represent the membrane at the nodes of Ranvier, and a partial differential cable equation to represent the internodes. Digital computer solutions of these equations show an impulse arising at a stimulating electrode and being propagated away, approaching a constant velocity. Action potential curves plotted against distance show discontinuities in slope, proportional to the nodal action currents, at the nodes. Action potential curves plotted against time, at the nodes and in the internodes, show a marked difference in steepness of the rising phase, but little difference in peak height. These results and computed action current curves agree fairly accurately with published experimental data from frog and toad fibers.
摘要
给出了一个有髓神经纤维电特性的数学模型,它由代表郎飞结处膜的霍奇金 - 赫胥黎常微分方程和代表结间段的偏微分电缆方程组成。这些方程的数字计算机解表明,一个冲动在刺激电极处产生并传播开去,接近一个恒定速度。相对于距离绘制的动作电位曲线在结处显示出斜率的不连续性,这与结处的动作电流成比例。相对于时间在结处和结间段绘制的动作电位曲线显示,上升相的陡度有显著差异,但峰值高度差异不大。这些结果和计算出的动作电流曲线与已发表的来自青蛙和蟾蜍纤维的实验数据相当准确地相符。
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