具有新型适应成分的听神经纤维生物物理模型。

Biophysical model of an auditory nerve fiber with a novel adaptation component.

作者信息

Woo Jihwan, Miller Charles A, Abbas Paul J

机构信息

Department of Otolaryngology, University of Iowa Hospitals and Clinics, Iowa City, IA 52242, USA.

出版信息

IEEE Trans Biomed Eng. 2009 Sep;56(9):2177-80. doi: 10.1109/TBME.2009.2023978. Epub 2009 Jun 2.

DOI:10.1109/TBME.2009.2023978

PMID:19497810

Abstract

Recent data from feline auditory nerve fibers (ANFs) indicate that electrically stimulated fibers can undergo large degrees of rate adaptation to pulse-train stimuli using pulse rates within the range used by clinical auditory prostheses. However, the application of Hodgkin-Huxley-type models does not produce such adaptation, which occurs over time periods on the order of 100 ms. We describe our development of a computational ANF axon model that incorporates a time-changing external potassium concentration ( K(+)) that depends on potassium currents produced by active nodal channel activity. This relatively simple and computationally tractable approach produces poststimulus time histograms that are similar to experimental (cat) data. Furthermore, this mechanism could be easily incorporated into other models to produce much more realistic estimates of the neural coding produced by repeated electric stimulation.

摘要

来自猫听觉神经纤维（ANFs）的最新数据表明，电刺激的纤维能够对临床听觉假体所使用的脉冲率范围内的脉冲序列刺激产生高度的频率适应性。然而，应用霍奇金-赫胥黎型模型并不会产生这种适应性，这种适应性会在大约100毫秒的时间内发生。我们描述了一种计算性ANF轴突模型的开发，该模型纳入了随时间变化的外部钾离子浓度（K⁺），它取决于活跃的节点通道活动产生的钾电流。这种相对简单且易于计算的方法产生的刺激后时间直方图与实验（猫）数据相似。此外，这种机制可以很容易地整合到其他模型中，以对重复电刺激产生的神经编码进行更现实的估计。

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具有新型适应成分的听神经纤维生物物理模型。

Biophysical model of an auditory nerve fiber with a novel adaptation component.

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