Integrated use of volume conduction and neural models to simulate the response to cochlear implants

Simulation Practice and Theory Pub Date : 2000-04-15 DOI:10.1016/S0928-4869(00)00008-2

Johan H.M. Frijns, Jeroen J. Briaire, Ruurd Schoonhoven

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引用次数: 34

Abstract

Cochlear implants are electronic devices intended to restore the sense of hearing in deaf people by direct electrical stimulation of the auditory nerve fibres that are still present in the deaf inner ear. Unfortunately, the clinical outcome is not very predictable. In this study a computational model is presented that can predict the neural response to an arbitrary cochlear implant. It first computes the potential distribution set up in a three-dimensional, spiralling volume conduction model of the auditory part of the inner ear (cochlea) and then applies a nerve fibre model to construct input/output curves and excitation profiles of the auditory nerve. As an initial validation the results are compared with experimentally induced electrically evoked auditory brainstem responses. In the light of the favourable results, we conclude that the model can serve as a tool for designing future cochlear implants. In combination with electrophysiological measurements in the individual patient it is applicable as an implant fitting tool.

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综合运用体积传导和神经模型模拟人工耳蜗植入后的反应

人工耳蜗是一种电子设备，旨在通过直接电刺激耳聋内耳中的听神经纤维来恢复耳聋人的听觉。不幸的是，临床结果很难预测。在这项研究中，提出了一个计算模型，可以预测神经反应的任意人工耳蜗植入。首先计算建立在内耳(耳蜗)听觉部分三维螺旋体积传导模型中的电位分布，然后应用神经纤维模型构建听神经的输入/输出曲线和兴奋剖面。作为初步验证的结果与实验诱导的电诱发听觉脑干反应进行了比较。鉴于良好的结果，我们得出结论，该模型可以作为设计未来人工耳蜗的工具。结合个体患者的电生理测量，它适用于植入物安装工具。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Simulation Practice and Theory

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