Novel Neural Interface for Vision Prosthesis Electrodes: Improving Electrical and Mechanical Properties through Layering

2007 3rd International IEEE/EMBS Conference on Neural Engineering Pub Date : 2007-05-02 DOI:10.1109/CNE.2007.369621

R. Green, L. Poole-Warren, N. Lovell

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引用次数: 11

Abstract

The rationale for this research is to address the problem of long-term function of neural interfaces. The approach followed is surface modification of traditional electrode materials using electrically conducting polymers and biological factors with the aim of establishing a functional neural interface between stimulating electrode and neural tissue. Polypyrrole films can be relatively flexible but have insufficient electrochemical stability to be used in long-term neuroprosthetic implants. Polyethylene dioxythiophene films have good electrochemical stability but are very difficult to handle and are subject to failure by brittle fracture. The specific aim of this study was to evaluate layering of different conductive polymers for optimization of film properties. Layering of the films was shown to produce composite materials with properties superior to those of the individual components. Conductivity of the layered film was between that of each film alone and mechanical stability was similar to the more flexible PPy films. Neurite outgrowth was improved on the layered film. These layered films show promise as conductive coatings for electrodes.

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视觉假体电极的新型神经接口:通过分层改善电学和力学性能

本研究的基本原理是解决神经接口的长期功能问题。接下来的方法是利用导电聚合物和生物因子对传统电极材料进行表面改性，目的是在刺激电极和神经组织之间建立功能性神经界面。聚吡咯薄膜相对灵活，但电化学稳定性不足，无法用于长期的神经假体植入。聚乙烯二氧噻吩薄膜具有良好的电化学稳定性，但处理难度大，易发生脆性断裂。本研究的具体目的是评估不同导电聚合物的分层对薄膜性能的优化。薄膜的分层被证明产生的复合材料的性能优于那些单独的组件。层状薄膜的电导率介于每层薄膜之间，机械稳定性与更灵活的PPy薄膜相似。层状膜上神经突的生长得到改善。这些层状薄膜有望成为电极的导电涂层。

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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2007 3rd International IEEE/EMBS Conference on Neural Engineering

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