Perforated silicon dices with integrated nerve guidance channels for interfacing peripheral nerves

Proceedings IEEE Micro Electro Mechanical Systems. 1995 Pub Date : 1995-01-29 DOI:10.1109/MEMSYS.1995.472594

J. Meyer, H. Beutel, E. Valderrama, E. Cabruja, P. Aebischer, G. Soldani, P. Dario

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引用次数: 15

Abstract

It has been shown previously that peripheral nerve axons are regenerating through microvias in silicon devices. A major challenge is the design of a biocompatible integrated neural connector allowing simultaneous, multi-site recordings or stimulation of axons in nerve bundles and to establish a reliable mechanical and electrical connection. This paper describes on-going research in the framework of an European project aimed to develop an implantable neural microsystem comprising various designs of perforated dices, multiple electrodes with on-chip integrated preprocessing circuitry, functional guidance channels for support and fixation of regenerating axons, and interconnection assemblies for bi-directional nervous signal transmission. Special emphasis is given on a light-weight design of the device and on the biocompatible integration and packaging of the chip. In this paper, we report about the microfabrication of the perforated dices, their incorporation into biocompatible guidance channels, and about in vitro and in vivo biocompatibility testing of materials applied.

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带集成神经引导通道的穿孔硅器件，用于连接周围神经

以前的研究表明，周围神经轴突可以通过硅器件中的微孔进行再生。一个主要的挑战是设计一种生物相容性的集成神经连接器，允许同时，多位点记录或刺激神经束中的轴突，并建立可靠的机械和电连接。本文描述了一个欧洲项目框架内正在进行的研究，该项目旨在开发一种可植入的神经微系统，该系统包括各种设计的穿孔器件、带有片上集成预处理电路的多个电极、用于支持和固定再生轴突的功能引导通道，以及用于双向神经信号传输的互连组件。特别强调器件的轻量化设计以及芯片的生物相容性集成和封装。在本文中，我们报道了穿孔器件的微加工，它们被纳入生物相容性引导通道，以及所应用材料的体外和体内生物相容性测试。

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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Proceedings IEEE Micro Electro Mechanical Systems. 1995

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