Fabrication of flat electrodes utilizing picosecond laser manufacturing technology: Preliminary study for fabrication of a novel transverse intrafascicular multichannel electrode

2014 IEEE 19th International Functional Electrical Stimulation Society Annual Conference (IFESS) Pub Date : 2014-09-01 DOI:10.1109/IFESS.2014.7036753

Matthias Mueller, F. Kohler, J. Ordonez, T. Stieglitz, M. Schuettler

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引用次数: 4

Abstract

Over the last decade we developed methods for the fabrication of laser-structured electrode arrays for neural engineering. For these electrode arrays a metal foil was structured with a 1064 nm Nd:YAG laser in the nanosecond pulse regime and placed within a silicone rubber substrate. Due to process restrictions the individual electrode sites are not in plane with the upper layer of the silicone rubber. Here, a new laser in the picosecond regime (355 nm Nd:YVO4) was used for laser-structuring. This allowed the fabrication of a novel electrode array out of a 25 μm thick sheet of MP35N metal with thinned-down and buried tracks as well as fixations for the electrode sites and contact pads. For the opening of the single electrodes two different processes, hatching and cutting, have been tested. Due to the interaction of the laser with the metal hatched electrodes had an increased surface area which was investigated with electrochemical measurements. The individual thicknesses of the layers were measured with a novel way of directly laser cutting the electrodes and measuring under a light microscope.

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利用皮秒激光制造技术制造平面电极:一种新型横向束内多通道电极制造的初步研究

在过去的十年中，我们开发了用于神经工程的激光结构电极阵列的制造方法。对于这些电极阵列，金属箔在纳秒脉冲范围内用1064 nm Nd:YAG激光器结构，并放置在硅橡胶衬底内。由于工艺限制，单个电极位点不与硅橡胶的上层在平面上。本文采用皮秒级激光(355nm Nd:YVO4)进行激光结构。这样就可以用25 μm厚的MP35N金属薄片制造出一种新型电极阵列，该电极阵列具有薄化和埋入的轨道，以及电极位置和接触垫的固定装置。对于单电极的开口，已经测试了两种不同的工艺，孵化和切割。由于激光与金属的相互作用，孵出的电极表面积增加，用电化学测量研究了这一现象。采用激光直接切割电极并在光学显微镜下测量各层厚度的新方法。

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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2014 IEEE 19th International Functional Electrical Stimulation Society Annual Conference (IFESS)

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