Flexible Regeneration-type Nerve Electrode with Integrated Microfluidic Channels

T. Suzuki, N. Kotake, K. Mabuchi, S. Takeuchi
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引用次数: 9

Abstract

The development of a neural interface that will allow signals from the human nervous system to control external equipment is extremely important for the next generation of prosthetic systems. A novel multichannel regeneration-type nerve electrode designed to record from and stimulate peripheral nerves has been developed to allow the control of artificial hands and to generate artificial sensations. In this study a novel flexible regeneration microelectrode based on the nerve regeneration principle was designed and fabricated using MEMS technologies. The electrode, which was fabricated on a 20-mum-thick parylene C substrate, has multiple fluidic channels. Each fluidic channel was 100 mum widetimes40 mum hightimes1500 mum long and featured multiple electrodes inside them as recording and stimulating sites. They also served as guidance channels for the regenerating axons. The authors are currently attempting to evaluate the probes using the sciatic nerve of rats
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集成微流控通道的柔性再生型神经电极
神经接口的发展将允许来自人类神经系统的信号来控制外部设备,这对下一代假肢系统非常重要。一种新的多通道再生型神经电极被设计用于记录和刺激周围神经,以允许控制假手并产生人工感觉。本研究基于神经再生原理,利用MEMS技术设计并制作了一种新型柔性再生微电极。该电极被制作在20毫米厚的聚对二甲苯衬底上,具有多个流体通道。每个流体通道的宽度为100 μ m,高为40 μ m,长为1500 μ m,其中有多个电极作为记录和刺激位点。它们还作为再生轴突的引导通道。作者目前正试图用大鼠坐骨神经来评估探针
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