Design and Microfabrication Considerations for Reliable Flexible Intracortical Implants

H. Sohal, K. Vassilevski, A. Jackson, S. Baker, A. O'Neill
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引用次数: 12

Abstract

Current microelectrodes designed to record chronic neural activity suffer from recording instabilities due to the modulus mismatch between the electrode materials and the brain. We sought to address this by microfabricating a novel flexible neural probe. Our probe was fabricated from parylene-C with a WTi metal, using contact photolithography and reactive ion etching, with three design features to address this modulus mismatch: a sinusoidal shaft, a rounded tip and a polyimide anchoring ball. The anchor restricts movement of the electrode recording sites and the shaft accommodates the brain motion. We successfully patterned thick metal and parylene-C layers, with a reliable device release process leading to high functional yield. This novel reliably microfabricated probe can record stable neural activity for up to two years without delamination, surpassing the current state-of-the-art intracortical probes. This challenges recent concerns that have been raised over the long-term reliability of chronic implants when Parylene-C is used as an insulator, for both research and human applications. The microfabrication and design considerations provided in this manuscript may aid in the future development of flexible devices for biomedical applications.
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可靠的柔性皮质内植入物的设计和微制造考虑
目前设计用于记录慢性神经活动的微电极由于电极材料与大脑之间的模量不匹配而存在记录不稳定性。我们试图通过微制造一种新型柔性神经探针来解决这个问题。我们的探针由聚苯乙烯- c和WTi金属制成,使用接触光刻和反应离子蚀刻,具有三个设计特征来解决这种模量不匹配:正弦轴,圆形尖端和聚酰亚胺锚定球。锚限制电极记录位置的运动,轴调节大脑运动。我们成功地制作了厚金属和聚苯乙烯- c层的图案化,具有可靠的器件释放过程,导致高功能收率。这种新颖可靠的微制造探针可以记录稳定的神经活动长达两年而不会分层,超过了目前最先进的皮质内探针。当聚苯乙烯- c作为绝缘体用于研究和人类应用时,人们对慢性植入物的长期可靠性提出了质疑。本文中提供的微加工和设计考虑可能有助于生物医学应用的柔性装置的未来发展。
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