一种基于聚合物的512通道多层神经探针阵列。
A 512-Channel Multi-Layer Polymer-Based Neural Probe Array.
作者信息
Scholten Kee, Larson Christopher E, Xu Huijing, Song Dong, Meng Ellis
机构信息
Department of Biomedical Engineering, Viterbi School of Engineering, University of Southern California, Los Angeles, CA 90089 USA.
出版信息
J Microelectromech Syst. 2020 Oct;29(5):1054-1058. doi: 10.1109/jmems.2020.2999550. Epub 2020 Jun 11.
Abstract
We present for the first time the design, fabrication, and preliminary bench-top characterization of a high-density, polymer-based penetrating microelectrode array, developed for chronic, large-scale recording in the cortices and hippocampi of behaving rats. We present two architectures for these targeted brain regions, both featuring 512 Pt recording electrodes patterned front-and-back on micromachined eight-shank arrays of thin-film Parylene C. These devices represent an order of magnitude improvement in both number and density of recording electrodes compared with prior work on polymer-based microelectrode arrays. We present enabling advances in polymer micro-machining related to lithographic resolution and a new method for back-side patterning of electrodes. electrochemical data verifies suitable electrode function and surface properties. Finally, we describe next steps toward the implementation of these arrays in chronic, large-scale recording studies in free-moving animal models.
摘要
我们首次展示了一种高密度、基于聚合物的穿透性微电极阵列的设计、制造及初步的台式表征,该阵列是为在行为大鼠的皮质和海马体中进行长期、大规模记录而开发的。我们展示了针对这些目标脑区的两种架构,均具有512个铂记录电极,这些电极在微机械加工的薄膜聚对二甲苯C八杆阵列的前后两面进行图案化。与先前基于聚合物的微电极阵列工作相比,这些器件在记录电极的数量和密度方面均有一个数量级的提升。我们展示了在与光刻分辨率相关的聚合物微加工方面取得的使能进展以及一种电极背面图案化的新方法。电化学数据验证了电极功能和表面特性合适。最后,我们描述了在自由活动动物模型中进行长期、大规模记录研究时实施这些阵列的后续步骤
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