材料科学
微电极
电极
纳米技术
多电极阵列
电生理学
体内
接口
可伸缩电子设备
神经科学
数码产品
电气工程
计算机科学
计算机硬件
物理化学
生物技术
工程类
化学
生物
作者
Dianpeng Qi,Zhiyuan Liu,Yan Liu,Ying Jiang,Wan Ru Leow,Mayank Pal,Shaowu Pan,Hui Yang,Yu Wang,Xiaoqian Zhang,Jiancan Yu,Bin Li,Zhe Yu,Wei Wang,Xiaodong Chen
标识
DOI:10.1002/adma.201702800
摘要
Abstract Polymeric microelectrode arrays (MEAs) are emerging as a new generation of biointegrated microelectrodes to transduce original electrochemical signals in living tissues to external electrical circuits, and vice versa. So far, the challenge of stretchable polymeric MEAs lies in the competition between high stretchability and good electrode–substrate adhesion. The larger the stretchability, the easier the delamination of electrodes from the substrate due to the mismatch in their Young's modulus. In this work, polypyrrole (PPy) electrode materials are designed, with PPy nanowires integrated on the high conductive PPy electrode arrays. By utilizing this electrode material, for the first time, stretchable polymeric MEAs are fabricated with both high stretchability (≈100%) and good electrode–substrate adhesion (1.9 MPa). In addition, low Young's modulus (450 kPa), excellent recycling stability (10 000 cycles of stretch), and high conductivity of the MEAs are also achieved. As a proof of concept, the as‐prepared polymeric MEAs are successfully used for conformally recording the electrocorticograph signals from rats in normal and epileptic states, respectively. Further, these polymeric MEAs are also successful in stimulating the ischiadic nerve of the rat. This strategy provides a new perspective to the highly stretchable and mechanically stable polymeric MEAs, which are vital for compliant neural electrodes.
科研通智能强力驱动
Strongly Powered by AbleSci AI