School of Materials Science and Engineering, Nanyang Technological University, 639798, Singapore.
Institute of Biomedical and Health Engineering, Shenzhen Institute of Advanced Technology, Chinese Academy of Sciences, Shenzhen University Town, 1068 Xueyuan Avenue, Shenzhen, 518055, P. R. China.
Adv Mater. 2017 Oct;29(40). doi: 10.1002/adma.201702800. Epub 2017 Sep 4.
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.
聚合物微电极阵列(MEA)作为新一代生物集成微电极,可将活体组织中的原始电化学信号转换为外部电路,反之亦然。到目前为止,可拉伸聚合物 MEA 的挑战在于高拉伸性和良好的电极-基底附着力之间的竞争。由于杨氏模量不匹配,拉伸性越大,电极从基底分层的可能性就越大。在这项工作中,设计了聚吡咯(PPy)电极材料,在高导电性的 PPy 电极阵列上集成了 PPy 纳米线。通过利用这种电极材料,首次制备了具有高拉伸性(≈100%)和良好电极-基底附着力(1.9 MPa)的可拉伸聚合物 MEA。此外,还实现了低杨氏模量(450 kPa)、优异的循环稳定性(10 000 次拉伸循环)和 MEA 的高导电性。作为概念验证,所制备的聚合物 MEA 成功地分别用于正常和癫痫状态下大鼠的皮层电图信号的顺应性记录。此外,这些聚合物 MEA 还成功地刺激了大鼠的坐骨神经。该策略为高度可拉伸和机械稳定的聚合物 MEA 提供了新的视角,这对于顺应性神经电极至关重要。
