自愈水凝胶
材料科学
电极
纳米技术
生物医学工程
结晶度
信号(编程语言)
胶粘剂
内应力
粘附
调制(音乐)
生物传感器
光电子学
整改
曲率
聚合物
激光器
金属
生物物理学
复合材料
作者
Mingze Zeng,Rong Li,Yue Pan,Zhihong Chen,Yusheng Zhang,Jie Ding,Chengheng Wu,Jing Sun,Huabing Yin,Dan Wei,Hongsong Fan
标识
DOI:10.1002/adfm.202527261
摘要
Abstract Flexible electrodes can conformably adhere to tissues, reducing mechanical mismatch compared with rigid metal electrodes. However, they still require complex surgical placement, which brings a high risk of tissue injury. Here, laser‐etching PEDOT: PSS (LP) hydrogels with an alternating rigid‐soft grooved structure are developed, exhibiting tunable self‐curling performance through the regulation of differential internal stress. Inspired by the laser attenuation, distinct phase separation, conformational transition, and crystallinity distribution are engineered in the out‐of‐plane direction of LP hydrogels. These modifications drive the release of differential internal stress, triggering the spontaneous 2D‐to‐3D curling transformation in wet environments. By designing laser scanning paths in the in‐plane direction, diverse complex flexible interfaces are obtained for matching variously shaped tissues. The hydration‐triggered self‐curling property enables LP hydrogels to autonomously conform to targeted tissues without adhesive layers or sutures, thereby simplifying implantation and enhancing electrode‐tissue compliance. Rat models demonstrate that the self‐curling LP hydrogels maintain high‐fidelity nerve and cardiac signal recording or/and modulation capabilities. This study offers an easy‐to‐use self‐curling flexible electrode interface for compatibility recording and modulating electrophysiological signals in diverse, complex tissues.
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