Trigger‐Detachable Hydrogel Adhesives for Bioelectronic Interfaces

生物电子学 纳米技术 材料科学 数码产品 电子材料 柔性电子器件 神经假体 可伸缩电子设备 胶粘剂 生物传感器 生物医学工程 电气工程 图层(电子) 神经科学 工程类 生物
作者
Yuhua Xue,Jun Zhang,Xingmei Chen,Jiajun Zhang,Guangda Chen,Kuan Zhang,Jingsen Lin,Chuan Fei Guo,Ji Liu
出处
期刊:Advanced Functional Materials [Wiley]
卷期号:31 (47) 被引量:159
标识
DOI:10.1002/adfm.202106446
摘要

Abstract Recent electronics technology development has provided unprecedented opportunities for enabling implantable bioelectronics for long‐term disease monitoring and treatment. Current electronics‐tissue interfaces are characterized by weak physical interactions, suffering from potential interfacial failure or dislocation during long‐term application. On the other hand, some new technologies can be used to achieve robust electronics‐tissue interfaces; however, such technologies are limited by potential risks and the discomfort associated with postdetachment of the bioelectronics. Here, a hydrogel‐based electronics‐tissue interface based on the exploitation of dynamic interactions (such as boronate‐diol complexation) that features an interfacial toughness over 400 J m −2 is presented. Moreover, these hydrogel adhesion layers are also trigger‐detachable by dissociating the dynamic complexes (i.e., addition of glucose). These hydrogel‐based bioelectronic interfaces enable the in vivo recording of physiological signals (i.e., electromyograph, blood pressure, or pulse rates). Upon mild triggering, these bioelectronics can be easily detached without causing any damage, trauma, or discomfort to the skin, tissues, and organs. This kind of trigger‐detachable hydrogel adhesives offer general applicability in bioelectronic interfaces, exhibiting promising utility in monitoring, modulating, and treating diseases where temporary monitoring of physiologic signals, interfacial robustness, and postremoval of bioelectronics are required.
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