生物电子学
离子电导率
材料科学
离子键合
生物高聚物
离子液体
自愈水凝胶
离子
聚合物
电导率
导电聚合物
纳米技术
侧链
明胶
化学工程
弹性模量
电活性聚合物
磺酸盐
高分子化学
动态力学分析
电化学
导电体
作者
Baojin Chen,Renjie Yu,Jiaqi Wang,Yunxiang Feng,Yujie Zhang,Yanchao Mao,Chongxin Shan,Xudong Wang
标识
DOI:10.1002/adfm.202527495
摘要
Abstract Ionic conduction is a crucial property for electronic biomaterials used in bioelectronics, as the biological systems rely on ions to conduct electricity. Currently, biomaterials‐based functional hydrogels emerged as a promising building block for bioelectronics owing to their natural biocompatibility. However, two critical challenges faced by this type of hydrogel are their low ionic conductivity and unmatched mechanical modulus with soft tissues, which are inherently related to their complex biopolymer chains. Here, by mimicking the ion‐accelerating effect of ion channel receptors in neuron membranes, a biomaterials‐based ionic hydrogel (BIH) is developed, which offers a high ionic conductivity of 7.04 S m −1 , outperforming conventional chitosan, cellulose, agarose, starch, and gelatin based ionic hydrogels. The sulfonate groups and quaternary ammonium groups on zwitterionic side chains of poly (sulfobetaine methacrylate) (pSBMA) construct artificial cation and anion channels, respectively. The highly branched polymer structure of pSBMA reduces chain entanglement and lowers the Young's modulus of BIH to 7.2 kPa. Compared with traditional biomaterials‐based hydrogels, the BIH simultaneously possesses excellent ionic conductivity and tissue‐matching softness. Such BIH offers substantially higher quality of electrocardiogram and electromyogram signals than those of commercial electrodes.
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