材料科学
光热治疗
纳米技术
伤口敷料
生物相容性
自愈
伤口愈合
生物医学工程
乙烯醇
复合材料
聚合物
外科
医学
病理
冶金
替代医学
作者
Mengyao Shan,Xin Chen,Xiaoyang Zhang,Shike Zhang,Linlin Zhang,Jinzhou Chen,Xianghong Wang,Xuying Liu
标识
DOI:10.1002/adhm.202303876
摘要
Abstract Wounds at joints are difficult to treat and tend to recover more slowly due to the frequent motions. When using traditional hydrogel dressings, they are easy to crack and undergo bacterial infection, difficult to match and monitor the irregular wounds. Integrating multiple functions within a hydrogel dressing to achieve intelligent wound monitoring and healing remains a significant challenge. In this research, a multifunctional hydrogel is developed based on polysaccharide biopolymer, poly(vinyl alcohol), and hydroxylated graphene through dynamic borate ester bonding and supramolecular interaction. The prepared hydrogel not only exhibits rapid self‐healing (within 60 s), injectable, conductive and motion monitoring properties, but also realizes in situ bacterial sensing and killing functions. It shows excellent bacterial sensitivity (within 15 min) and killing ability via the changes of electrical signals and photothermal therapy, avoiding the emergence of drug‐resistant bacteria. In vivo experiments prove that the hydrogel can promote wound healing effectively. In addition, it displays great electromechanical performance to achieve real‐time monitoring and prevent re‐tearing of the wound at human joints. The injectable pH‐responsive hydrogel with good biocompatibility demonstrates considerable potential as multifunctional bioelectronic dressing for the detection, treatment, management, and healing of infected joint wounds.
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