材料科学
多元统计
级联
多元分析
糖尿病
伤口愈合
生物医学工程
内科学
化学工程
医学
外科
机器学习
计算机科学
内分泌学
工程类
作者
Yuxin Huang,Ding‐Shinn Chen,Tak Man Wong,Baolin Li,Yongxin Shi
出处
期刊:APL Materials
[American Institute of Physics]
日期:2025-05-01
卷期号:13 (5)
被引量:2
摘要
The impaired immune function observed in diabetic patients significantly increases their susceptibility of diabetic wounds to bacterial infections. Conventional treatment for bacterial infections relies heavily on antibiotics; however, this approach is often accompanied by the development of bacterial resistance. In this study, a nanozyme (Q@CuMn@G) exhibiting exceptional antibacterial efficacy with the capability to circumvent drug resistance was ingeniously designed. It operates through the generation of hydroxyl radicals (•OH) via a self-cascade reaction. The glucose oxidase (GOx) encapsulated within the Cu-metal–organic framework (MOF) generates H2O2 by degrading glucose present in the wound environment, which is subsequently catalyzed by the Cu-MOF to produce •OH, thereby exerting potent antibacterial effects. Meanwhile, MnO2 loaded within Cu-MOF generates O2, ameliorating the hypoxic environment of the wound and further supporting the degradation of glucose by GOx. Quaternized chitosan is employed as a shell to envelop the nanozyme, thus preventing the rapid degradation of GOx. In vitro experiments demonstrated that Q@CuMn@G exhibits sustained release of •OH and significant bactericidal effects against Escherichia coli and Staphylococcus aureus, confirming the high antibacterial activity of the nanozyme. Moreover, in vivo experiments revealed that Q@CuMn@G effectively kills bacteria in infected diabetic wounds, modulates the immune microenvironment, and accelerates wound healing, achieving a healing ratio of 96.78%. This study employs the Q@CuMn@G nanozyme to achieve highly effective antibacterial efficacy through chemodynamic therapy, thereby offering an innovative strategy for antibiotic-free treatment of diabetic wound repair.
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