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Microenvironment-triggered cascade metal-polyphenolic nanozyme for ROS/NO synergistic hyperglycemic wound healing

Shuo Shi, Yaru Han, Jianxing Feng, Jingru Shi, Xiaoling Liu, Bangfeng Fu, Jianlong Wang, Wentao Zhang, Jinyou Duan

2024Redox Biology23 citationsDOIOpen Access PDF

Abstract

Wound infection of hyperglycemic patient often has extended healing period and increased probability due to the high glucose level. However, achieving precise and safe therapy of the hyperglycemic wound with specific wound microenvironment (WME) remains a major challenge. Herein, a WME-activated smart L-Arg/GOx@TA-Fe (LGTF) nanozymatic system composed of generally recognized as safe (GRAS) compound is engineered. The nanozymatic system combining metal-polyphenol nanozyme (tannic acid-Fe3+, TA-Fe) and natural enzyme (glucose oxidase, GOx) can consume the high-concentration glucose, generating reactive oxygen species (ROS) and nitric oxide (NO) in situ to synergistically disinfect hyperglycemia wound. In addition, glucose consumption and gluconic acid generation can lower glucose level to promote wound healing and reduce the pH of WME to enhance the catalytic activities of the LGTF nanozymatic system. Thereby, low-dose LGTF can perform remarkable synergistic disinfection and healing effect towards hyperglycemic wound. The superior biosafety, high catalytic antibacterial and beneficial WME regulating capacity demonstrate this benign GRAS nanozymatic system is a promising therapeutic agent for hyperglycemic wound.

Topics & Concepts

Glucose oxidaseWound healingGluconic acidChemistryReactive oxygen speciesPolyphenolNitric oxidePharmacologyBiochemistryAntioxidantFood scienceMedicineEnzymeSurgeryOrganic chemistryAdvanced Nanomaterials in CatalysisNanoplatforms for cancer theranosticsGraphene and Nanomaterials Applications
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