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Bioclay Enzyme with Bimetal Synergistic Sterilization and Infectious Wound Regeneration

Ying Chen, Shiqi Wei, Rui Li, Weimin Xie, Huaming Yang

2024Nano Letters12 citationsDOI

Abstract

Bacteria invasion is the main factor hindering the wound-healing process. However, current antibacterial therapies inevitably face complex challenges, such as the abuse of antibiotics or severe inflammation during treatment. Here, a drug-free bioclay enzyme (Bio-Clayzyme) consisting of Fe 2+ -tannic acid (TA) network-coated kaolinite nanoclay and glucose oxidase (GOx) was reported to destroy harmful bacteria via bimetal antibacterial therapy. At the wound site, Bio-Clayzyme was found to enhance the generation of toxic hydroxyl radicals for sterilization via cascade catalysis of GOx and Fe 2+ -mediated peroxidase mimetic activity. Specifically, the acidic characteristics of the infection microenvironment accelerated the release of Al 3+ from kaolinite, which further led to bacterial membrane damage and amplified the antibacterial toxicity of Fe 2+ . Besides, Bio-Clayzyme also performed hemostasis and anti-inflammatory functions inherited from Kaol and TA. By the combination of hemostasis and anti-inflammatory and bimetal synergistic sterilization, Bio-Clayzyme achieves efficient healing of infected wounds, providing a revolutionary approach for infectious wound regeneration.

Topics & Concepts

Sterilization (economics)BimetalRegeneration (biology)EnzymeChemistryCell biologyBiologyBiochemistryBusinessFinancePhysical chemistryExchange rateForeign exchange marketEnzyme Production and CharacterizationBacterial biofilms and quorum sensingCancer Research and Treatments
Bioclay Enzyme with Bimetal Synergistic Sterilization and Infectious Wound Regeneration | Litcius