Selenide-Driven Reactive Oxygen Species Activation and Fe(II) Regeneration for Enhanced Nanocatalytic Antibacterial Therapeutics.

IF 10 2区医学 Q1 ENGINEERING, BIOMEDICAL

Advanced Healthcare Materials Pub Date : 2025-05-09 DOI:10.1002/adhm.202501021

Chenyao Wu, Yanling You, Dehong Yu, Ya-Xuan Zhu, Han Lin, Jianlin Shi

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Abstract

Fenton-based nanocatalytic therapy has attracted widespread attention for its high efficiency and safety. Nevertheless, Fe²⁺ regeneration, as the rate-limiting step of Fenton reaction, hinders the ROS-induced oxidative killing. Herein, a Fe²⁺ auto-regeneration strategy is exemplified by 2D FeSe₂ nanosheets to break the rate limitation of Fenton reaction and subsequently enhances the antibacterial oxidative damage via dual ROS generation pathways. To be specific, the Se species accelerate the Fe³⁺ reduction to maintain high ·OH productivity of Fe²⁺-mediated Fenton reaction, which is accompanied by the production of H₂Se in the presence of H⁺. The H₂Se further converts O₂ into O₂ ^·- and synergistically breaks the oxidative threshold of bacteria, leading to irreversible bacterial death with glutathione depletion, lipid peroxidation, and membrane destruction. In summary, the FeSe₂-mediated Fe²⁺ auto-regeneration and ROS self-production pathways largely elevate its oxidative killing capability, providing a potential ROS enhancement strategy for broad-spectrum nonantibiotic bacterial disinfection.

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硒驱动的活性氧活化和铁（II）再生用于增强纳米催化抗菌治疗。

fenton基纳米催化治疗因其高效、安全等优点而受到广泛关注。然而，Fe2+再生作为Fenton反应的限速步骤，阻碍了ros诱导的氧化杀伤。本文以二维FeSe2纳米片为例，采用Fe2+自动再生策略，打破Fenton反应的速率限制，随后通过双ROS生成途径增强抗菌氧化损伤。具体来说，硒加速了Fe3+的还原，以保持Fe2+介导的Fenton反应的高·OH生产率，同时在H+存在的情况下产生H2Se。H2Se进一步将O2转化为O2·-，并协同打破细菌的氧化阈值，导致不可逆的细菌死亡，伴有谷胱甘肽耗竭、脂质过氧化和膜破坏。综上所述，fese2介导的Fe2+自动再生和ROS自我产生途径大大提高了其氧化杀伤能力，为广谱非抗生素细菌消毒提供了潜在的ROS增强策略。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Advanced Healthcare Materials 工程技术-生物材料

CiteScore

14.40

自引率

3.00%

发文量

600

审稿时长

1.8 months

期刊介绍： Advanced Healthcare Materials, a distinguished member of the esteemed Advanced portfolio, has been dedicated to disseminating cutting-edge research on materials, devices, and technologies for enhancing human well-being for over ten years. As a comprehensive journal, it encompasses a wide range of disciplines such as biomaterials, biointerfaces, nanomedicine and nanotechnology, tissue engineering, and regenerative medicine.