生物膜
抗菌剂
活性氧
催化作用
纳米技术
化学
药物输送
抗生素耐药性
纳米材料
微生物学
细菌
合理设计
双重角色
抗生素
微生物代谢
纳米医学
介孔材料
合成生物学
介孔二氧化硅
材料科学
生物
氧原子
生物物理学
氧代谢
大肠杆菌
抗菌肽
组合化学
作者
Haoju Huang,Yang Gao,Xizheng Wu,Zhiying Ding,Junqiao Zhao,Qinlong Wen,Lan Xie,Tian Ma,Mao Wang,Chong Cheng,Weifeng Zhao,Changsheng Zhao
出处
期刊:ACS Nano
[American Chemical Society]
日期:2025-10-13
卷期号:19 (41): 36784-36797
标识
DOI:10.1021/acsnano.5c13477
摘要
The global crisis of antimicrobial resistance demands solutions that transcend conventional antibiotic paradigms. Here, we present an atomically engineered VS4-based nanomaterial (TFB-Fe@VS4) featuring dendritic architectures with single-iron catalytic sites, designed as a multimodal reactive oxygen species (ROS) generator against methicillin-resistant Staphylococcus aureus (MRSA) and its recalcitrant biofilms. This biocatalytic system leverages three synergistic mechanisms: nanodendrite-mediated bacterial capture, microenvironment-responsive ROS generation, and ultrasound-amplified oxidative burst, which collectively address the key challenges in eradicating drug-resistant infections. Structural and spectroscopic analyses reveal that atomic iron sites serve dual functions as peroxidase-mimetic catalytic sites and electronic structure modulators, significantly enhancing ultrasound-triggered ROS production through band engineering. The TFB-Fe@VS4 achieves complete MRSA biofilm eradication and rapid wound sterilization in rabbit models with therapeutic outcomes similar to vancomycin yet without detectable inflammation or systemic toxicity. These findings present a design example for artificial biocatalysts that combines precise atomic engineering with multimodal antimicrobial action. The ability to simultaneously target bacterial adhesion, microenvironment adaptation, and on-demand ROS amplification presents transformative potential for treating resistant infections across diverse clinical scenarios, particularly where conventional therapies fail.
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