生物膜
离子键合
铜
材料科学
离子
纳米技术
生物物理学
微生物学
化学
冶金
生物
细菌
遗传学
有机化学
作者
Xiaoye Li,Qiang Li,Ao He,Meng Dang,Yu Zhang,Minjin Wang,Qinhong Sun,Zhuo Dai,Meng Ding,Jinjin Zheng,Yongbin Mou,Weijun Xiu,Heng Dong
出处
期刊:ACS Nano
[American Chemical Society]
日期:2025-07-31
卷期号:19 (31): 28624-28643
被引量:29
标识
DOI:10.1021/acsnano.5c08035
摘要
Bacterial infections caused by drug-resistant bacteria persist due to biofilm-mediated tolerance, which limits the efficacy of both antimicrobial agents and host immune defenses. Here, we develop ionic microbubbles (MB-CuTA) self-assembled by Fe 3 O 4 @CuTA nanoparticles to enhance copper ion-mediated antibiofilm therapy. Upon ultrasound activation, MB-CuTA undergoes inertial cavitation, disrupting biofilm integrity and generating a localized surge of copper ions. This process achieves a dual therapeutic effect: (1) disruption of bacterial metabolic homeostasis, thereby overcoming the intrinsic resistance of biofilms to conventional antimicrobial agents, and (2) activation of cellular immunity to effectively counteract bacterial immune evasion mechanisms. By breaking biofilm tolerance through both metabolic and immunological pathways, our strategy enables deep copper ion penetration in biofilms and effective infection clearance in both mouse implant infection and peritonitis infection models. Our approach introduces a biofilm tolerance disruption method through inducing bacterial cuproptosis-like death and cellular immunity activation, offering a promising strategy against biofilm infections.
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