金黄色葡萄球菌
纳米纤维
肺
中性粒细胞胞外陷阱
伤口愈合
细胞外
毒力
微生物学
细胞生物学
细胞外小泡
细胞膜
表型
吞噬作用
化学
小泡
膜
细胞
免疫学
医学
炎症
急性呼吸窘迫综合征
材料科学
病菌
生物物理学
慢性伤口
生物
癌症研究
程序性细胞死亡
作者
Jiaying Lin,Jiali Duan,Jiangna Guo,H. Xu,Rongwei Shi,Linhui Zhao,Yangyang Liu,Na Meng,Jiateng Zhou,Xiao Zhang,Shihui Lin,Feng Yan,Bin Wang,Hailei Mao
标识
DOI:10.1002/adma.202519131
摘要
Staphylococcus aureus membrane vesicles (MVs) cause host injury and excessive inflammation, yet their pathological roles and clearance strategies remain undefined. Guided by molecular dynamics simulations of MV-polymer interactions, we engineered imidazolium-based poly(ionic liquid) (PIL) electrospun nanofibers for targeted MV interception. Among multiple formulations, PIL-C4 demonstrated optimal performance, combining potent antibacterial activity, robust adsorption of methicillin-resistant S. aureus (MRSA) MVs and their virulence factors, minimal cytotoxicity, and inhibition of resistance transmission. In vivo, PIL-C4 attenuated MV-induced neutrophil extracellular trap (NET) formation (NETosis) and vascular leakage, thereby reducing purulent-exudative wound injury and preventing systemic organ damage, including fatal lung injury. Notably, DNase-mediated NET degradation alone failed to rescue MV pathology, underscoring the necessity of direct MV clearance. This study uncovers previously unrecognized NETosis-driven phenotypes of S. aureus MVs-local purulent-exudative wound injury and systemic lethal lung damage-and establishes a polymer-based clearance strategy with translational potential for infection control.
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