重编程
金黄色葡萄球菌
化学
免疫系统
光热治疗
免疫疗法
排序酶A
癌症研究
再生(生物学)
细胞生物学
伤口愈合
催化作用
连接器
组织工程
微生物学
生物膜
渗透(战争)
细胞毒性
细菌
细胞
先天免疫系统
转录组
细胞疗法
抗原
免疫学
慢性伤口
脚手架
临床实习
作者
S X Xu,Binge Huang,Hao Lin,Jinming Li,Lu Zhang,Qi Zhang,Jia Li,Shiping Yang,Songsong Lan,Yan Yang,Yun Feng,Xiaojun He
标识
DOI:10.1002/advs.202516783
摘要
Translating pathogen-specific molecular insights into effective treatments remains a significant challenge, particularly for drug-resistant wound infections. In this study, we develop a nitrogen-doped iron/cobalt dual-atom catalyst (FeCo-N-DAC) with high metal loading (Fe > 5.4%, Co > 4.8%) as a multifunctional platform that integrates nanozyme-mimicking catalytic activity and photothermal therapy. FeCo-N-DAC mimics multiple natural enzymes to generate reactive oxygen species, disrupt bacterial biofilms, and eradicate methicillin-resistant Staphylococcus aureus (MRSA) in both murine and porcine models of subcutaneous abscesses and infectious wounds, respectively. Upon near-infrared (NIR-II) irradiation, the material exhibits deep-seated tissue penetration and synergistic catalytic-photothermal effects, enabling complete biofilm clearance in otherwise recalcitrant infections. Multi-omics analyses, including transcriptomics and proteomics, reveal that FeCo-N-DAC modulates immune responses and promotes tissue regeneration by reprogramming inflammation- and fibrosis-related pathways. This study highlights the therapeutic potential of dual-atom nanozymes for precision anti-infective therapy and underscores their translational relevance in treating complex, biofilm-associated infections.
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