金黄色葡萄球菌
抗生素
抗菌活性
活性氧
光热治疗
小学(天文学)
微生物学
免疫学
细菌
病菌
人类病原体
致病菌
生物
巨噬细胞
抗原
细胞毒性
材料科学
人类健康
传染源
葡萄球菌感染
抗菌剂
抗感染药
传染病(医学专业)
作者
Jiangge Li,Sutong Xiao,Shihuan Gao,Mao Wang,Minjia Yuan,H Yang,Mohsen Adeli,Shuang Li,Weifeng Zhao,Chong Cheng,Changsheng Zhao
摘要
The rapid evolution of antibiotic-resistant bacteria, particularly methicillin-resistant Staphylococcus aureus (MRSA), poses a critical threat to human healthcare, underscoring the need for antibiotic-free antibacterial strategies that achieve both effective pathogen eradication and sustained protection against reinfection. Here, inspired by the functions of natural macrophages, we report the de novo design of an Ir/TiN-based photothermal-activable artificial macrophage (ITN Art-M) with enhanced systemic antibacterial activity to combat primary and secondary infections caused by antibiotic-resistant bacteria. The experimental studies and theoretical calculations reveal that the ITN Art-M displays spiky topology, robust photothermal properties, and electron-rich Ir-Ti catalytic sites for reactive oxygen species (ROS) production, which can efficiently capture and kill antibiotic-resistant bacteria. Meanwhile, the synthesized ITN Art-M can induce severe bacterial antigen leakage and exposure through synergistic oxidative and hyperthermic stress, thereby potently stimulating systemic antibacterial responses, assisting in the elimination of primary infections and establishing durable defensive surveillance against secondary infections. Notably, ITN Art-M demonstrates superior MRSA eradication and recurrence prevention, offering a potent, intelligent alternative that may surpass conventional antibiotics in combating bacteria and many other pathogenic cells.
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