Zhu Wanbo, Mei Jiawei, Zhang Xianzuo, Zhou Jun, Xu Dongdong, Su Zheng, Fang Shiyuan, Wang Jiaxing, Zhang Xianlong, Zhu Chen
Department of Orthopedics, The First Affiliated Hospital of USTC, University of Science and Technology of China, Hefei, Anhui, 230001, P. R. China.
Department of Orthopedics, Shanghai Sixth People's Hospital Affiliated to Shanghai Jiao Tong University School of Medicine, Shanghai Jiao Tong University, Shanghai, 200233, P. R. China.
Adv Mater. 2022 Dec;34(51):e2207961. doi: 10.1002/adma.202207961. Epub 2022 Nov 17.
Owing to high antibiotic resistance and thermotolerance, bacterial biofilm infections (BBIs) are refractory to elimination. Iron is essential for bacterial growth and metabolism, and bacteria can thus accumulate iron from surrounding cells to maintain biofilm formation and survival. Consequently, iron deficiency in the biofilm microenvironment (BME) leads to the functional failure of innate immune cells. Herein, a novel antibiofilm strategy of iron-actuated Janus ion therapy (IJIT) is proposed to regulate iron metabolism in both bacterial biofilm and immune cells. A BME-responsive photothermal microneedle patch (FGO@MN) is synthesized by the growth of Fe O nanoparticles on graphene oxide nanosheets and then encapsulated in methacrylated hyaluronic acid needle tips. The catalytic product of ·OH by FGO@MN in BME disrupts the bacterial heat-shock proteins, coercing biofilm thermal sensitization. As synergistic mild photothermal treatment triggers iron uptake, the intracellular iron overload further induces ferroptosis-like death. Moreover, iron-nourished neutrophils around BME can be rejuvenated for reactivating the suppressed antibiofilm function. Thus, more than 95% BBIs elimination can be achieved by combining heat stress-triggered iron interference with iron-nutrient immune reactivation. Furthermore, in vivo experiments validate the scavenging of refractory BBI after 15 days, suggesting the promising perspective of IJIT in future clinical application.
由于高抗生素耐药性和耐热性,细菌生物膜感染(BBIs)难以消除。铁对于细菌生长和代谢至关重要,因此细菌可以从周围细胞中积累铁以维持生物膜的形成和存活。因此,生物膜微环境(BME)中的铁缺乏会导致先天免疫细胞功能失效。在此,提出了一种新型的铁驱动的Janus离子疗法(IJIT)抗生物膜策略,以调节细菌生物膜和免疫细胞中的铁代谢。通过在氧化石墨烯纳米片上生长Fe₃O₄纳米颗粒,然后封装在甲基丙烯酸化透明质酸针尖中,合成了一种BME响应性光热微针贴片(FGO@MN)。FGO@MN在BME中产生的·OH催化产物破坏细菌热休克蛋白,迫使生物膜热敏化。由于协同温和的光热处理触发铁摄取,细胞内铁过载进一步诱导铁死亡样死亡。此外,BME周围铁营养充足的中性粒细胞可以恢复活力,重新激活被抑制的抗生物膜功能。因此,通过将热应激触发的铁干扰与铁营养免疫再激活相结合,可以实现超过95%的BBIs消除。此外,体内实验验证了15天后难治性BBI的清除,表明IJIT在未来临床应用中有广阔前景。
