活性氧
渗透(战争)
炎症
化学
材料科学
医学
生物化学
免疫学
运筹学
工程类
作者
Heping Wang,Xi Chen,Lulu Zhang,Ziwei Han,Jinxin Zheng,Yilin Qi,Weitao Zhao,Xihan Xu,Tianqi Li,Yutong Zhou,Pingping Bao,Xue Xue
标识
DOI:10.1002/advs.202305063
摘要
Abstract Bacterial infection‐induced inflammatory response could cause irreversible death of pulp tissue in the absence of timely and effective therapy. Given that, the narrow structure of root canal limits the therapeutic effects of passive diffusion‐drugs, considerable attention has been drawn to the development of nanomotors, which have high tissue penetration abilities but generally face the problem of insufficient fuel concentration. To address this drawback, dual‐fuel propelled nanomotors (DPNMs) by encapsulating L‐arginine (L‐Arg), calcium peroxide (CaO 2 ) in metal‐organic framework is developed. Under pathological environment, L‐Arg could release nitric oxide (NO) by reacting with reactive oxygen species (ROS) to provide the driving force for movement. Remarkably, the depleted ROS could be supplemented through the reaction between CaO 2 with acids abundant in the inflammatory microenvironment. Owing to high diffusivity, NO achieves further tissue penetration based on the first‐stage propulsion of nanomotors, thereby removing deep‐seated bacterial infection. Results indicate that the nanomotors effectively eliminate bacterial infection based on antibacterial activity of NO, thereby blocking inflammatory response and oxidative damage, forming reparative dentine layer to avoid further exposure and infection. Thus, this work provides a propagable strategy to overcome fuel shortage and facilitates the therapy of deep lesions.
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