A Synergistic Antibacterial Platform Combining Low−Temperature Photothermal Therapy and Antibiotic Therapy

Future Pharmacology Pub Date : 2023-02-07 DOI:10.3390/futurepharmacol3010013

Qiming Zhang, Lei Chang, Caixia Sun, Wanchao Zuo, Shibo Zhang, Cong Liu, Shuyue Deng, Pengcheng Wu, Panpan Dai, Jianjun Dai, Yanmin Ju

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Abstract

Antimicrobial resistance has brought great burden to global public health. Alternative strategies are needed to reduce the development of drug resistance. Herein, we have developed an effective synergistic antibacterial strategy combining low−temperature photothermal therapy (LT−PTT) with antibiotic therapy, improving the bactericidal efficiency to avoid antimicrobial resistance. Copper sulfide templated with bovine serum albumin (CuS−BSA) nanoparticles were selected as the photothermal agent, and co−loaded into the hydrogel (Gel) with mupirocin. The Gel could slow down the release rate of CuS−BSA and mupirocin, thereby prolonging the effective drug reaction time. More importantly, when applying near−infrared laser irradiation, the antibacterial activity of the platform could be enhanced greatly by LT−PTT effect of CuS−BSA nanoparticles. In vitro and in vivo results both confirmed that the antibacterial efficacy of the synergistic therapeutic strategy was improved greatly with complete bacterial removal. Overall, this platform has posed a potential strategy to reduce the development of drug resistance and improve patient compliance.

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低温光热治疗与抗生素治疗的协同抗菌平台

抗菌素耐药性给全球公共卫生带来了巨大负担。需要其他策略来减少耐药性的产生。在此，我们开发了一种有效的协同抗菌策略，将低温光热疗法(LT - PTT)与抗生素治疗相结合，提高了杀菌效率，避免了抗生素耐药性。选择以牛血清白蛋白(cu - BSA)纳米颗粒为模板的硫化铜作为光热剂，用莫比罗星将co -负载到水凝胶(Gel)中。凝胶可以减缓CuS−BSA和莫哌罗星的释放速度，从而延长药物的有效反应时间。更重要的是，当近红外激光照射时，cu - BSA纳米颗粒的LT - PTT效应可以大大增强平台的抗菌活性。体外和体内实验结果均证实了协同治疗策略的抗菌效果大大提高，细菌完全去除。总体而言，该平台提出了减少耐药性发展和提高患者依从性的潜在策略。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Future Pharmacology

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