College of Materials Science and Engineering, Nanjing Tech University, Nanjing 211816, China.
Nanoscale. 2020 Oct 14;12(38):19655-19664. doi: 10.1039/d0nr06281b. Epub 2020 Sep 30.
The increasing threat of antibiotic-resistant bacterial strains represents the current antibacterial dilemma and requires novel bactericidal treatment to circumvent this problem. In this work, an efficient strategy for killing bacteria using PEDOT/MnO@Ag micromotors is reported based on the intense motion-induced convection and excellent sterilization ability of silver (Ag) ions. A distinctive inner surface structure with cubic Ag nanoparticle growth and dispersion in the MnO layer was constructed by simple cathodic co-electrodeposition. Due to the synergistic catalytic reaction of both MnO and Ag, the micromotors can rapidly swim in very low concentrations of hydrogen peroxide (HO). The antibacterial efficiency of the micromotors was evaluated with the Escherichia coli (E. coli) model. The continuous movement of micromotors, corresponding to violent mass transfer, along with the on-the-fly release of silver ions, greatly enhanced bacteria killing efficacy, with about 14% increase in bacterial death in 0.2% HO solution as compared to no motors. Such proposed micromotors could be ideal candidates for combating antibiotic-resistant bacteria in the fields of biomedical and environmental applications.
不断增加的抗生素耐药菌株威胁代表了当前抗菌领域的困境,需要新的杀菌疗法来解决这一问题。在这项工作中,基于银(Ag)离子强烈的运动诱导对流和出色的杀菌能力,报道了一种使用 PEDOT/MnO@Ag 微马达杀死细菌的有效策略。通过简单的阴极共电沉积构建了具有立方 Ag 纳米颗粒生长和分散在 MnO 层中的独特内表面结构。由于 MnO 和 Ag 的协同催化反应,微马达可以在非常低浓度的过氧化氢(HO)中快速游动。使用大肠杆菌(E. coli)模型评估了微马达的抗菌效率。微马达的连续运动,对应于剧烈的传质,以及银离子的即时释放,大大提高了杀菌效果,与没有微马达的 0.2%HO 溶液相比,细菌死亡率增加了约 14%。这种提出的微马达可以成为生物医学和环境应用领域对抗抗生素耐药细菌的理想候选者。
