探索聚合物基纳米复合材料中的电活性微环境以使细菌细胞对低剂量抗菌素敏感

J. Moreira, M. Fernandes, Estela O. Carvalho, A. Nicolau, V. Lazić, V. Lazić, J. Nedeljković, S. Lanceros‐Méndez
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摘要

由于抗生素耐药性的惊人出现,迫切需要寻找能够避免细菌耐药机制的新型抗菌策略。应用物理刺激作为致敏细菌的手段,使抗菌素对其他耐药细菌起作用,或通过允许极少量的抗菌素起作用,可被视为实现这一目的的突破。这项工作提出了利用压电聚合物(聚偏氟乙烯-共三氟乙烯)(PVDF-TrFE)产生的电活性微环境与绿色合成的银纳米颗粒(AgNPs)之间的协同作用来开发抗菌纳米复合材料。电微环境是通过使用实验室制造的机械生物反应器对压电PVDF-TrFE/AgNPs薄膜进行机械刺激而产生的。生成的材料的电响应进一步转化为细菌细胞,细菌细胞与AgNPs和材料的特定形态特征结合,诱导出重要的抗菌和抗生物膜活性。当机械频率为4Hz时,多孔和非多孔PVDF复合材料都显示出抗菌特性,当纳米复合材料中加入AgNPs时,效果得到增强,浮游和生物膜形式的细菌生长减少了80%以上。电活性环境使细菌敏感,允许极低剂量的AgNPs的作用。重要的是,这种材料不会损害哺乳动物细胞的生存能力,因此被认为是生物相容性的。利用机械刺激(压力/触摸)来发挥抗菌和抗生物膜活性,pvdf基聚合物薄膜的压电刺激可能代表了医院设备抗菌涂层发展的一个突破。
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Exploring Electroactive Microenvironments in Polymer-Based Nanocomposites to Sensitize Bacterial Cells to Low Doses of Antimicrobials
The search for novel antimicrobial strategies capable of avoiding resistance mechanisms in bacteria are highly needed due to the alarming emergence of antimicrobial resistance. The application of physical stimuli as a mean of sensitizing bacteria for the action of antimicrobials on otherwise resistant bacteria or by allowing the action of an extremely low quantity of antimicrobials may be seen as a breakthrough for such purpose. This work proposes the development of antibacterial nanocomposites using the synergy between the electrically active microenvironments, created by a piezoelectric polymer (poly(vinylidene fluoride-co-trifluoroethylene) (PVDF-TrFE)), with green-synthesized silver nanoparticles (AgNPs). The electrical microenvironment is generated via mechanical stimulation of piezoelectric PVDF-TrFE/AgNPs films using a lab-made mechanical bioreactor. The generated material’s electrical response further translates to bacterial cells, which in combination with AgNPs and the specific morphological features of the material induce important antibacterial and antibiofilm activity. Both porous and non-porous PVDF composites have shown antibacterial characteristics when stimulated at a mechanical frequency of 4Hz being the effect boosted when AgNPs were incorporated in the nanocomposite, reducing in more than 80 % the bacterial growth in planktonic and biofilm form. The electroactive environments sensitize the bacteria allowing the action of extremely low doses of AgNPs. Importantly, the material did not compromise the viability of mammalian cells, thus being considered biocompatible. The piezoelectric stimulation of PVDF-based polymeric films may represent a breakthrough in the development of antibacterial coatings for devices used at hospital setting, taking advantage on the use of mechanical stimuli (pressure/touch) to exert antibacterial and antibiofilm activity.
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