Faculty of Engineering and Environment, Northumbria University, Newcastle upon Tyne, NE1 8ST, UK.
Hub of Biotechnology in the Building Environment, Department of Applied Science, Northumbria University, Newcastle upon Tyne, NE1 8ST, UK.
Lab Chip. 2024 Sep 10;24(18):4344-4356. doi: 10.1039/d4lc00285g.
Formation of bacterial films on structural surfaces often leads to severe contamination of medical devices, hospital equipment, implant materials, , and antimicrobial resistance of microorganisms has indeed become a global health issue. Therefore, effective therapies for controlling infectious and pathogenic bacteria are urgently needed. Being a promising active method for this purpose, surface acoustic waves (SAWs) have merits such as nanoscale earthquake-like vibration/agitation/radiation, acoustic streaming induced circulations, and localised acoustic heating effect in liquids. However, only a few studies have explored controlling bacterial growth and inactivation behaviour using SAWs. In this study, we proposed utilising piezoelectric thin film-based SAW devices on a silicon substrate for controlling bacterial growth and inactivation with and without using ZnO micro/nanostructures. Effects of SAW powers on bacterial growth for two types of bacteria, , and , were evaluated. Varied concentrations of ZnO tetrapods were also added into the bacterial culture to study their effects and the combined antimicrobial effects along with SAW agitation. Our results showed that when the SAW power was below a threshold (, about 2.55 W in this study), the bacterial growth was apparently enhanced, whereas the further increase of SAW power to a high power caused inactivation of bacteria. Combination of thin film SAWs with ZnO tetrapods led to significantly decreased growth or inactivation for both and , revealing their effectiveness for antimicrobial treatment. Mechanisms and effects of SAW interactions with bacterial solutions and ZnO tetrapods have been systematically discussed.
结构表面上细菌膜的形成常常导致医疗器械、医院设备、植入材料等严重污染,微生物的抗菌耐药性确实已成为一个全球性的健康问题。因此,迫切需要有效的治疗方法来控制感染性和致病性细菌。作为一种有前途的主动方法,表面声波(SAW)具有纳米级地震般的振动/搅动/辐射、声流引起的循环以及液体中的局部声加热效应等优点。然而,只有少数研究探索了使用 SAW 控制细菌生长和失活动力学。在这项研究中,我们提出利用基于压电薄膜的硅基 SAW 器件来控制细菌生长和失活,同时使用和不使用 ZnO 微/纳米结构。评估了两种细菌、 和 的 SAW 功率对细菌生长的影响。还向细菌培养物中添加了不同浓度的 ZnO 四足体,以研究它们的作用以及与 SAW 搅拌相结合的联合抗菌作用。结果表明,当 SAW 功率低于阈值(,在本研究中约为 2.55 W)时,细菌生长明显增强,而当 SAW 功率进一步增加到高功率时,细菌失活。薄膜 SAW 与 ZnO 四足体的结合导致 和 两种细菌的生长明显减少或失活,表明它们在抗菌治疗方面的有效性。系统地讨论了 SAW 与细菌溶液和 ZnO 四足体相互作用的机制和影响。
