Clinical Microbiology, Queen Elizabeth Hospital, University Hospitals Birmingham NHS Foundation Trust, Birmingham, United Kingdom.
NIHR Surgical Reconstruction and Microbiology Research Centre, Queen Elizabeth Hospital, Birmingham, United Kingdom.
Appl Environ Microbiol. 2019 Oct 16;85(21). doi: 10.1128/AEM.01346-19. Print 2019 Nov 1.
Light-emitting diodes (LEDs) demonstrate therapeutic effects for a range of biomedical applications, including photodisinfection. Bands of specific wavelengths (centered at 405 nm) are reported to be the most antimicrobial; however, there remains no consensus on the most effective irradiation parameters for optimal photodisinfection. The aim of this study was to assess decontamination efficiency by direct photodisinfection of monomicrobial biofilms using a violet-blue light (VBL) single-wavelength array (SWA) and multiwavelength array (MWA). Mature biofilms of nosocomial bacteria (, , , and ) were grown on 96-well polypropylene PCR plates. The biofilms were then exposed to VBL for 2,700 s (SWA) and 1,170 s (MWA) to deliver 0 to 670 J/cm, and the antibacterial activity of VBL was assessed by comparing the seeding of the irradiated and the nonirradiated biofilms. Nonirradiated groups were used as controls. The VBL arrays were characterized optically (spectral irradiance and beam profile) and thermally. The SWA delivered 401-nm VBL and the MWA delivered between 379-nm and 452-nm VBL, albeit at different irradiances and with different beam profiles. In both arrays, the irradiated groups were exposed to increased temperatures compared to the nonirradiated controls. All bacterial isolates were susceptible to VBL and demonstrated reductions in the seeding of exposed biofilms compared with the nonirradiated controls. VBL at 405 nm exerted the most antimicrobial activity, exhibiting reductions in seeding of up to 94%. Decontamination efficiency is dependent on the irradiation parameters, bacterial species and strain, and experimental conditions. Controlled experiments that ameliorate the heating effects and improve the optical properties are required to optimize the dosing parameters to advance the successful clinical translation of this technology. This study reports the efficacy of VBL and blue light (BL) and their antimicrobial activity against mature biofilms of a range of important nosocomial pathogens. While this study investigated the antibacterial activity of a range of wavelengths of between 375 and 450 nm and identified a specific wavelength region (∼405 nm) with increased antibacterial activity, decontamination was dependent on the bacterial species, strain, irradiation parameters, and experimental conditions. Further research with controlled experiments that ameliorate the heating effects and improve the optical properties are required to optimize the dosing parameters to advance the successful clinical translation of this technology.
发光二极管 (LED) 在各种生物医学应用中显示出治疗效果,包括光动力杀菌。据报道,特定波长(中心在 405nm 处)的波段最具抗菌性;然而,对于最佳光动力杀菌的最有效辐照参数仍没有共识。本研究的目的是使用紫光-蓝光 (VBL) 单波长阵列 (SWA) 和多波长阵列 (MWA) 直接光动力杀菌对单微生物生物膜进行消毒效率评估。医院获得性细菌 ( 、 、 和 ) 的成熟生物膜在 96 孔聚丙烯 PCR 板上生长。然后将生物膜暴露于 VBL 2700s(SWA) 和 1170s(MWA) 以提供 0 至 670J/cm,并通过比较辐照和未辐照生物膜的接种来评估 VBL 的抗菌活性。未辐照组用作对照。VBL 阵列在光学 (光谱辐照度和光束轮廓) 和热学方面进行了表征。SWA 提供 401nm VBL,MWA 提供 379nm 至 452nm VBL,但辐照度和光束轮廓不同。在两个阵列中,与未辐照对照相比,辐照组的温度升高。所有细菌分离株均对 VBL 敏感,与未辐照对照相比,暴露生物膜的接种减少。405nm 的 VBL 显示出最强的抗菌活性,接种减少高达 94%。消毒效率取决于辐照参数、细菌种类和菌株以及实验条件。需要进行受控实验以减轻加热效应并改善光学特性,从而优化剂量参数,以推进该技术的成功临床转化。本研究报告了 VBL 和蓝光 (BL) 的功效及其对一系列重要医院获得性病原体成熟生物膜的抗菌活性。虽然本研究调查了 375 至 450nm 之间的一系列波长的抗菌活性,并确定了具有增加的抗菌活性的特定波长区域 (∼405nm),但消毒取决于细菌种类、菌株、辐照参数和实验条件。需要进行具有受控实验的进一步研究,以减轻加热效应并改善光学特性,从而优化剂量参数,以推进该技术的成功临床转化。
