Department of Civil and Environmental Engineering, University of New Hampshire, Durham, New Hampshire, USA.
Department of Civil, Construction, and Environmental Engineering, North Carolina State Universitygrid.40803.3f, Raleigh, North Carolina, USA.
Appl Environ Microbiol. 2022 Oct 11;88(19):e0122122. doi: 10.1128/aem.01221-22. Epub 2022 Sep 21.
The objective of this study was to evaluate the effectiveness of UV technology for virus disinfection to allow FFR reuse. UV is a proven decontamination tool for microbial pathogens, including the SARS-CoV-2 virus. Research findings suggest that the impacts of UV-C treatment on FFR material degradation should be confirmed using microbial surrogates in addition to the commonly performed abiotic particle testing. This study used the surrogates, E. coli and MS-2 bacteriophage, as they bracket the UV response of SARS-CoV-2. Lower log inactivation was observed on FFRs than predicted by aqueous-based UV dose-response data for MS-2 bacteriophage and E. coli. In addition, the dose-response curves did not follow the trends commonly observed with aqueous data for E. coli and MS-2. The dose-response curves for the respirators in this study had a semicircle shape, where the inactivation reached a peak and then decreased. This decrease in UV inactivation is thought to be due to the degradation of the fibers of the FFR and allows for more viral and bacterial cells to wash through the layers of the respirator. This degradation phenomenon was observed at UV doses at and above 2,000 mJ/cm. Results have demonstrated that FFR materials yield various results in terms of effective disinfection in experiments conducted on KN95 and N95 face respirators. The highest inactivation for both surrogates was observed with the KN95 respirator made by Purism, yielding 3 and 2.75 log inactivation for E. coli and MS-2 at UV doses of 1,500 mJ/cm. The KN95 made by Anboruo yielded the lowest inactivation for MS-2 at 0.75 log when exposed to 1,000 mJ/cm. To further test the degradation theory, experiments used a collimated beam device to test the hypothesis further that degradation is occurring at and above UV doses of 1,500 mJ/cm. The experiment aimed to determine the effect of "predosing" a respirator with UV before inoculating the respirator with MS-2. In this test, quantification of the penetrated irradiance value and the ability of each layer to retain MS-2 were quantified. The results of the experiments varied from the intact FFR degradation experiments but displayed some data to support the degradation theory. Research suggests degradation of FFR materials at high UV doses is important. There appears to be a peak inactivation dose at approximately 1,500 mJ/cm. The subsequent dose increases appear to have the reverse effect on inactivation values; these trends have shown true with both the N95 and KN95-Purism respirators.
本研究旨在评估 UV 技术对病毒消毒的有效性,以实现 FFR 的重复使用。UV 是一种经过验证的微生物病原体消毒工具,包括 SARS-CoV-2 病毒。研究结果表明,除了通常进行的非生物颗粒测试外,还应使用微生物替代物来确认 UV-C 处理对 FFR 材料降解的影响。本研究使用大肠杆菌和 MS-2 噬菌体作为替代物,因为它们涵盖了 SARS-CoV-2 的 UV 反应。与基于水溶液的 MS-2 噬菌体和大肠杆菌 UV 剂量-反应数据预测相比,FFR 上观察到的对数灭活较低。此外,剂量-反应曲线不符合大肠杆菌和 MS-2 通常观察到的水溶液数据趋势。本研究中呼吸器的剂量-反应曲线呈半圆形,其中灭活达到峰值然后下降。这种 UV 灭活的减少被认为是由于 FFR 纤维的降解,从而允许更多的病毒和细菌细胞通过呼吸器的层洗过。这种降解现象在 2000mJ/cm 及以上的 UV 剂量下观察到。结果表明,在对 KN95 和 N95 口罩进行的实验中,FFR 材料在有效消毒方面产生了不同的结果。对于两种替代物,Purism 制造的 KN95 口罩的灭活效果最高,在 1500mJ/cm 的 UV 剂量下,大肠杆菌和 MS-2 的灭活分别为 3 和 2.75 个对数。当暴露于 1000mJ/cm 时,Anboruo 制造的 KN95 口罩对 MS-2 的灭活最低,为 0.75 个对数。为了进一步测试降解理论,实验使用准直光束装置进一步测试假设,即降解发生在 1500mJ/cm 及以上的 UV 剂量下。该实验旨在确定在接种 MS-2 之前用 UV 对口罩进行“预照射”的效果。在该测试中,量化了穿透辐照度值和每个层保留 MS-2 的能力。实验结果与完整 FFR 降解实验有所不同,但显示出一些数据支持降解理论。研究表明,高剂量的 FFR 材料降解很重要。在大约 1500mJ/cm 的剂量似乎存在一个峰值灭活剂量。随后的剂量增加似乎对灭活值产生了相反的影响;这些趋势在 N95 和 KN95-Purism 口罩中都得到了证实。
