Efficiency of an air circulation decontamination device for micro-organisms using ultraviolet radiation.

BACKGROUND: The concern with environmental security to avoid contamination of individuals was intensified with the crisis established by SARS-CoV-2. The COVID-19 pandemic has shown the necessity to create systems and devices capable of clearing the air in an environment of micro-organisms more efficiently. The development of systems that allow the removal of micro-droplets mainly originating from breathing or talking from the air was the motivation of this study. AIM: This article describes a portable and easy-to-operate system that helps to eliminate the droplets or aerosols present in the environment by circulating air through an ultraviolet-C (UV-C) reactor. METHODS: An air circulation device was developed, and a proof-of-principle study was performed using the device against bacteria in simulated and natural environments. The microbiological analysis was carried out by the simple sedimentation technique. In order to compare the experimental results and the expected results for other micro-organisms, the reduction rate values for bacteria and viruses were calculated and compared with the experimental results based on technical parameters (clean air delivery rate (CADR) and air changes per hour (ACH)). FINDINGS: Results showed that the micro-organisms were eliminated with high efficiency by the air circulation decontamination device, with reductions of 99.9% in the proof-of-principle study, and 84-97% in the hospital environments study, contributing to reducing contamination of individuals in environments considered to present risk. CONCLUSION: This study resulted in a low-cost and relatively simple device, which was shown to be effective and safe, and could be replicated, especially in low-income countries, respecting the standards for air disinfection using UV-C technologies.

The influence of experimental conditions on the final result of photoinhibition of Staphylococcus aureus.

BACKGROUND: By and large, phototherapies are a promising approach to promote inactivation of microorganisms using light exposure, providing an effective alternative to control multidrug-resistant bacterial infections. Considering this, intercomparison between experiments is vitally important. Most experiments are performed using multiwell plates in which the volume of the culture medium is not standardized. In such cases, light attenuation and the distance it travels, which also depends on the volume and vessel geometry, can lead to different results. This study investigated how the different volumes imply different depths that light will have to travel through in this volume and the relation of this parameter with the result that will be obtained. METHODS: Staphylococcus aureus was exposed to 460nm light with 50, 100 and 200J/cm2, in 100, 200, 500 and 1000µL of inocula in a 24-well plate to investigate pure light inactivation. RESULTS: The literature suggests that fluence is the most important light parameter to obtain a high eradication of microbial cells in phototherapies. Our results show evidence that different geometrical configurations, taking into account the volume of the vessels, clearly affect the in vitro results, risking misinterpretation of dosimetry studies. Effects, such as dose distribution and decantation, are discussed throughout the paper. CONCLUSION: The outcome strongly depends on the volume and vessel geometry used. This study aims to encourage the standardization of phototherapies in vitro in general.