Wavelength-dependent Time-dose Reciprocity and Stress Mechanism for UV-LED Disinfection of Escherichia Coli

Overview

Journal J Photochem Photobiol B

Specialty Biology

Date 2021 Mar 13

PMID 33713893

Citations 13

Authors

Dana Pousty

Ron Hofmann

Yoram Gerchman

Hadas Mamane

Affiliations

Soon will be listed here.

Abstract

Ultraviolet (UV) disinfection efficiency by low-pressure (LP) mercury lamp depends on the UV fluence (dose): the product of incident irradiance (fluence rate) and exposure time, with correction factors. Time-dose reciprocity may not always apply, as higher UV-LP inactivation of E. coli was obtained at a higher irradiance over shorter exposure time, for the same UV fluence. Disinfection by UV LEDs is limited by low radiant flux compared to mercury LP lamps. Our goal was to determine the UV-LED time-dose reciprocity of E. coli for four different central LED wavelengths (265, 275, 285 and 295 nm) under different fluence rates. Inactivation kinetics determined at UV-LED was not affected by the fluence rate or exposure time for a given UV fluence. In contrast, UV-LED, UV-LED, and UV-LED led to higher inactivation at low fluence rate coupled to high exposure time, for the same UV fluence. The intracellular damage mechanisms for each LED central wavelength were determined by using the bioreporters RecA as an indicator of bacterial DNA damage and SoxS as an indicator of oxidative stress. For 265 nm, higher DNA damage was observed, whereas for 285 and 295 nm, higher oxidative stress (possibly due to reactive oxygen species [ROS] damage) was observed. ROS inactivation of E. coli was predicted to be more effective when keeping the ROS concentration low but allowing longer exposure, for a given UV fluence.

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