![Sample our Physical Sciences journals, sign in here to start your FREE access for 14 days]({"type":"image" , "src" : "/sda/110819/TOC-Subject-Sample-2021-Physical-Sciences.jpg"})
Abstract
An ultraviolet (UV)-based advanced oxidation process (AOP), with hydrogen peroxide and medium-pressure (MP) UV light (H2O2/UV), was used as a pretreatment strategy for biofilm control in water. Suspended Pseudomonas aeruginosa cells were exposed to UV-based AOP treatment, and the adherent biofilm formed by the surviving cells was monitored. Control experiments using H2O2 or MP UV irradiation alone could inhibit biofilm formation for only short periods of time (<24 h) post-treatment. In a H2O2/filtered-UV (>295 nm) system, an additive effect on biofilm control was shown vs filtered-UV irradiation alone, probably due to activity of the added hydroxyl radical (OH•). In a H2O2/full-UV (ie full UV spectrum, not filtered) system, this result was not obtained, possibly due to the germicidal UV photons overwhelming the AOP system. Generally, however, H2O2/UV prevented biofilm formation for longer periods (days) only when maintained with residual H2O2. The ratio of surviving bacterial concentration post-treatment to residual H2O2 concentration played an important role in biofilm prevention and bacterial regrowth. H2O2 treatments alone resulted in poorer biofilm control compared to UV-based AOP treatments maintained with similar levels of residual H2O2, indicating a possible advantage of AOP.
Acknowledgements
This research is sponsored by the MAGNET Program of the Office of the Chief Scientist of the Ministry of Industry, Trade & Labor, Grant no. 2668. The authors acknowledge Atlantium Technologies Ltd and especially Dr Tali Harif and Dr Vladimir Glukhman for their fruitful collaboration and insights on UV, and thank Dr Alex Barbul, from the IDRFU (Inner Departmental Research Facility Unit), Tel-Aviv University, for his kind assistance with the confocal microscopy.