Reducing the Impacts of Biofouling in RO Membrane Systems through In Situ Low Fluence Irradiation Employing UVC-LEDs

Sperle, Philipp; Wurzbacher, Christian; Drewes, Jörg E.; Skibinski, Bertram

doi:10.3390/membranes10120415

Cited by 13 publications

(12 citation statements)

References 133 publications

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“…Dhakal et al [39] developed and demonstrated the applicability of the flow cytometry (FCM)-based bacterial growth potential (BGP) method to assess the biofouling potential in seawater (SW) RO systems using a natural microbial consortium. Sperle et al [40] reported the potential of UVC irradiation using the recently developed UV-LEDs as an in situ pretreatment strategy for biofouling control in RO or NF systems. In contrast to UV studies carried out previously, they tested if low fluences are sufficient to not only delay the biofilm formation but further lead to a reduced hydraulic resistance of the biofilm while approaching a severe biofouling state.…”

Section: Conventional Thermal Technologiesmentioning

confidence: 99%

Comparative Analysis of Conventional and Emerging Technologies for Seawater Desalination: Northern Chile as A Case Study

et al. 2021

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The aim of this work was to study different desalination technologies as alternatives to conventional reverse osmosis (RO) through a systematic literature review. An expert panel evaluated thermal and membrane processes considering their possible implementation at a pilot plant scale (100 m3/d of purified water) starting from seawater at 20 °C with an average salinity of 34,000 ppm. The desalination plant would be located in the Atacama Region (Chile), where the high solar radiation level justifies an off-grid installation using photovoltaic panels. We classified the collected information about conventional and emerging technologies for seawater desalination, and then an expert panel evaluated these technologies considering five categories: (1) technical characteristics, (2) scale-up potential, (3) temperature effect, (4) electrical supply options, and (5) economic viability. Further, the potential inclusion of graphene oxide and aquaporin-based biomimetic membranes in the desalinization processes was analyzed. The comparative analysis lets us conclude that nanomembranes represent a technically and economically competitive alternative versus RO membranes. Therefore, a profitable desalination process should consider nanomembranes, use of an energy recovery system, and mixed energy supply (non-conventional renewable energy + electrical network). This document presents an up-to-date overview of the impact of emerging technologies on desalinated quality water, process costs, productivity, renewable energy use, and separation efficiency.

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Section: Conventional Thermal Technologiesmentioning

confidence: 99%

Comparative Analysis of Conventional and Emerging Technologies for Seawater Desalination: Northern Chile as A Case Study

et al. 2021

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“…For instance, LED lights are promising tools for in situ antimicrobial treatments along water distribution facilities such as plumbing installations and showerheads in order to prevent the development of opportunistic pathogens (Cates and Torkzadeh 2020 ). In addition, the installation of optical fibres within the plumbing network can provide a treatment solution for the internal surfaces of the pipes, as suggested by (Lanzarini-Lopes et al 2020 ), and also for reducing biofouling in membrane filtration systems (Sperle et al 2020 ).…”

Section: Introductionmentioning

confidence: 99%

Cell density and extracellular matrix composition mitigate bacterial biofilm sensitivity to UV-C LED irradiation

Labadie,

Marchal,

Merbahi

et al. 2024

Appl Microbiol Biotechnol

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Ultraviolet-C light-emitting diodes (UV-C LEDs) are an emerging technology for decontamination applications in different sectors. In this study, the inactivation of bacterial biofilms was investigated by applying an UV-C LED emitting at 280 nm and by measuring both the influence of the initial cell density (load) and presence of an extracellular matrix (biofilm). Two bacterial strains exposing diverging matrix structures and biochemical compositions were used: Pseudomonas aeruginosa and Leuconostoc citreum. UV-C LED irradiation was applied at three UV doses (171 to 684 mJ/cm2) on both surface-spread cells and on 24-h biofilms and under controlled cell loads, and bacterial survival was determined. All surface-spread bacteria, between 105 and 109 CFU/cm2, and biofilms at 108 CFU/cm2 showed that bacterial response to irradiation was dose-dependent. The treatment efficacy decreased significantly for L. citreum surface-spread cells when the initial cell load was high, while no load effect was observed for P. aeruginosa. Inactivation was also reduced when bacteria were grown under a biofilm form, especially for P. aeruginosa: a protective effect could be attributed to abundant extracellular DNA and proteins in the matrix of P. aeruginosa biofilms, as revealed by Confocal Laser Scanning Microscopy observations. This study showed that initial cell load and exopolymeric substances are major factors influencing UV-C LED antibiofilm treatment efficacy. Key points • Bacterial cell load (CFU/cm2) could impact UV-C LED irradiation efficiency • Characteristics of the biofilm matrix have a paramount importance on inactivation • The dose to be applied can be predicted based on biofilm properties Graphical Abstract

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“…drinking and wastewater disinfection. However, applying UV disinfection for other applications like using UV irradiation as pre-treatment for biofouling control in membrane filtration systems, , E. coli may not be the ideal model organism. Biofilms often consist of noninfectious, nonmodel organisms, which to our knowledge have not been used as challenge organisms, yet.…”

Section: Introductionmentioning

confidence: 99%

“…This study aims to provide a standardized biodosimetry protocol for flow-through reactors and to elucidate critical steps that mitigate artifacts exploring new UV treatment designs with bacterial cells (using LEDs or conventional lamps). This is achieved by comparing the existing methods for flow-through UV reactors and the subsequent evaluation of the most important steps resulting in a standardized and reproducible biodosimetry protocol for the nonmodel organism, Aquabacterium citratiphilum , a Gram-negative bacterium found typically in drinking water biofilms around Europe with potential relevance for biofouling of high-pressure membrane treatment …”

Section: Introductionmentioning

confidence: 99%

A Practical Bacterial Biodosimetry Procedure to Assess Performance of Lab-Scale Flow-through Ultraviolet Water Disinfection Reactors

et al. 2023

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Biodosimetry can be used to estimate the fluence of a reactor by determining its ability to inactivate a challenge organism. Especially for small-scale flow-through reactors, inconsistent procedures are reported for bacterial cells. This study aims to develop a standardized, simple procedure for bacterial biodosimetry in flow-through UV systems with relevant biofilmforming bacteria, to evaluate biofouling control by UV. In particular, the challenge organism, the type of experimental setup, and the execution of single steps during biodosimetry with bacterial cells can cause largely deviating results. Since previous work was restricted to model organisms, which are not relevant for biofouling, we critically re-evaluated all reported steps for the biofilm forming Aquabacterium citratiphilum and identified three main factors for biodosimetry reproducibility in flow-through systems: Protractions of cells from controls without UV can heavily impact inactivation efficacy but can be reduced by ordering samples by decreasing fluence. Further, to avoid photorepair, samples must be processed under red light only. Lastly, biofilm forming bacteria can strongly adsorb on plastic labware, which requires counter measures in the form of special labware and the addition of surfactants. Overall, the developed protocol provides a biodosimetry standardization for bacterial cells of flow-through systems, facilitating reproducibility and transferability of results between studies that use bacterial cells as a challenge organism.

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Reducing the Impacts of Biofouling in RO Membrane Systems through In Situ Low Fluence Irradiation Employing UVC-LEDs

Cited by 13 publications

References 133 publications

Comparative Analysis of Conventional and Emerging Technologies for Seawater Desalination: Northern Chile as A Case Study

Comparative Analysis of Conventional and Emerging Technologies for Seawater Desalination: Northern Chile as A Case Study

Cell density and extracellular matrix composition mitigate bacterial biofilm sensitivity to UV-C LED irradiation

A Practical Bacterial Biodosimetry Procedure to Assess Performance of Lab-Scale Flow-through Ultraviolet Water Disinfection Reactors

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