Triclosan biodegradation performance of adapted mixed cultures in batch and continuous operating systems at high-concentration levels

Triclosan biodegradation performance of adapted mixed cultures in batch and continuous operating systems at high-concentration levels

Pollutants like triclosan (TCS) of medium to high logKow value tend to be mainly adsorbed and poorly biodegraded during waste water treatment, complicating removal after release. Complete mineralization of TCS is crucial, since transformation products may be even more toxic, but has been proven only...

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Main Authors: Yen Lin Leong, Dominik Krivak, Martina Kiel, Eleni Laski, Armando González-Sánchez, Daniel Dobslaw
Format: Article
Language:English
Published: Elsevier 2021-12-01
Series:Cleaner Engineering and Technology
Subjects:
Triclosan
Elimination
Micropollutants
Biodegradation
Biotrickling filter
Biomembrane reactor
Online Access:http://www.sciencedirect.com/science/article/pii/S2666790821002263
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spelling doaj-6d9217ba28d247ac853c2118ee13ff902021-09-05T04:42:07ZengElsevierCleaner Engineering and Technology2666-79082021-12-015100266Triclosan biodegradation performance of adapted mixed cultures in batch and continuous operating systems at high-concentration levelsYen Lin Leong0Dominik Krivak1Martina Kiel2Eleni Laski3Armando González-Sánchez4Daniel Dobslaw5Institute of Sanitary Engineering, Water Quality and Solid Waste Management, University of Stuttgart, D-70569, Stuttgart, GermanyInstitute of Sanitary Engineering, Water Quality and Solid Waste Management, University of Stuttgart, D-70569, Stuttgart, GermanyInstitute of Sanitary Engineering, Water Quality and Solid Waste Management, University of Stuttgart, D-70569, Stuttgart, GermanyInstitute of Sanitary Engineering, Water Quality and Solid Waste Management, University of Stuttgart, D-70569, Stuttgart, GermanyInstitute of Sanitary Engineering, Water Quality and Solid Waste Management, University of Stuttgart, D-70569, Stuttgart, Germany; Institute of Engineering, Universidad Nacional Autónoma de México (UNAM), Circuito Escolar, Ciudad Universitaria, 04510, Mexico City, MexicoInstitute of Sanitary Engineering, Water Quality and Solid Waste Management, University of Stuttgart, D-70569, Stuttgart, Germany; Corresponding author. Department of Biological Waste Air Purification, Institute of Sanitary Engineering, Water Quality and Solid Waste Management, University of Stuttgart, Bandtäle 2, D-70569, Stuttgart, Germany.Pollutants like triclosan (TCS) of medium to high logKow value tend to be mainly adsorbed and poorly biodegraded during waste water treatment, complicating removal after release. Complete mineralization of TCS is crucial, since transformation products may be even more toxic, but has been proven only in a few cases. In this study, the performance of different batch (cultivation flask, TCSmix100) and continuous operating systems (submerged biotrickling filter, TCSmix100; biomembrane reactor, TCSmix200) was tested with two pre-adapted mixed cultures named TCSmix100 and TCSmix200, and compared to non-adapted cultures in a biotrickling filter and a sand filter as reference systems. Mineralization rates up to 172 mg TCS/L/d were observed during batch conditions for TCSmix100 at 1.45 g TCS/L as initial concentration. Triclosan was completely mineralized by both cultures, as shown by stoichiometric release of chloride at conversion rates of 5,7–11.4 mg TCS/L/d (biotrickling filter) and 0.72–1.45 mg TCS/L/d (biomembrane reactor) at 20 and 7.5–15 mg TCS/L as influent concentrations. In TCSmix100, Achromobacter sp. was identified as the relevant strain in TCS biodegradation. Community analysis of TCSmix200 revealed Nitrosomonas europaea, Nitrospira moscoviensis, Nitrosospira multiformis, and Rhodanobacter lindaniclasticus as the predominant strains. In contrast, chloride formation and triclosan elimination in the non-adapted biotrickling filter was less than 12% of the expected chloride concentration at hydraulic retention times up to 60 d. In the reference sand filter, TCS abatement was 42.8% in average with neither formation of chloride nor increase in biofilm density, indicating mostly sorptive or precipitative effects for elimination. With mineralization levels surpassing those of comparable references by a factor of 3–11, both adapted fixed-biomass reactor systems proved highly suitable for treatment of effluents containing high concentrations of TCS as they occur in industrial discharges or concentrates of membrane-based wastewater treatment plants.http://www.sciencedirect.com/science/article/pii/S2666790821002263TriclosanEliminationMicropollutantsBiodegradationBiotrickling filterBiomembrane reactor
collection DOAJ
language English
format Article
sources DOAJ
author Yen Lin Leong
Dominik Krivak
Martina Kiel
Eleni Laski
Armando González-Sánchez
Daniel Dobslaw
spellingShingle Yen Lin Leong
Dominik Krivak
Martina Kiel
Eleni Laski
Armando González-Sánchez
Daniel Dobslaw
Triclosan biodegradation performance of adapted mixed cultures in batch and continuous operating systems at high-concentration levels
Cleaner Engineering and Technology
Triclosan
Elimination
Micropollutants
Biodegradation
Biotrickling filter
Biomembrane reactor
author_facet Yen Lin Leong
Dominik Krivak
Martina Kiel
Eleni Laski
Armando González-Sánchez
Daniel Dobslaw
author_sort Yen Lin Leong
title Triclosan biodegradation performance of adapted mixed cultures in batch and continuous operating systems at high-concentration levels
title_short Triclosan biodegradation performance of adapted mixed cultures in batch and continuous operating systems at high-concentration levels
title_full Triclosan biodegradation performance of adapted mixed cultures in batch and continuous operating systems at high-concentration levels
title_fullStr Triclosan biodegradation performance of adapted mixed cultures in batch and continuous operating systems at high-concentration levels
title_full_unstemmed Triclosan biodegradation performance of adapted mixed cultures in batch and continuous operating systems at high-concentration levels
title_sort triclosan biodegradation performance of adapted mixed cultures in batch and continuous operating systems at high-concentration levels
publisher Elsevier
series Cleaner Engineering and Technology
issn 2666-7908
publishDate 2021-12-01
description Pollutants like triclosan (TCS) of medium to high logKow value tend to be mainly adsorbed and poorly biodegraded during waste water treatment, complicating removal after release. Complete mineralization of TCS is crucial, since transformation products may be even more toxic, but has been proven only in a few cases. In this study, the performance of different batch (cultivation flask, TCSmix100) and continuous operating systems (submerged biotrickling filter, TCSmix100; biomembrane reactor, TCSmix200) was tested with two pre-adapted mixed cultures named TCSmix100 and TCSmix200, and compared to non-adapted cultures in a biotrickling filter and a sand filter as reference systems. Mineralization rates up to 172 mg TCS/L/d were observed during batch conditions for TCSmix100 at 1.45 g TCS/L as initial concentration. Triclosan was completely mineralized by both cultures, as shown by stoichiometric release of chloride at conversion rates of 5,7–11.4 mg TCS/L/d (biotrickling filter) and 0.72–1.45 mg TCS/L/d (biomembrane reactor) at 20 and 7.5–15 mg TCS/L as influent concentrations. In TCSmix100, Achromobacter sp. was identified as the relevant strain in TCS biodegradation. Community analysis of TCSmix200 revealed Nitrosomonas europaea, Nitrospira moscoviensis, Nitrosospira multiformis, and Rhodanobacter lindaniclasticus as the predominant strains. In contrast, chloride formation and triclosan elimination in the non-adapted biotrickling filter was less than 12% of the expected chloride concentration at hydraulic retention times up to 60 d. In the reference sand filter, TCS abatement was 42.8% in average with neither formation of chloride nor increase in biofilm density, indicating mostly sorptive or precipitative effects for elimination. With mineralization levels surpassing those of comparable references by a factor of 3–11, both adapted fixed-biomass reactor systems proved highly suitable for treatment of effluents containing high concentrations of TCS as they occur in industrial discharges or concentrates of membrane-based wastewater treatment plants.
topic Triclosan
Elimination
Micropollutants
Biodegradation
Biotrickling filter
Biomembrane reactor
url http://www.sciencedirect.com/science/article/pii/S2666790821002263
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AT dominikkrivak triclosanbiodegradationperformanceofadaptedmixedculturesinbatchandcontinuousoperatingsystemsathighconcentrationlevels
AT martinakiel triclosanbiodegradationperformanceofadaptedmixedculturesinbatchandcontinuousoperatingsystemsathighconcentrationlevels
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AT armandogonzalezsanchez triclosanbiodegradationperformanceofadaptedmixedculturesinbatchandcontinuousoperatingsystemsathighconcentrationlevels
AT danieldobslaw triclosanbiodegradationperformanceofadaptedmixedculturesinbatchandcontinuousoperatingsystemsathighconcentrationlevels
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