New insights into the transformation of trimethoprim during biological wastewater treatment

Jewell, Kevin S.; Castronovo, Sandro; Wick, Arne N.; Falås, Per; Joss, Adriano; Ternes, Thomas A.

doi:10.1016/j.watres.2015.10.026

Cited by 96 publications

(73 citation statements)

References 30 publications

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“…NOBs were representing less than 0.1% (mostly Candidatus Nitrotoga arctica ) of the community. These results can explain the differences in the negative effect of antibiotics on nitrifying community between this study and previously reported data because of different key nitrifying bacteria …”

Section: Resultssupporting

confidence: 62%

Effect of sulfadiazine and trimethoprim on activated sludge performance and microbial community dynamics in laboratory‐scale membrane bioreactors and sequencing batch reactors at 8°C

Kruglova

Mikola

González‐Martínez

et al. 2018

Biotechnology Progress

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The effect of antibiotics sulfadiazine and trimethoprim on activated sludge operated at 8°C was investigated. Performance and microbial communities of sequencing batch reactors (SBRs) and Membrane Bioreactors (MBRs) were compared before and after the exposure of antibiotics to the synthetic wastewater. The results revealed irreversible negative effect of these antibiotics in environmentally relevant concentrations on nitrifying microbial community of SBR activated sludge. In opposite, MBR sludge demonstrated fast adaptation and more stable performance during the antibiotics exposure. Dynamics of microbial community was greatly affected by presence of antibiotics. Bacteria from classes Betaproteobacteria and Bacteroidetes demonstrated the potential to develop antibiotic resistance in both wastewater treatment systems while Actinobacteria disappeared from all of the reactors after 60 days of antibiotics exposure. Altogether, results showed that operational parameters such as sludge retention time (SRT) and reactor configuration had great effect on microbial community composition of activated sludge and its vulnerability to antibiotics. Operation at long SRT allowed archaea, including ammonium oxidizing species (AOA) such as Nitrososphaera viennensis to grow in MBRs. AOA could have an important role in stable nitrification performance of MBR‐activated sludge as a result of tolerance of archaea to antibiotics. © 2018 American Institute of Chemical Engineers Biotechnol. Prog., 35: e2708, 2019

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Section: Resultssupporting

confidence: 62%

Effect of sulfadiazine and trimethoprim on activated sludge performance and microbial community dynamics in laboratory‐scale membrane bioreactors and sequencing batch reactors at 8°C

Kruglova

Mikola

González‐Martínez

et al. 2018

Biotechnology Progress

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“…These results suggest that electrochemistry-high resolution mass spectrometry is an interesting technique for studying oxidative reactions of organic compounds of environmental interest, as was previously suggested by Hoffmann et al [12]. Nitrifying bacteria in activated sludge [34].…”

Section: Thin-layer Flow Cell Coupled Online To High-resolution Mass supporting

confidence: 75%

“…In a previous study of the transformation of TRI under aerobic conditions in nitrifying activated sludge, this same structure was assigned to a transformation product of TRI with the same exact mass, albeit a completely different MS/MS spectrum [34]. While differences in MS/MS could be the result of different mass analyzers (the present study used an QqTOF while in the study of Jewell et al a linear ion trap-orbitrap mass spectrometer was used) mass accuracy, spectral accuracy and comparison of MS/MS spectrum and in silico fragmentation suggests that the most likely structure of OP290 is isomer E or (2,4-diaminopyrimidin-5-yl)-(4-hydroxy-3,5-dimethoxyphenyl)methanone.…”

Section: Electrochemically-assisted Fenton Reactionmentioning

confidence: 87%

Electrochemistry-High Resolution Mass Spectrometry to Study Oxidation Products of Trimethoprim

et al. 2018

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Abstract:The study of the fate of emerging organic contaminants (EOCs), especially the identification of transformation products, after water treatment or in the aquatic environment, is a topic of growing interest. In recent years, electrochemistry coupled to mass spectrometry has attracted a lot of attention as an alternative technique to investigate oxidation metabolites of organic compounds. The present study used different electrochemical approaches, such as cyclic voltammetry, electrolysis, electro-assisted Fenton reaction coupled offline to high resolution mass spectrometry and thin-layer flow cell coupled online to high resolution mass spectrometry, to study oxidation products of the anti-infective trimethoprim, a contaminant of emerging concern frequently reported in wastewaters and surface waters. Results showed that mono-and di-hydroxylated derivatives of trimethoprim were generated in electrochemically and possibly tri-hydroxylated derivatives as well. Those compounds have been previously reported as mammalian and bacterial metabolites as well as transformation products of advance oxidation processes applied to waters containing trimethoprim. Therefore, this study confirmed that electrochemical techniques are relevant not only to mimic specific biotransformation reactions of organic contaminants, as it has been suggested previously, but also to study the oxidation reactions of organic contaminants of interest in water treatment. The key role that redox reactions play in the environment make electrochemistry-high resolution mass spectrometry a sensitive and simple technique to improve our understanding of the fate of organic contaminants in the environment.

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“…However, previous reports on the effect of initial concentrations on biotransformation pathways of pharmaceuticals were contradictory. The same degradation route was reported on trimethoprim by nitrifying activated sludge with two metabolites produced at initial concentrations of 20 mg L -1 and 20 µg L -1 whereas different biotransformation products were found under different spiked concentration (500 µg L -1 and 5 µg L -1 ) in another study (Eichhorn et al, 2005;Jewell et al, 2016). This discrepancy might be due to the properties of the activated sludge and the dominant microorganisms in different studies, which deserve further research.…”

Section: This Section Summarises the Findings Of The Work Described Isupporting

confidence: 59%

“…Two metabolites were formed and the degradation route was independent on the initial concentration of trimethoprim (20 mg L -1 or 20 µg L -1 ). However, biodegradation of trimethoprim was also investigated by nitrifying activated sludge in another recent study (Jewell et al, 2016), resulting in different biotransformation products under different spiked concentration of trimethoprim (500 µg L -1 or 5 µg L -1 ). From the mass balance analysis, carboxy-acyclovir seems to be the only product by heterotrophs either in higher initial concentration or lower initial concentration of acyclovir.…”

Section: Discussionmentioning

confidence: 99%

Understanding the biodegradation products and pathways of selected pharmaceuticals atenolol and acyclovir by an enriched nitrifying sludge through experiments and modeling

Xu¹

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Pharmaceuticals could potentially pose detrimental effects on aquatic ecosystems and human health, with wastewater treatment being one of the major pathways for pharmaceuticals to enter into the environment. Enhanced removal of pharmaceuticals has been widely observed by ammonia oxidizing bacteria (AOB). However, the degradation mechanisms involved in pharmaceutical biotransformation were still ambiguous. In addition, pharmaceutical biotransformation models have not yet considered transformation products associated with the metabolic type of microorganisms. The overall objective of this thesis is to understand the contribution of different metabolisms by relevant microorganisms to the biotransformation of selected pharmaceuticals (i.e., atenolol and acyclovir) accompanied with the formation of their transformation products in an enriched nitrifying sludge, in terms of product identification, influencing factor assessment and mathematical modeling.Biodegradation of atenolol in an enriched nitrifying sludge was studied under different metabolic conditions. The positive link was observed between atenolol biodegradation and the cometabolic activity of AOB in the presence of ammonium, likely due to a broad substrate spectrum of ammonia monooxygenase (AMO). In the presence of ammonium, atenolol was transformed into P267 (atenolol acid) and three new products including P117(1-isopropylamino-2-propanol), P167 (1-amino-3-phenoxy-2-propanol), and an unknown product P227. However, atenolol was only transformed to P267 and P227 in the absence of ammonium. The formation of P117, P167 and P227 was further confirmed from follow-up atenolol acid biodegradation experiments in the presence of ammonium. Therefore, a tentative biodegradation pathway of atenolol is proposed in the enriched nitrifying sludge, consisting of two steps regardless of the presence of ammonium: i) microbial amide-bond hydrolysis to carboxyl group, producing P267 and ii) a possible formation of P227 and other two cometabolically induced reactions: iii) breakage of ether bond in the alkyl side chain to produce P117 and iv) a minor pathway through N-dealkylation and loss of acetamide moiety from the aromatic ring, yielding P167. An important insight was herein provided regarding the biotransformation pathways of pharmaceuticals under different metabolic conditions.To further assess the influence of the growth substrate on atenolol biotransformation in enriched nitrifying culture, different ammonium concentrations were applied constantly to study atenolol degradation kinetics and the biotransformation product formation dynamics.Higher ammonium concentrations led to the lower atenolol removal efficiencies probably II due to the substrate competition between ammonium and atenolol. The formation of biotransformation product atenolol acid was positively related to the ammonium oxidation activity, resulting in a higher amount of atenolol acid at the end of experiments at higher ammonium concentrations. Positive correlations between ammonia oxidation rate an...

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New insights into the transformation of trimethoprim during biological wastewater treatment

Cited by 96 publications

References 30 publications

Effect of sulfadiazine and trimethoprim on activated sludge performance and microbial community dynamics in laboratory‐scale membrane bioreactors and sequencing batch reactors at 8°C

Effect of sulfadiazine and trimethoprim on activated sludge performance and microbial community dynamics in laboratory‐scale membrane bioreactors and sequencing batch reactors at 8°C

Electrochemistry-High Resolution Mass Spectrometry to Study Oxidation Products of Trimethoprim

Understanding the biodegradation products and pathways of selected pharmaceuticals atenolol and acyclovir by an enriched nitrifying sludge through experiments and modeling

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