Future water quality monitoring--adapting tools to deal with mixtures of pollutants in water resource management

Rolf Altenburger; Selim Ait-Aissa; Philipp Antczak; Thomas Backhaus; Damià Barceló; Thomas-Benjamin Seiler; Francois Brion; Wibke Busch; Kevin Chipman; Miren López de Alda; Gisela de Aragão Umbuzeiro; Beate I Escher; Francesco Falciani; Michael Faust; Andreas Focks; Klara Hilscherova; Juliane Hollender; Henner Hollert; Felix Jäger; Annika Jahnke; Andreas Kortenkamp; Martin Krauss; Gregory F Lemkine; John Munthe; Steffen Neumann; Emma L Schymanski; Mark Scrimshaw; Helmut Segner; Jaroslav Slobodnik; Foppe Smedes; Subramaniam Kughathas; Ivana Teodorovic; Andrew J Tindall; Knut Erik Tollefsen; Karl-Heinz Walz; Timothy Williams; Paul J Van den Brink; Jos van Gils; Branislav Vrana; Xiaowei Zhang; Werner Brack

doi:10.1016/j.scitotenv.2014.12.057

Future water quality monitoring--adapting tools to deal with mixtures of pollutants in water resource management

Rolf Altenburger, Selim Ait-Aissa, Philipp Antczak, Thomas Backhaus, Damià Barceló, Thomas-Benjamin Seiler, Francois Brion, Wibke Busch, Kevin Chipman, Miren López de Alda, Gisela de Aragão Umbuzeiro, Beate I Escher, Francesco Falciani, Michael Faust, Andreas Focks, Klara Hilscherova, Juliane Hollender, Henner Hollert, Felix Jäger, Annika JahnkeAndreas Kortenkamp, Martin Krauss, Gregory F Lemkine, John Munthe, Steffen Neumann, Emma L Schymanski, Mark Scrimshaw, Helmut Segner, Jaroslav Slobodnik, Foppe Smedes, Subramaniam Kughathas, Ivana Teodorovic, Andrew J Tindall, Knut Erik Tollefsen, Karl-Heinz Walz, Timothy Williams, Paul J Van den Brink, Jos van Gils, Branislav Vrana, Xiaowei Zhang, Werner Brack

Biosciences

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Abstract

Environmental quality monitoring of water resources is challenged with providing the basis for safeguarding the environment against adverse biological effects of anthropogenic chemical contamination from diffuse and point sources. While current regulatory efforts focus on monitoring and assessing a few legacy chemicals, many more anthropogenic chemicals can be detected simultaneously in our aquatic resources. However, exposure to chemical mixtures does not necessarily translate into adverse biological effects nor clearly shows whether mitigation measures are needed. Thus, the question which mixtures are present and which have associated combined effects becomes central for defining adequate monitoring and assessment strategies. Here we describe the vision of the international, EU-funded project SOLUTIONS, where three routes are explored to link the occurrence of chemical mixtures at specific sites to the assessment of adverse biological combination effects. First of all, multi-residue target and non-target screening techniques covering a broader range of anticipated chemicals co-occurring in the environment are being developed. By improving sensitivity and detection limits for known bioactive compounds of concern, new analytical chemistry data for multiple components can be obtained and used to characterise priority mixtures. This information on chemical occurrence will be used to predict mixture toxicity and to derive combined effect estimates suitable for advancing environmental quality standards. Secondly, bioanalytical tools will be explored to provide aggregate bioactivity measures integrating all components that produce common (adverse) outcomes even for mixtures of varying compositions. The ambition is to provide comprehensive arrays of effect-based tools and trait-based field observations that link multiple chemical exposures to various environmental protection goals more directly and to provide improved in situ observations for impact assessment of mixtures. Thirdly, effect-directed analysis (EDA) will be applied to identify major drivers of mixture toxicity. Refinements of EDA include the use of statistical approaches with monitoring information for guidance of experimental EDA studies. These three approaches will be explored using case studies at the Danube and Rhine river basins as well as rivers of the Iberian Peninsula. The synthesis of findings will be organised to provide guidance for future solution-oriented environmental monitoring and explore more systematic ways to assess mixture exposures and combination effects in future water quality monitoring.

Original language	English
Pages (from-to)	540-51
Number of pages	12
Journal	Science of the Total Environment
Volume	512-513
Early online date	31 Jan 2015
DOIs	https://doi.org/10.1016/j.scitotenv.2014.12.057
Publication status	Published - 15 Apr 2015

Bibliographical note

Keywords

Conservation of Natural Resources
Environmental Monitoring
Water Pollutants, Chemical
Water Quality
Water Resources

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10.1016/j.scitotenv.2014.12.057

Altenburger_et_al_Future_water_quality_Science_Total_Environment_2015_Post-Print
NOTICE: this is the author’s version of a work that was accepted for publication in Science of the Total Environment. Changes resulting from the publishing process, such as peer review, editing, corrections, structural formatting, and other quality control mechanisms may not be reflected in this document. Changes may have been made to this work since it was submitted for publication. A definitive version was subsequently published in Science of the Total Environment, Vol 512-3, 2015. DOI: 10.1016/j.scitotenv.2014.12.057 Eligibility for repository checked
Accepted author manuscript, 563 KBLicence: Creative Commons: Attribution-NonCommercial-NoDerivs (CC BY-NC-ND)

Cite this

Altenburger, R., Ait-Aissa, S., Antczak, P., Backhaus, T., Barceló, D., Seiler, T-B., Brion, F., Busch, W., Chipman, K., López de Alda, M., Umbuzeiro, G. D. A., Escher, B. I., Falciani, F., Faust, M., Focks, A., Hilscherova, K., Hollender, J., Hollert, H., Jäger, F., ... Brack, W. (2015). Future water quality monitoring--adapting tools to deal with mixtures of pollutants in water resource management. Science of the Total Environment, 512-513, 540-51. Advance online publication. https://doi.org/10.1016/j.scitotenv.2014.12.057

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abstract = "Environmental quality monitoring of water resources is challenged with providing the basis for safeguarding the environment against adverse biological effects of anthropogenic chemical contamination from diffuse and point sources. While current regulatory efforts focus on monitoring and assessing a few legacy chemicals, many more anthropogenic chemicals can be detected simultaneously in our aquatic resources. However, exposure to chemical mixtures does not necessarily translate into adverse biological effects nor clearly shows whether mitigation measures are needed. Thus, the question which mixtures are present and which have associated combined effects becomes central for defining adequate monitoring and assessment strategies. Here we describe the vision of the international, EU-funded project SOLUTIONS, where three routes are explored to link the occurrence of chemical mixtures at specific sites to the assessment of adverse biological combination effects. First of all, multi-residue target and non-target screening techniques covering a broader range of anticipated chemicals co-occurring in the environment are being developed. By improving sensitivity and detection limits for known bioactive compounds of concern, new analytical chemistry data for multiple components can be obtained and used to characterise priority mixtures. This information on chemical occurrence will be used to predict mixture toxicity and to derive combined effect estimates suitable for advancing environmental quality standards. Secondly, bioanalytical tools will be explored to provide aggregate bioactivity measures integrating all components that produce common (adverse) outcomes even for mixtures of varying compositions. The ambition is to provide comprehensive arrays of effect-based tools and trait-based field observations that link multiple chemical exposures to various environmental protection goals more directly and to provide improved in situ observations for impact assessment of mixtures. Thirdly, effect-directed analysis (EDA) will be applied to identify major drivers of mixture toxicity. Refinements of EDA include the use of statistical approaches with monitoring information for guidance of experimental EDA studies. These three approaches will be explored using case studies at the Danube and Rhine river basins as well as rivers of the Iberian Peninsula. The synthesis of findings will be organised to provide guidance for future solution-oriented environmental monitoring and explore more systematic ways to assess mixture exposures and combination effects in future water quality monitoring.",

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Altenburger, R, Ait-Aissa, S, Antczak, P, Backhaus, T, Barceló, D, Seiler, T-B, Brion, F, Busch, W, Chipman, K, López de Alda, M, Umbuzeiro, GDA, Escher, BI, Falciani, F, Faust, M, Focks, A, Hilscherova, K, Hollender, J, Hollert, H, Jäger, F, Jahnke, A, Kortenkamp, A, Krauss, M, Lemkine, GF, Munthe, J, Neumann, S, Schymanski, EL, Scrimshaw, M, Segner, H, Slobodnik, J, Smedes, F, Kughathas, S, Teodorovic, I, Tindall, AJ, Tollefsen, KE, Walz, K-H, Williams, T, Van den Brink, PJ, van Gils, J, Vrana, B, Zhang, X & Brack, W 2015, 'Future water quality monitoring--adapting tools to deal with mixtures of pollutants in water resource management', Science of the Total Environment, vol. 512-513, pp. 540-51. https://doi.org/10.1016/j.scitotenv.2014.12.057

TY - JOUR

T1 - Future water quality monitoring--adapting tools to deal with mixtures of pollutants in water resource management

AU - Altenburger, Rolf

AU - Ait-Aissa, Selim

AU - Antczak, Philipp

AU - Backhaus, Thomas

AU - Barceló, Damià

AU - Seiler, Thomas-Benjamin

AU - Brion, Francois

AU - Busch, Wibke

AU - Chipman, Kevin

AU - López de Alda, Miren

AU - Umbuzeiro, Gisela de Aragão

AU - Escher, Beate I

AU - Falciani, Francesco

AU - Faust, Michael

AU - Focks, Andreas

AU - Hilscherova, Klara

AU - Hollender, Juliane

AU - Hollert, Henner

AU - Jäger, Felix

AU - Jahnke, Annika

AU - Kortenkamp, Andreas

AU - Krauss, Martin

AU - Lemkine, Gregory F

AU - Munthe, John

AU - Neumann, Steffen

AU - Schymanski, Emma L

AU - Scrimshaw, Mark

AU - Segner, Helmut

AU - Slobodnik, Jaroslav

AU - Smedes, Foppe

AU - Kughathas, Subramaniam

AU - Teodorovic, Ivana

AU - Tindall, Andrew J

AU - Tollefsen, Knut Erik

AU - Walz, Karl-Heinz

AU - Williams, Timothy

AU - Van den Brink, Paul J

AU - van Gils, Jos

AU - Vrana, Branislav

AU - Zhang, Xiaowei

AU - Brack, Werner

PY - 2015/4/15

Y1 - 2015/4/15

N2 - Environmental quality monitoring of water resources is challenged with providing the basis for safeguarding the environment against adverse biological effects of anthropogenic chemical contamination from diffuse and point sources. While current regulatory efforts focus on monitoring and assessing a few legacy chemicals, many more anthropogenic chemicals can be detected simultaneously in our aquatic resources. However, exposure to chemical mixtures does not necessarily translate into adverse biological effects nor clearly shows whether mitigation measures are needed. Thus, the question which mixtures are present and which have associated combined effects becomes central for defining adequate monitoring and assessment strategies. Here we describe the vision of the international, EU-funded project SOLUTIONS, where three routes are explored to link the occurrence of chemical mixtures at specific sites to the assessment of adverse biological combination effects. First of all, multi-residue target and non-target screening techniques covering a broader range of anticipated chemicals co-occurring in the environment are being developed. By improving sensitivity and detection limits for known bioactive compounds of concern, new analytical chemistry data for multiple components can be obtained and used to characterise priority mixtures. This information on chemical occurrence will be used to predict mixture toxicity and to derive combined effect estimates suitable for advancing environmental quality standards. Secondly, bioanalytical tools will be explored to provide aggregate bioactivity measures integrating all components that produce common (adverse) outcomes even for mixtures of varying compositions. The ambition is to provide comprehensive arrays of effect-based tools and trait-based field observations that link multiple chemical exposures to various environmental protection goals more directly and to provide improved in situ observations for impact assessment of mixtures. Thirdly, effect-directed analysis (EDA) will be applied to identify major drivers of mixture toxicity. Refinements of EDA include the use of statistical approaches with monitoring information for guidance of experimental EDA studies. These three approaches will be explored using case studies at the Danube and Rhine river basins as well as rivers of the Iberian Peninsula. The synthesis of findings will be organised to provide guidance for future solution-oriented environmental monitoring and explore more systematic ways to assess mixture exposures and combination effects in future water quality monitoring.

AB - Environmental quality monitoring of water resources is challenged with providing the basis for safeguarding the environment against adverse biological effects of anthropogenic chemical contamination from diffuse and point sources. While current regulatory efforts focus on monitoring and assessing a few legacy chemicals, many more anthropogenic chemicals can be detected simultaneously in our aquatic resources. However, exposure to chemical mixtures does not necessarily translate into adverse biological effects nor clearly shows whether mitigation measures are needed. Thus, the question which mixtures are present and which have associated combined effects becomes central for defining adequate monitoring and assessment strategies. Here we describe the vision of the international, EU-funded project SOLUTIONS, where three routes are explored to link the occurrence of chemical mixtures at specific sites to the assessment of adverse biological combination effects. First of all, multi-residue target and non-target screening techniques covering a broader range of anticipated chemicals co-occurring in the environment are being developed. By improving sensitivity and detection limits for known bioactive compounds of concern, new analytical chemistry data for multiple components can be obtained and used to characterise priority mixtures. This information on chemical occurrence will be used to predict mixture toxicity and to derive combined effect estimates suitable for advancing environmental quality standards. Secondly, bioanalytical tools will be explored to provide aggregate bioactivity measures integrating all components that produce common (adverse) outcomes even for mixtures of varying compositions. The ambition is to provide comprehensive arrays of effect-based tools and trait-based field observations that link multiple chemical exposures to various environmental protection goals more directly and to provide improved in situ observations for impact assessment of mixtures. Thirdly, effect-directed analysis (EDA) will be applied to identify major drivers of mixture toxicity. Refinements of EDA include the use of statistical approaches with monitoring information for guidance of experimental EDA studies. These three approaches will be explored using case studies at the Danube and Rhine river basins as well as rivers of the Iberian Peninsula. The synthesis of findings will be organised to provide guidance for future solution-oriented environmental monitoring and explore more systematic ways to assess mixture exposures and combination effects in future water quality monitoring.

KW - Conservation of Natural Resources

KW - Environmental Monitoring

KW - Water Pollutants, Chemical

KW - Water Quality

KW - Water Resources

U2 - 10.1016/j.scitotenv.2014.12.057

DO - 10.1016/j.scitotenv.2014.12.057

M3 - Article

C2 - 25644849

SN - 0048-9697

VL - 512-513

SP - 540

EP - 551

JO - Science of the Total Environment

JF - Science of the Total Environment

ER -

Future water quality monitoring--adapting tools to deal with mixtures of pollutants in water resource management

Abstract

Bibliographical note

Keywords

Access to Document

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