Aquatic environments are often contaminated with complex mixtures of chemicals that may pose a risk to ecosystems and human health. This contamination cannot be addressed with target analysis alone but tools are required to reduce this complexity and identify those chemicals that might cause adverse effects. Effect-directed analysis (EDA) is designed to meet this challenge and faces increasing interest in water and sediment quality monitoring. Thus, the present paper summarizes current experience with the EDA approach and the tools required, and provides practical advice on their application. The paper highlights the need for proper problem formulation and gives general advice for study design. As the EDA approach is directed by toxicity, basic principles for the selection of bioassays are given as well as a comprehensive compilation of appropriate assays, including their strengths and weaknesses. A specific focus is given to strategies for sampling, extraction and bioassay dosing since they strongly impact prioritization of toxicants in EDA. Reduction of sample complexity mainly relies on fractionation procedures, which are discussed in this paper, including quality assurance and quality control. Automated combinations of fractionation, biotesting and chemical analysis using so-called hyphenated tools can enhance the throughput and might reduce the risk of artifacts in laboratory work. The key to determining the chemical structures causing effects is analytical toxicant identification. The latest approaches, tools, software and databases for target-, suspect and non-target screening as well as unknown identification are discussed together with analytical and toxicological confirmation approaches. A better understanding of optimal use and combination of EDA tools will help to design efficient and successful toxicant identification studies in the context of quality monitoring in multiply stressed environments.

Eawag Swiss Federal Institute of Aquatic Science and Technology 8600 Dübendorf Switzerland

Institut National de l'Environnement Industriel et des Risques INERIS BP2 60550 Verneuil en Halatte France

Leibniz Institute of Plant Biochemistry Halle Germany

Masaryk University Research Centre for Toxic Compounds in the Environment Kamenice 753 5 625 00 Brno Czech Republic

NILU Norwegian Institute for Air Research Instituttveien 18 2007 Kjeller Norway

RWTH Aachen University Worringerweg 1 52074 Aachen Germany

UFZ Helmholtz Centre for Environmental Research Permoserstraße 15 04318 Leipzig Germany

UFZ Helmholtz Centre for Environmental Research Permoserstraße 15 04318 Leipzig Germany; Eberhard Karls University Tübingen 72074 Tübingen Germany

UFZ Helmholtz Centre for Environmental Research Permoserstraße 15 04318 Leipzig Germany; RWTH Aachen University Worringerweg 1 52074 Aachen Germany

University of Campinas Limeira Brazil

US Environmental Protection Agency Office of Research and Development National Health and Environmental Effects Research Laboratory Atlantic Ecology Division Narragansett RI USA

VU Amsterdam Institute for Environmental Studies Amsterdam The Netherlands

VU University BioMolecular Analysis Group Amsterdam The Netherlands

WatchFrag Bâtiment Genavenir 3 1 Rue Pierre Fontaine 91000 Evry France

Water Science and Technology Directorate Environment Canada 867 Lakeshore Road Burlington Ontario L7S 1A1 Canada

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