BACKGROUND: Rivers receive water and associated organic micropollutants from their entire catchment, including from urban, agricultural and natural sources, and constitute an important environmental component for catalyzing pollutant turnover. Environmental removal processes were extensively investigated under laboratory conditions in the past but there is still a lack of information on how organic micropollutants attenuate on the catchment scale. The aim of this study was to describe the chemical and toxicological profile of a 4th order river and to characterize in-stream processes. We propose indicator chemicals and indicator in vitro bioassays as screening methods to evaluate micropollutant input and transport and transformation processes of the chemical burden in a river. Carbamazepine and sulfamethoxazole were selected as indicators for dilution processes and the moderately degradable chemicals tramadol and sotalol as indicators for potential in-stream attenuation processes. The battery of bioassays covers seven environmentally relevant modes of action, namely estrogenicity, glucocorticogenic activity, androgenicity progestagenic activity and oxidative stress response, as well as activation of the peroxisome proliferator-activated receptor and the aryl hydrocarbon receptor, using the GeneBLAzer test battery and the AhR-CALUX and AREc32 assays. RESULTS: Both approaches, targeted chemical analysis and in vitro bioassays, identified a wastewater treatment plant (WWTP) as a major input source of organic micropollutants that dominantly influenced the water quality of the river. Downstream of the WWTP the amount of detected chemicals and biological effects decreased along the river flow. The organic indicator chemicals of known degradability uncovered dilution and potential loss processes in certain river stretches. The average cytotoxic potency of the river water decreased in a similar fashion as compounds of medium degradability such as the pharmaceutical sotalol. CONCLUSIONS: This study showed that the indicator chemical/indicator bioassay approach is suitable for identifying input sources of a mixture of organic micropollutants and to trace changes in the water quality along small rivers. This method forms the necessary basis for evaluating the natural attenuation processes of organic micropollutants on a catchment scale, especially when combined with enhanced sampling strategies in future studies.
BACKGROUND: Rivers receive water and associated organic micropollutants from their entire catchment, including from urban, agricultural and natural sources, and constitute an important environmental component for catalyzing pollutant turnover. Environmental removal processes were extensively investigated under laboratory conditions in the past but there is still a lack of information on how organic micropollutants attenuate on the catchment scale. The aim of this study was to describe the chemical and toxicological profile of a 4th order river and to characterize in-stream processes. We propose indicator chemicals and indicator in vitro bioassays as screening methods to evaluate micropollutant input and transport and transformation processes of the chemical burden in a river. Carbamazepine and sulfamethoxazole were selected as indicators for dilution processes and the moderately degradable chemicals tramadol and sotalol as indicators for potential in-stream attenuation processes. The battery of bioassays covers seven environmentally relevant modes of action, namely estrogenicity, glucocorticogenic activity, androgenicity progestagenic activity and oxidative stress response, as well as activation of the peroxisome proliferator-activated receptor and the aryl hydrocarbon receptor, using the GeneBLAzer test battery and the AhR-CALUX and AREc32 assays. RESULTS: Both approaches, targeted chemical analysis and in vitro bioassays, identified a wastewater treatment plant (WWTP) as a major input source of organic micropollutants that dominantly influenced the water quality of the river. Downstream of the WWTP the amount of detected chemicals and biological effects decreased along the river flow. The organic indicator chemicals of known degradability uncovered dilution and potential loss processes in certain river stretches. The average cytotoxic potency of the river water decreased in a similar fashion as compounds of medium degradability such as the pharmaceutical sotalol. CONCLUSIONS: This study showed that the indicator chemical/indicator bioassay approach is suitable for identifying input sources of a mixture of organic micropollutants and to trace changes in the water quality along small rivers. This method forms the necessary basis for evaluating the natural attenuation processes of organic micropollutants on a catchment scale, especially when combined with enhanced sampling strategies in future studies.
Authors: Christian W Götz; Christian Stamm; Kathrin Fenner; Heinz Singer; Michael Schärer; Juliane Hollender Journal: Environ Sci Pollut Res Int Date: 2009-05-28 Impact factor: 4.223
Authors: Beate I Escher; Mayumi Allinson; Rolf Altenburger; Peter A Bain; Patrick Balaguer; Wibke Busch; Jordan Crago; Nancy D Denslow; Elke Dopp; Klara Hilscherova; Andrew R Humpage; Anu Kumar; Marina Grimaldi; B Sumith Jayasinghe; Barbora Jarosova; Ai Jia; Sergei Makarov; Keith A Maruya; Alex Medvedev; Alvine C Mehinto; Jamie E Mendez; Anita Poulsen; Erik Prochazka; Jessica Richard; Andrea Schifferli; Daniel Schlenk; Stefan Scholz; Fujio Shiraishi; Shane Snyder; Guanyong Su; Janet Y M Tang; Bart van der Burg; Sander C van der Linden; Inge Werner; Sandy D Westerheide; Chris K C Wong; Min Yang; Bonnie H Y Yeung; Xiaowei Zhang; Frederic D L Leusch Journal: Environ Sci Technol Date: 2013-12-26 Impact factor: 9.028
Authors: Beate I Escher; Selim Aїt-Aїssa; Peter A Behnisch; Werner Brack; François Brion; Abraham Brouwer; Sebastian Buchinger; Sarah E Crawford; David Du Pasquier; Timo Hamers; Karina Hettwer; Klára Hilscherová; Henner Hollert; Robert Kase; Cornelia Kienle; Andrew J Tindall; Jochen Tuerk; Ron van der Oost; Etienne Vermeirssen; Peta A Neale Journal: Sci Total Environ Date: 2018-02-20 Impact factor: 7.963