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Die Gefährdung von Auen mit ihren typischen Vegetationsgesellschaften beruht vor allem auf dem Ausbau der Flüsse zu Wasserstraßen, einhergehend mit dem Bau von Dämmen, Staustufen, Deichen und Uferbefestigungen. Der Ausbau der Wasserstraßen hat weitreichende Konsequenzen für die Hydrodynamik des Flusses, die Geomorphologie und die hydrologischen Bedingungen in der Aue. Ein Lebensraumtypus, der dabei in besonderem Maße betroffen ist, sind die Weichholzauen. Während vor wenigen Jahrhunderten die Vorländer der Elbe noch größere Bestände von Weichholz- und Hartholzauen aufwiesen, ist das heutige Landschaftsbild vor allem durch extensiv genutzte Grünländer geprägt. Weichholzauenwälder sind als prioritär zu schützender, natürlicher Lebensraumtyp eingestuft und besitzen eine besondere Schutz- und Entwicklungsbedürftigkeit. Weichholzauenwälder bieten nicht nur Lebensraum für viele seltene Tier- und Pflanzenarten, sie beeinflussen auch den Nährstoffkreislauf innerhalb der Aue, haben einen wichtigen Einfluss auf die Wasserqualität und stabilisieren Ufer- und Vorlandbereiche. Zudem dienen sie als Retentionsraum und können damit zum Hochwasserschutz beitragen. Vor diesem Hintergrund förderte die Deutsche Bundesstiftung Umwelt (DBU) das interdisziplinäre Projekt „KoWeB – Konzept zur Weichholzauen- Entwicklung als Beitrag zum naturverträglichen Hochwasserschutz an Bundeswasserstraßen“ in der Laufzeit 2006 bis 2009. Das Ziel war die Entwicklung einer praxistauglichen Methode zur Identifizierung von Flächen zur Ansiedlung von Weichholzauen in Überschwemmungsgebieten unter Beachtung der ökologischen Kriterien und der Hochwasserneutralität.
In almost all parts of the world the industrialisation grows continuously and thus, the chemical pollution of natural waters has become a major public concern. A major consequence and one of the key environmental problems we are facing today is the increasing contamination of freshwater systems with chemicals. The chemicals are detected in wastewater, surface (river) water, ground water and drinking water ubiquitously in natural waters and not only in industrialised areas. The main point sources for water pollution and the release of these synthetic organic substances of human origin, so called micropollutants (MPs), are wastewater treatment plants (WWTPs). These MPs such as pharmaceuticals, personal care products, disinfectant chemicals, chemicals used in the industry and in households, contraceptives, hormones, food additives, artificial sweeteners, pesticides, biocides, and many emerging contaminants are only incompletely removed by the existing conventional wastewater treatment technologies. The MPs end up in the water cycle and have adverse effects on wildlife aquatic ecosystems and human health even at very low concentrations. Therefore, advanced wastewater treatment (AWWT) technologies, such as ozonation, treatment with activated carbon, biofiltration, membrane bioreactors (MBRs) or exposure to ultraviolet light are investigated as options to upgrade conventional WWTPs. However, several studies show that especially the ozonation of wastewater generates diverse transformation products (TPs) with unknown properties. These TPs could be more toxic than the mother compound. Thus, a post-treatment after the ozonation process is required.
The present thesis was part of the BMBF-funded TransRisk project dealing with “the characterisation, communication, and minimisation of risks of emerging pollutants and pathogens in the water cycle”. One main objective was the investigation of conventional treated wastewater after a full-scale ozonation with four post-treatments (each non-aerated and aerated granular activated carbon (GAC) filtration and biofiltration) in comparison to a MBR treatment of raw (untreated) wastewater separately and in combination with an additional ozonation on a pilot WWTP. For this purpose, the wastewater samples were characterised with a comprehensive battery of in vitro and in vivo bioassays. The in vitro bioassays were performed to detect endocrine activities (such as (anti)estrogenic and (anti)androgenic activities), genotoxicity, and mutagenicity. The results showed a decreased estrogenic activity due to the conventional wastewater treatment as well as the ozonation, but a distinct increase of the anti-estrogenic activity and the mutagenicity in the ozonated wastewater, possibly caused by new formed TPs, that were reduced after the post-treatments whereas the GAC filtration performed better than the biofiltration. The in vivo bioassays included for example the impact of the wastewater on mortality, reproduction, development, and energy reserves of the test organisms. The in vivo on-site tests with the mudsnail Potamopyrgus antipodarum and with the amphipod Gammarus fossarum indicated a major impact of conventional treated wastewater, ozonated wastewater, and MBR treated wastewater. The flow channel experiments in the laboratory with Gammarus pulex pointed to a serious impact of an estrogenic effluent on life-history traits of the amphipod. Finally, an ozonation of the wastewater with subsequent GAC filtration represented the most promising option. In addition, chemical analyses of 40 selected MPs, so called tracer substances, performed in parallel to the in vitro and in vivo bioassays underlined this assumption.
A second main objective was the optimisation of the preparation of water and wastewater samples for ecotoxicological in vitro bioassays because common sample preparation techniques are predominantly adapted for chemical analyses. Therefore, the impact of sample filtration, long-term acidification with following neutralisation as well as the enrichment with solid phase extraction (SPE) in combination with short-term acidification were investigated using amongst others raw (untreated) wastewater, hospital wastewater, conventional treated and ozonated wastewater, surface water, and ground water. Overall, eleven in vitro bioassays were performed for the detection of endocrine activities, genotoxicity, and mutagenicity. The results show that sample filtration and acidification/neutralisation significantly affected the outcome of the bioassays especially the anti-estrogenic activity and the mutagenicity whereas the sample filtration had a minor impact than the acidification. Thus, the testing of untreated (waste)water samples is advisable because the sample is minimally processed. Furthermore, the SPE extracts showed in parts high cytotoxic effects whereby no conclusions on the results of the bioassays were possible. However, the enrichment of endocrine activity and mutagenicity was predominantly effective but depended on the used SPE cartridge and the pH value of the (waste)water samples. Based on the results the use of a Telos C18/ENV cartridge and an acidified sample is recommendable. In the end, there is a need to optimise the sample preparation for in vitro bioassays to reach their maximum outcome for the best possible assessment of the water quality.