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Agricultural pesticides, especially insecticides, are an integral part of modern farming. However, these may often leave their target ecosystems and cause adverse effects in non- target, especially freshwater ecosystems, leading to their deterioration. In this thesis, the focus will be on Insect Growth Regulators (IGRs) that can in many ways cause disruption of the endocrine system of invertebrates. Freshwater invertebrates play important ecological, economic and medical roles, and disruption of their endocrine systems may be crucial, considering the important role hormones play in the developmental and reproductive processes in organisms. Although Endocrine Disruption Chemicals (EDCs) can affect moulting, behaviour, morphology, sexual maturity, time to first brood, egg development time, brood size (fecundity), and sex determination in invertebrates, there is currently no agreement upon how to characterize and assess endocrine disruption (ED). Current traditional ecotoxicity tests for Ecological Risk Assessment (ERA) show limitations on generating data at the population level that may be relevant for the assessment of EDCs, which effects may be sublethal, latent and persist for several generations of species (transgenerational).
It is therefore the primary objective of this thesis to use a test method to investigate adverse effects of EDCs on endpoints concerning development and reproduction in freshwater invertebrates. The full life-cycle test over two generations that includes all sensitive life stages of C. riparius (a sexual reproductive organism) allows an assessment of its reproduction and should be suitable for the investigation of long-term toxicity of EDCs in freshwater invertebrates. C. riparius is appropriate for this purpose because of its short life cycle that enables the assessment of functional endpoints of the organism over several generations. Moreover, the chironomid life cycle consists of a complete metamorphosis controlled by a well-known endocrine mechanism and the endocrine system of insects has been most investigated in great detail among invertebrates. Hence, the full life-cycle test with C. riparius provides an approach to assess functional endpoints (e.g. reproduction, sex ratio) that are population-relevant as a useful amendment to the ERA of EDCs. In the laboratory, C. riparius was exposed to environmentally-relevant concentrations of the selected IGRs in either spiked water or spiked sediment scenario over two subsequent generations.
The results reported in this thesis revealed significant effects of the IGRs on the development and the reproduction of C. riparius with the second (F1) generation showing greater sensitivity. These findings indicated for the first time the suitability of multigenerational testing for various groups of EDCs and strongly suggested considering the full life-cycle of C. riparius as an appropriate test method for a better assessment of EDCs in the freshwater environment. In conclusion, this thesis helps to detect additional information that can be extrapolated at population level and, thus, might contribute to better protection of freshwater ecosystems against the risks of Endocrine Disrupting Chemicals (EDCs.) It may furthermore contribute to changes in the ERA process that are necessary for a real implementation of the new European chemical legislation, REACH (Registration, Evaluation Authorization and Restriction of Chemicals). Finally, significant interactions between temperature, chemical exposure and generation were reported for the first time and, may help predict impacts that may occur in the future, in the field, under predicted climate change scenarios.
In einem Großteil der Welt wird Grundwasser für die Versorgung von Siedlungen und Agrarflächen genutzt. Organismen, die im Grundwasser leben, erfüllen wichtige Funktionen im Ökosystem und haben positiven Einfluss auf die Grundwasserqualität. Um das Risiko negativer Effekte auf diese wertvollen Ökosysteme zu minimieren muss die entsprechende Sanierungsmethode, im Falle einer Grundwasserbehandlung, mit Vorsicht gewählt werden. In der vorliegenden Thesis wurde das Umweltrisiko von Carbo-Iron untersucht, ein Komposit aus nanoskaligem null-valentem Eisen und Aktivkohle zur in situ-Behandlung von Grundwasser. Des Weiteren wurde eine umfassende Beurteilung des Umweltrisikos und des Nutzens einer Grundwasserbehandlung mit Carbo-Iron durchgeführt.
Zu Beginn der Arbeit an der vorliegenden Thesis existierten noch keine Empfehlungen für Untersuchung der Ökotoxizität von Nanomaterialien. Daher bestanden viele Unsicherheiten hinsichtlich geeigneter Methoden. Im Rahmen dieser Thesis wurde eine Entscheidungshilfe entwickelt, um bei der ökotoxikologischen Untersuchung von Nanomaterialien systematisch geeignete methodische Schritte auszuwählen.
Mögliche Effekte von Carbo-Iron wurden in Tests mit embryonalen, juvenilen und adulten Lebensstadien des Zebrabärblings (Danio rerio) und juvenilen und adulten Amphipoden (Hyalella azteca) untersucht. Die gewählten Testsysteme basierten auf existierenden Testmethoden der OECD und EPA zur ökotoxikologischen Untersuchung von Chemikalien (OECD, 1992a, 2013a, 2013b; US EPA, 2000). Zusätzlich wurde die Aufnahme der Partikel in die genannten Testorganismen untersucht. In Zebrabärblingsembryonen wurden außerdem potentielle Effekte auf die Genexpression mittels Microarrays ermittelt. Die erhaltenen Daten wurden später mit Ergebnissen aus Tests mit dem Wasserfloh Daphnia magna, der Alge Scenedesmus vacuolatus, Larven der Mücke Chironomus riparius und nitrifizierenden Bodenmikroorganismen ergänzt.
In dem Fischembryotoxizitätstest wurde keine Passage der Carbo-Iron-Partikel durch das Chorion in den perivitellinen Raum oder den Embryo beobachtet. Nach der Exposition wurde Carbo-Iron im Darm von H. azteca und D. rerio, aber keinem anderen Gewebe oder Organen detektiert. Carbo-Iron hatte keine signifikanten Effekte auf die Nitrifikationsrate der Bodenmikroorganismen sowie Überleben und Wachstum des Zebrabärblings. Dennoch wurden signifikant negative Effekte auf Wachstum, Fütterungsrate und Reproduktion von H. azteca und auf das Überleben und die Reproduktion von D. magna festgestellt. Des Weiteren war die Entwicklungsrate von C. riparius und das Zellvolumen von S. vacuolatus negativ beeinflusst.
Anhand der durchgeführten Studien wurde basierend auf dem Ergebnis des Reproduktionstests mit D. magna und einem assessment factor von 10 für Carbo-Iron eine predicted no effect concentration von 0,1 mg/L ermittelt. Diese wurde mit modellierten und gemessenen Umweltkonzentrationen von Carbo-Iron verglichen die in einer Studie erhoben wurden, in denen Carbo-Iron zur Behandlung eines mit Chlorkohlenwasserstoffen kontaminierten Aquifers eingesetzt wurde, und Risiko-Quotienten wurden abgeleitet. Zur gesamtheitlichen Betrachtung wurde anschließend ein Schema zur Bewertung des Umweltrisikos vor und nach der Behandlung des Aquifers mit Carbo-Iron entwickelt. Die erhobenen Daten weisen auf ein reduziertes Umweltrisiko nach der Applikation von Carbo-Iron hin. Dementsprechend überwiegen die Vorteile einer Grundwasserbehandlung mit Carbo-Iron die potentiellen negativen Effekte auf die Umwelt.
Agricultural land-use may lead to brief pulse exposures of pesticides in edge-of-field streams, potentially resulting in adverse effects on aquatic macrophytes, invertebrates and ecosystem functions. The higher tier risk assessment is mainly based on pond mesocosms which are not designed to mimic stream-typical conditions. Relatively little is known on exposure and effect assessment using stream mesocosms.
Thus the present thesis evaluates the appliacability of the stream mesocosms to mimic stream-typical pulse exposures, to assess resulting effects on flora and fauna and to evaluate aquatic-terrestrial food web coupling. The first objective was to mimic stream-typical pulse exposure scenarios with different durations (≤ 1 to ≥ 24 hours). These exposure scenarios established using a fluorescence tracer were the methodological basis for the effect assessment of an herbicide and an insecticide. In order to evaluate the applicability of stream mesocosms for regulatory purposes, the second objective was to assess effects on two aquatic macrophytes following a 24-h pulse exposure with the herbicide iofensulfuron-sodium (1, 3, 10 and 30 µg/L; n = 3). Growth inhibition of up to 66 and 45% was observed for the total shoot length of Myriophyllum spicatum and Elodea canadensis, respectively. Recovery of this endpoint could be demonstrated within 42 days for both macrophytes. The third objective was to assess effects on structural and functional endpoints following a 6-h pulse exposure of the pyrethroid ether etofenprox (0.05, 0.5 and 5 µg/L; n = 4). The most sensitive structural (abundance of Cloeon simile) and functional (feeding rates of Asellus aquaticus) endpoint revealed significant effects at 0.05 µg/L etofenprox. This concentration was below field-measured etofenprox concentrations and thus suggests that pulse exposures adversely affect invertebrate populations and ecosystem functions in streams. Such pollutions of streams may also result in decreased emergence of aquatic insects and potentially lead to an insect-mediated transfer of pollutants to adjacent food webs. Test systems capable to assess aquatic-terrestrial effects are not yet integrated in mesocosm approaches but might be of interest for substances with bioaccumulation potential. Here, the fourth part provides an aquatic-terrestrial model ecosystem capable to assess cross-ecosystem effects. Information on the riparian food web such as the contribution of aquatic (up to 71%) and terrestrial (up to 29%) insect prey to the diet of the riparian spider Tetragnatha extensa was assessed via stable isotope ratios (δ13C and δ15N). Thus, the present thesis provides the methodological basis to assess aquatic-terrestrial pollutant transfer and effects on the riparian food web.
Overall the results of this thesis indicate, that stream mesocosms can be used to mimic stream-typical pulse exposures of pesticides, to assess resulting effects on macrophytes and invertebrates within prospective environmental risk assessment (ERA) and to evaluate changes in riparian food webs.
Leaf litter breakdown is a fundamental process in aquatic ecosystems, being mainly mediated by decomposer-detritivore systems that are composed of microbial decomposers and leaf-shredding, detritivorous invertebrates. The ecological integrity of these systems can, however, be disturbed, amongst others, by chemical stressors. Fungicides might pose a particular risk as they can have negative effects on the involved microbial decomposers but may also affect shredders via both waterborne toxicity and their diet; the latter by toxic effects due to dietary exposure as a result of fungicides’ accumulation on leaf material and by negatively affecting fungal leaf decomposers, on which shredders’ nutrition heavily relies. The primary aim of this thesis was therefore to provide an in-depth assessment of the ecotoxicological implications of fungicides in a model decomposer-detritivore system using a tiered experimental approach to investigate (1) waterborne toxicity in a model shredder, i.e., Gammarus fossarum, (2) structural and functional implications in leaf-associated microbial communities, and (3) the relative importance of waterborne and diet-related effects for the model shredder.
Additionally, knowledge gaps were tackled that were related to potential differences in the ecotoxicological impact of inorganic (also authorized for organic farming in large parts of the world) and organic fungicides, the mixture toxicity of these substances, the field-relevance of their effects, and the appropriateness of current environmental risk assessment (ERA).
In the course of this thesis, major differences in the effects of inorganic and organic fungicides on the model decomposer-detritivore system were uncovered; e.g., the palatability of leaves for G. fossarum was increased by inorganic fungicides but deteriorated by organic substances. Furthermore, non-additive action of fungicides was observed, rendering mixture effects of these substances hardly predictable. While the relative importance of the waterborne and diet-related effect pathway for the model shredder seems to depend on the fungicide group and the exposure concentration, it was demonstrated that neither path must be ignored due to additive action. Finally, it was shown that effects can be expected at field-relevant fungicide levels and that current ERA may provide insufficient protection for decomposer-detritivore systems. To safeguard aquatic ecosystem functioning, this thesis thus recommends including leaf-associated microbial communities and long-term feeding studies using detritus feeders in ERA testing schemes, and identifies several knowledge gaps whose filling seems mandatory to develop further reasonable refinements for fungicide ERA.