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3. Mechanistic Effect Modeling of Earthworms in the Context of Pesticide Risk Assessment: Synthesis of the FORESEE Workshop

Author

Kevin R. Butt, Martin Holmstrup, David J. Spurgeon, Alice S. A. Johnston, Andreas Focks, Sabine Duquesne, Yvan Capowiez, Mathilde Zorn, Gregor Ernst, Valery E. Forbes, André Gergs, Vanessa Roeben, Cornelis A.M. van Gestel, Kim J. Rakel, Melissa Reed, Dirk Nickisch, Erik van den Berg, Joerg Roembke, Silvia Pieper, Roman Ashauer, Mark E. Hodson, Mattia Meli, Pernille Thorbek, Ralf B. Schäfer, Annika Agatz, Animal Ecology, University of Minnesota [Twin Cities] (UMN), University of Minnesota System, Minnesota State University [Mankato], Minnesota State Colleges and Universities system, Ibacon GmbH, University of York [York, UK], University of Central Lancashire [Preston] (UCLAN), Environnement Méditerranéen et Modélisation des Agro-Hydrosystèmes (EMMAH), Avignon Université (AU)-Institut National de Recherche pour l’Agriculture, l’Alimentation et l’Environnement (INRAE), Helmholtz Zentrum für Umweltforschung = Helmholtz Centre for Environmental Research (UFZ), Bayer Cropscience, and European Crop Protection Association (ECPA)

Subjects
Environmental Risk Assessment, 010504 meteorology & atmospheric sciences, Soil organisms, Computer science, Ecology (disciplines), Geography, Planning and Development, Population, Context (language use), 010501 environmental sciences, 01 natural sciences, Risk Assessment, Soil, Population modeling, Multidisciplinary approach, Germany, Animals, Humans, Workgroup, Oligochaeta, Pesticides, education, Ecosystem, 0105 earth and related environmental sciences, General Environmental Science, Plant protection products, [SDV.EE]Life Sciences [q-bio]/Ecology, environment, education.field_of_study, business.industry, Environmental resource management, Stakeholder, Common ground, General Medicine, 15. Life on land, Agriculture and Soil Science, 13. Climate action, business, Risk assessment, Cross-species extrapolation, Uptake routes
Abstract

Earthworms are important ecosystem engineers, and assessment of the risk of plant protection products toward them is part of the European environmental risk assessment (ERA). In the current ERA scheme, exposure and effects are represented simplistically and are not well integrated, resulting in uncertainty when the results are applied to ecosystems. Modeling offers a powerful tool to integrate the effects observed in lower tier laboratory studies with the environmental conditions under which exposure is expected in the field. This paper provides a summary of the (In)Field Organism Risk modEling by coupling Soil Exposure and Effect (FORESEE) Workshop held 28-30 January 2020 in Düsseldorf, Germany. This workshop focused on toxicokinetic-toxicodynamic (TKTD) and population modeling of earthworms in the context of ERA. The goal was to bring together scientists from different stakeholder groups to discuss the current state of soil invertebrate modeling and to explore how earthworm modeling could be applied to risk assessments, in particular how the different model outputs can be used in the tiered ERA approach. In support of these goals, the workshop aimed at addressing the requirements and concerns of the different stakeholder groups to support further model development. The modeling approach included 4 submodules to cover the most relevant processes for earthworm risk assessment: environment, behavior (feeding, vertical movement), TKTD, and population. Four workgroups examined different aspects of the model with relevance for risk assessment, earthworm ecology, uptake routes, and cross-species extrapolation and model testing. Here, we present the perspectives of each workgroup and highlight how the collaborative effort of participants from multidisciplinary backgrounds helped to establish common ground. In addition, we provide a list of recommendations for how earthworm TKTD modeling could address some of the uncertainties in current risk assessments for plant protection products. Integr Environ Assess Manag 2021;17:352-363. © 2020 SETAC.

Published
2021
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4. The BEEHAVE

Author

Thomas G, Preuss, Annika, Agatz, Benoit, Goussen, Vanessa, Roeben, Jack, Rumkee, Liubov, Zakharova, and Pernille, Thorbek

Subjects
Animals, Bees, Pesticides, Models, Theoretical, Risk Assessment
Abstract

Mechanistic effect models are powerful tools for extrapolating from laboratory studies to field conditions. For bees, several good models are available that can simulate colony dynamics. Controlled and reliable experimental systems are also available to estimate the inherent toxicity of pesticides to individuals. However, there is currently no systematic and mechanistic way of linking the output of experimental ecotoxicological testing to bee models for bee risk assessment. We introduce an ecotoxicological module that mechanistically links exposure with the hazard profile of a pesticide for individual honeybees so that colony effects emerge. This mechanistic link allows the translation of results from standard laboratory studies to relevant parameters and processes for simulating bee colony dynamics. The module was integrated into the state-of-the-art honeybee model BEEHAVE. For the integration, BEEHAVE was adapted to mechanistically link the exposure and effects on different cohorts to colony dynamics. The BEEHAVE

Published
2022

5. Integrating earthworm movement and life history through dynamic energy budgets

Author

Andre Gergs, Kim Rakel, Dino Bussen, Yvan Capowiez, Gregor Ernst, and Vanessa Roeben

Subjects
Physiology, Ecological Modeling, Management, Monitoring, Policy and Law, Nature and Landscape Conservation
Abstract

Earthworms are considered ecosystem engineers and, as such, they are an integral part of the soil ecosystem. The movement of earthworms is significantly influenced by environmental factors such as temperature and soil properties. As movement may directly be linked to food ingestion, especially of endogeic species like Aporrectodea caliginosa, changes in those environmental factors also affect life history traits such as growth and reproduction.In our laboratory studies, earthworms showed a decrease in burrowing activity with decreasing moisture levels and, to some extent, the organic matter content. The burrowing activity of earthworms was also affected by temperature, for which the casts produced per earthworm was used as a proxy in laboratory experiments. We integrated changes in earthworm movement and life histories in response to temperature, soil organic matter content and the moisture level, as observed in our experiment and reported in the literature, through dynamic energy budget (DEB) modelling. The joint parametrization of a DEB model for A. caliginosa based on movement and life history data revealed that food ingestion via movement is an integral part of the earthworms’ energy budgets. Our findings highlight the importance of soil properties to be considered in the model development for earthworms. Furthermore, by understanding and incorporating the effect of environmental factors on the physiology, this mechanistic approach can help assess the impact of environmental changes such as temperature rise or drought.

Published
2022
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7. Towards a spatiotemporally explicit toxicokinetic-toxicodynamic model for earthworm toxicity

Author

Christoph Oberdoerster, Yvan Capowiez, André Gergs, Gregor Ernst, Susanne Oberdoerster, Dino Liesy, Vanessa Roeben, Thomas G. Preuss, Kim J. Rakel, Resarch Institute for Operations Management [Aachen], RWTH Aachen University, Bayer Cropscience, Environnement Méditerranéen et Modélisation des Agro-Hydrosystèmes (EMMAH), and Avignon Université (AU)-Institut National de Recherche pour l’Agriculture, l’Alimentation et l’Environnement (INRAE)

Subjects
Insecticides, Environmental Engineering, Toxicodynamics, 010504 meteorology & atmospheric sciences, Ecology (disciplines), Population, 010501 environmental sciences, 01 natural sciences, Exposure, Soil, Environmental Chemistry, Animals, Soil Pollutants, Oligochaeta, Pesticides, education, Waste Management and Disposal, Organism, 0105 earth and related environmental sciences, Exposure assessment, education.field_of_study, Modeling, Pollution, Bioaccumulation, Toxicokinetics, Population model, 13. Climate action, Burrowing behavior, [SDE]Environmental Sciences, Environmental science, Spatial variability, Biochemical engineering, Risk assessment
Abstract

International audience; The aim of the environmental risk assessment of chemicals is the prevention of unacceptable adverse effects on the environment. Therefore, the risk assessment for in-soil organisms, such as earthworms, is based on two key elements: the exposure assessment and the effect assessment. In the current risk assessment scheme, these two elements are not linked. While for the exposure assessment, advanced exposure models can take the spatial and temporal scale of substances into account, the effect assessment in the lower tiers considers only a limited temporal and spatial variability. However, for soil organisms, such as earthworms, those scales play a significant role as species move through the soil in response to environmental factors. To overcome this gap, we propose a conceptual integration of pesticide exposure, ecology, and toxicological effects on earthworms using a modular modeling approach. An essential part of this modular approach is the environment module, which utilizes exposure models to provide spatially and temporally explicit information on environmental variables (e.g., temperature, moisture, organic matter content) and chemical concentrations. The behavior module uses this information and simulates the feeding and movement of different earthworm species using a trait-based approach. The resulting exposure can be processed by a toxico kinetic-toxicodynamic (TKTD) module. TKTD models are particularly suitable to make effect predictions for time-variable exposure situations as they include the processes of uptake, elimination, internal distribution, and biotransformation of chemicals and link the internal concentration to an effect at the organism level. The population module incorporates existing population models of different earthworm species. The modular approach is illustrated using a case study with an insecticide. Our results emphasize that using a modular model approachwill facilitate the integration of exposure and effects and thus enhance the risk assessment of soil organisms.

Published
2020
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