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1. Seasonal dynamics of the macrophyte test species Myriophyllum spicatum over two years in experimental ditches for population modelling application in risk assessment

Author

Arts, G.H.P., Smeden, J., Wolters, M.F., Belgers, J.D.M., Matser, A.M., Hommen, U., Bruns, E., Heine, S., Solga, A., Taylor, S., Arts, G.H.P., Smeden, J., Wolters, M.F., Belgers, J.D.M., Matser, A.M., Hommen, U., Bruns, E., Heine, S., Solga, A., and Taylor, S.

Abstract

Myriophyllum spicatum is a sediment-rooted, aquatic macrophyte growing submerged, with a wide geographical distribution and high ecological relevance in freshwater ecosystems. It is used in testing and risk assessment for pesticides in water and sediment. Population models enable effects measured under laboratory conditions to be extrapolated to effects expected in the field with time-variable environmental factors including exposure. These models are a promising tool in higher tier risk assessments. However, there is a lack of data on the seasonal dynamics of M. spicatum, which is needed to test model predictions of typical population dynamics in the field. To generate such data, a 2-year study was set up in outdoor experimental systems from May 2017 to May 2019. The growth of M. spicatum was monitored in 0.2025 m2 plant baskets installed in an experimental ditch. Parameters monitored included biomass (fresh and dry weight), shoot length, seasonal short-term growth rates of shoots, relevant environmental parameters and weather data. The results showed a clear seasonal pattern of biomass and shoot length and their variability. Myriophyllum spicatum reached a maximum total shoot length of 125.3 m.m-2 and a maximum standing crop aboveground dry weight of 262 g.m-2. Periodical growth rates reached up to 0.072.d-1, 0.095.d-1 and 0.085.d-1 for total length, fresh weight and dry weight, respectively. Multivariate regression revealed that pH (as a surrogate for the availability of carbon species) and water temperature could explain a significant part of the variability in Myriophyllum spicatum growth rates (p-values < 0.05). This study has delivered an ecologically relevant dataset on seasonal population dynamics representative of shallow freshwater ecosystems, which can be used to test and refine population models for use in chemical risk assessment and ecosystem management.

Published
2022

3. Dataset underlying the publication Seasonal dynamics of the macrophyte test species Myriophyllum spicatum over two years in experimental ditches for population modelling application in risk assessment

Author

Arts, Gertie, van Smeden, Jasper, Wolters, Marieke, Belgers, Dick, Matser, Arrienne, Hommen, U., Bruns, E., Heine, S., Solga, A., Taylor, S., Arts, Gertie, van Smeden, Jasper, Wolters, Marieke, Belgers, Dick, Matser, Arrienne, Hommen, U., Bruns, E., Heine, S., Solga, A., and Taylor, S.

Abstract

The dataset covers biotic and abiotic data from the aquatic habitat of a population of the sediment-rooted macrophyte Myriophyllum spicatum in the temperate climate region (The Netherlands). The growth of M. spicatum was monitored in 0.2025 m2 plant baskets installed in an experimental ditch. Parameters monitored included biomass (fresh and dry weight), shoot length, seasonal short-term growth rates of shoots, relevant environmental parameters and weather data. This dataset includes the 2-year experimental biotic (macrophyte biomass and growth data) and environmental data (water quality data, sediment data). A second file includes the statistical data. A third file includes the weather data.

Published
2021

5. Reintroducing Environmental Change Drivers in Biodiversity-Ecosystem Functioning Research

Author

De Laender, F., Rohr, J.R., Ashauer, R., Baird, D.J., Berger, U., Eisenhauer, N., Grimm, V., Hommen, U., Maltby, L., Meliàn, C.J., Pomati, F., Roessink, I., Radchuk, V., Van den Brink, P.J., and Publica

Subjects
traits, food webs, modeling, environmental change, richness, biodiversity
Abstract

For the past 20 years, research on biodiversity and ecosystem functioning (B-EF) has only implicitly considered the underlying role of environmental change. We illustrate that explicitly reintroducing environmental change drivers in B-EF research is needed to predict the functioning of ecosystems facing changes in biodiversity. Next we show how this reintroduction improves experimental control over community composition and structure, which helps to provide mechanistic insight on how multiple aspects of biodiversity relate to function and how biodiversity and function relate in food webs. We also highlight challenges for the proposed reintroduction and suggest analyses and experiments to better understand how random biodiversity changes, as studied by classic approaches in B-EF research, contribute to the shifts in function that follow environmental change.

Published
2016

6. How TK-TD and population models for aquatic macrophytes could support the risk assessment for plant protection products

Author

Hommen, U., Schmitt, W., Heine, S., Brock, T.C.M., Duquesne, S., Manson, P., Meregali, G., Ochoa-Acuna, H., van Vliet, P., Arts, G.H.P., and Publica

Subjects
Environmental Risk Assessment, Macrophytes, WIMEK, Dynamic exposure, Mechanistic effect models, Pesticide risk assessment
Abstract

This case study of the Society of Environmental Toxicology and Chemistry (SETAC) workshop MODELINK demonstrates the potential use of mechanistic effects models for macrophytes to extrapolate from effects of a plant protection product observed in laboratory tests to effects resulting from dynamic exposure on macrophyte populations in edge-of-field water bodies. A standard European Union (EU) risk assessment for an example herbicide based on macrophyte laboratory tests indicated risks for several exposure scenarios. Three of these scenarios are further analyzed using effect models for 2 aquatic macrophytes, the free-floating standard test species Lemna sp., and the sediment-rooted submerged additional standard test species Myriophyllum spicatum. Both models include a toxicokinetic (TK) part, describing uptake and elimination of the toxicant, a toxicodynamic (TD) part, describing the internal concentration-response function for growth inhibition, and a description of biomass growth as a function of environmental factors to allow simulating seasonal dynamics. The TK-TD models are calibrated and tested using laboratory tests, whereas the growth models were assumed to be fit for purpose based on comparisons of predictions with typical growth patterns observed in the field. For the risk assessment, biomass dynamics are predicted for the control situation and for several exposure levels. Based on specific protection goals for macrophytes, preliminary example decision criteria are suggested for evaluating the model outputs. The models refined the risk indicated by lower tier testing for 2 exposure scenarios, while confirming the risk associated for the third. Uncertainties related to the experimental and the modeling approaches and their application in the risk assessment are discussed. Based on this case study and the assumption that the models prove suitable for risk assessment once fully evaluated, we recommend that 1) ecological scenarios be developed that are also linked to the exposure scenarios, and 2) quantitative protection goals be set to facilitate the interpretation of model results for risk assessment.

Published
2016

7. How to use mechanistic effect models in environmental risk assessment of pesticides: Case studies and recommendations from the SETAC workshop MODELINK

Author

Hommen, U., Forbes, V., Grimm, Volker, Preuss, T.G., Thorbek, P., Ducrot, V., Hommen, U., Forbes, V., Grimm, Volker, Preuss, T.G., Thorbek, P., and Ducrot, V.

Abstract

Mechanistic effect models (MEMs) are useful tools for ecological risk assessment of chemicals to complement experimentation. However, there are currently no recommendations for how to use them in risk assessments. Therefore, the SETAC MODELINK workshop aimed at providing guidance for when and how to apply MEMs in regulatory risk assessments. The workshop focused on risk assessment of plant protection products under Regulation (EC) No 1107/2009 using MEMs at the organism- and population levels. Realistic applications of MEMs were demonstrated in six case studies covering assessments for plants, invertebrates and vertebrates in aquatic and terrestrial habitats. From the case studies and their evaluation, 12 recommendations on the future use of MEMs were formulated, addressing the issues of how to translate specific protection goals into workable questions, how to select species and scenarios to be modelled, and where and how to fit MEMs into current and future risk assessment schemes. The most important recommendations are: protection goals should be made more quantitative; the species to be modelled must be vulnerable not only regarding toxic effects but also regarding their life history and dispersal traits; the models should be as realistic as possible for a specific risk assessment question, and the level of conservatism required for a specific risk assessment should be reached by designing appropriately conservative environmental and exposure scenarios; scenarios should include different regions of the EU and different crops; in the long run, generic MEMs covering relevant species based on representative scenarios should be developed, which will require EU-level joint initiatives of all stakeholders involved. The main conclusion from the MODELINK workshop is that the considerable effort required for making MEMs an integral part of environmental risk assessment of pesticides is worthwhile because it will make risk assessments not only more ecologically relevant an

Published
2015

8. The minimum detectable difference (MDD) and the interpretation of treatmentr related effects of pesticides in experimental ecosystems

Author

Brock, T.C.M., Hammers-Wirtz, M., Hommen, U., Preuss, T.G., Ratte, H.T., Roessink, I., Strauss, T., van den Brink, P.J., Brock, T.C.M., Hammers-Wirtz, M., Hommen, U., Preuss, T.G., Ratte, H.T., Roessink, I., Strauss, T., and van den Brink, P.J.

Abstract

In the European registration procedure for pesticides, microcosm and mesocosm studies are the highest aquatic experimental tier to assess their environmental effects. Evaluations of microcosm/mesocosm studies rely heavily on no observed effect concentrations (NOECs) calculated for different population-level endpoints. Ideally, a power analysis should be reported for the concentration–response relationships underlying these NOECs, as well as for measurement endpoints for which significant effects cannot be demonstrated. An indication of this statistical power can be provided a posteriori by calculated minimum detectable differences (MDDs). The MDD defines the difference between the means of a treatment and the control that must exist to detect a statistically significant effect. The aim of this paper is to expand on the Aquatic Guidance Document recently published by the European Food Safety Authority (EFSA) and to propose a procedure to report and evaluate NOECs and related MDDs in a harmonised way. In addition, decision schemes are provided on how MDDs can be used to assess the reliability of microcosm/mesocosm studies and for the derivation of effect classes used to derive regulatory acceptable concentrations. Furthermore, examples are presented to show how MDDs can be reduced by optimising experimental design and sampling techniques.

Published
2015

9. Ecological models for regulatory risk assessments of pesticides: Developing a strategy for the future

Author

Thorbek, P., Forbes, V., Heimbach, F., Hommen, U., Thulke, H.H., and van den Brink, P.J.

Subjects
ecological risk assessment, risk assessment, simulation models, pesticides, ecologische risicoschatting, simulatiemodellen, landbouw en milieu, risicoschatting, milieufactoren, agriculture and environment, environmental factors, milieutoets, pesticiden, environmental assessment, ecologie, ecology
Abstract

Ecological Models for Regulatory Risk Assessments of Pesticides: Developing a Strategy for the Future provides a coherent, science-based view on ecological modeling for regulatory risk assessments. It discusses the benefits of modeling in the context of registrations, identifies the obstacles that prevent ecological modeling being used routinely in regulatory submissions, and explores the actions needed to overcome these obstacles. The book focuses on the following issues: Uncertainties in the process of model development, such as design, analysis, documentation, and communication, The availability of data and background information needed for optimal modeling, The limited knowledge of modeling, The lack of confidence in the outcome of ecological models and their reliability in pesticide risk assessment, It also suggests future solutions to these challenges, including: A guidance document on the modeling process, Case studies that show how ecological models can provide reliable ecologically relevant risk assessments, Training the people who generate or evaluate results obtained by ecological models, Focusing on ecological models, such as unstructured population models, stage-structured matrix models, and individual- or agent-based models, this volume helps regulatory authorities, manufacturers, and scientists assess the risk of plant protection products in nontarget organisms.

Published
2010

10. Potential application of ecological models in the European environmental risk assessment of chemicals: I. review of protection goals of EU directives

Author

Hommen, U., Baveco, J.M., Galic, N.G., and van den Brink, P.J.

Subjects
Aquatic Ecology and Water Quality Management, Data requirements, WIMEK, CL - Ecological Models and Monitoring, CWC - Environmental Risk Assessment, Aquatische Ecologie en Waterkwaliteitsbeheer, CWK - Environmental Risk Assessment, Protection goals, CL - Ecologische Modellen en Monitoring, Alterra - Centre for Water and Climate, Chemical risk assessment, Wageningen Environmental Research, Ecological model, Alterra - Centrum Water en Klimaat
Abstract

Several European directives and regulations address the environmental risk assessment of chemicals. We used the protection of freshwater ecosystems against plant protection products, biocidal products, human and veterinary pharmaceuticals, and other chemicals and priority substances under the Water Framework Directive as examples to explore the potential of ecological effect models for a refined risk assessment. Our analysis of the directives, regulations, and related guidance documents lead us to distinguish the following 5 areas for the application of ecological models in chemical risk assessment: 1) Extrapolation of organism-level effects to the population level: The protection goals are formulated in general terms, e.g., avoiding unacceptable effects or adverse impact on the environment or the viability of exposed species. In contrast, most of the standard ecotoxicological tests provide data only on organism-level endpoints and are thus not directly linked to the protection goals which focus on populations and communities. 2) Extrapolation of effects between different exposure profiles: Especially for plant protection products, exposure profiles can be very variable and impossible to cover in toxicological tests. 3) Extrapolation of recovery processes: As a consequence of the often short-term exposures to plant protection products, the risk assessment is based on the community recovery principle. On the other hand, assessments under the other directives assume a more or less constant exposure and are based on the ecosystem threshold principle. 4) Analysis and prediction of indirect effects: Because effects on 1 or a few taxa might have consequences on other taxa that are not directly affected by the chemical, such indirect effects on communities have to be considered. 5) Prediction of bioaccumulation within food chains: All directives take the possibility of bioaccumulation, and thus secondary poisoning within the food chain, into account.

Published
2010

13. Potential application of population models in the European ecological risk assessment of chemicals: II review of models and whether they can address the protection aims

Author

Galic, N.G., Hommen, U., Baveco, J.M., and van den Brink, P.J.

Subjects
Aquatic Ecology and Water Quality Management, WIMEK, CL - Ecological Models and Monitoring, CWC - Environmental Risk Assessment, Aquatische Ecologie en Waterkwaliteitsbeheer, Bioaccumulation, Indirect effects, CWK - Environmental Risk Assessment, CL - Ecologische Modellen en Monitoring, Alterra - Centre for Water and Climate, Wageningen Environmental Research, Ecological models, Extrapolation recovery, Alterra - Centrum Water en Klimaat
Abstract

Whereas current chemical risk assessment (RA) schemes within the European Union (EU) focus mainly on toxicity and bioaccumulation of chemicals in individual organisms, most protection goals aim at preserving populations of nontarget organisms rather than individuals. Ecological models are tools rarely recommended in official technical documents on RA of chemicals, but are widely used by researchers to assess risks to populations, communities and ecosystems. Their great advantage is the relatively straightforward integration of the sensitivity of species to chemicals, the mode of action and fate in the environment of toxicants, life-history traits of the species of concern, and landscape features. To promote the usage of ecological models in regulatory risk assessment, this study tries to establish whether existing, published ecological modeling studies have addressed or have the potential to address the protection aims and requirements of the chemical directives of the EU. We reviewed 148 publications, and evaluated and analyzed them in a database according to defined criteria. Published models were also classified in terms of 5 areas where their application would be most useful for chemical RA. All potential application areas are well represented in the published literature. Most models were developed to estimate population-level responses on the basis of individual effects, followed by recovery process assessment, both in individuals and at the level of metapopulations. We provide case studies for each of the proposed areas of ecological model application. The lack of clarity about protection goals in legislative documents made it impossible to establish a direct link between modeling studies and protection goals. Because most of the models reviewed here were not developed for regulatory risk assessment, there is great potential and a variety of ecological models in the published literature. Integr Environ Assess Manag 2010;6:338-360.

Published
2010

16. Détermination et application de normes de qualité environnementale pour l'eau et les sédiments

Author

Matthiessen, P., Babut, Marc, Baetley, G., Douglas, M., Fawell, J., Hommen, U., Hutchinson, T., Janssen, M., Maycock, D., Reiley, M., Schneider, U., Weltje, Lennart, Crane, M., Merrington, G., Whitehouse, P., Irstea Publications, Migration, Qualité des eaux et prévention des pollutions (UR QELY), Centre national du machinisme agricole, du génie rural, des eaux et forêts (CEMAGREF), CSIRO AU, Partenaires IRSTEA, Institut national de recherche en sciences et technologies pour l'environnement et l'agriculture (IRSTEA)-Institut national de recherche en sciences et technologies pour l'environnement et l'agriculture (IRSTEA), DOW CHEMICALS GBR, FHI DEU, ASRA ZENECA GBR, RIVM NLD, WCA GBR, USEPA USA, ENVIRONNEMENT CANADA CA, and BASF DEU

Subjects
[SDE] Environmental Sciences, [SDE]Environmental Sciences, ComputingMilieux_MISCELLANEOUS
Abstract

International audience

Published
2009

20. Aquatic macroinvertebrates in the Altes Land, an intensely used orchard region in Germany

Author

Schäfers, C., Hommen, U., Dembinski, M., Gonzalez-Valero, J.F., and Publica

Abstract

To assess the impact of pesticides on aquatic organisms under realistic worst-case conditions, a macroinvertebrate community of small ditches was sampled at 40 sites of the orchard region Altes Land near Hamburg, Germany. To differentiate between pesticide impact and other variables, the ditches selected for sampling were located at different distances along grassland, unused apple orchards, and orchards managed with integrated and/or organic crop protection methods. Samples of macroinvertebrates were taken on five dates over two years. In addition to biological data, water chemistry and structural parameters were measured. For each sampling site, a potential for exposure was calculated on the basis of the distance of the ditch to the nearest row of trees and the depth and width of the ditch. The neighborhood to either grassland or orchards turned out to have a larger impact on the macroinvertebrate community than the potential for exposure. Therefore, grassland sites were omitted from further evaluation. Remaining sites were grouped into low exposure (sites at unused orchards), medium exposure (distance of 3-5 m [track] between trees and ditch), and high exposure (trees close to the ditch, mean distance

Published
2006

39. The food web approach in the environmental management of toxic substances

Author

Baird, D.J., Brock, T.C.M., de Ruiter, P.C., Boxall, A.B.A., Culp, J.M., Eldridge, P., Hommen, U., Jak, R.G., Kidd, K.A., and DeWit, T.

Subjects
nutriënten, milieu, pesticiden, ecotoxicologie, Wageningen Environmental Research, bestrijdingsmiddelen, bodemecologie, voedselweb
Published
2001

40. Ecological models supporting management of wildlife diseases

Author

Thorbek, P., Forbes, V., Heimbach, F., Hommen, U., Thulke, H.-H., van den Brink, P., Wogram, J., Grimm, V., Thulke, Hans-Hermann, Grimm, Volker, Thorbek, P., Forbes, V., Heimbach, F., Hommen, U., Thulke, H.-H., van den Brink, P., Wogram, J., Grimm, V., Thulke, Hans-Hermann, and Grimm, Volker

Published
2010

41. State-of-the-art of ecological modelling for pesticide risk assessment: a critical review

Author

Thorbek, P., Forbes, V., Heimbach, F., Hommen, U., Thulke, H.-H., van den Brink, P., Wogram, J., Grimm, V., Grimm, Volker, Schmolke, Amelie, Chapman, P., Thorbek, P., Forbes, V., Heimbach, F., Hommen, U., Thulke, H.-H., van den Brink, P., Wogram, J., Grimm, V., Grimm, Volker, Schmolke, Amelie, and Chapman, P.

Abstract

While many ecological models addressing pesticide risk assessment can be found in the academic literature, they are rarely applied in pesticide registrations. In order to determine issues with existing models as published in literature, we assess the state-of-the-art of ecological models addressing pesticide risk assessments. We focus on how toxic effects were modelled, how risk was quantified, and on the verification and validation of the models. From an extensive literature scan, 41 models were selected for review. Three main classes of models are used for pesticide risk assessment: difference and differential equations (14 out of 41 models), matrix models (17), and individual-based models (IBMs; 8). Additionally, two grid-based simulations were included. In the majority of models, toxicity was implemented as increased mortality, and risk was quantified by the effects on population dynamics. In some publications, both measures remained unclear. Apart from a subset of the IBMs, no validation was performed on the models. Another problem could be identified in the often ambiguous description of the models, and a lack of justification of the choice of model type. From this review of models as published in scientific literature, we conclude that most models do not address key issues of pesticide risk assessment sufficiently. We provide recommendations for the future use of ecological models in pesticide risk assessment.

Published
2010

42. Short introduction to ecological modelling

Author

Thorbek, P., Forbes, V., Heimbach, F., Hommen, U., Thulke, H.-H., van den Brink, P., Wogram, J., Grimm, V., Grimm, Volker, Thorbek, P., Forbes, V., Heimbach, F., Hommen, U., Thulke, H.-H., van den Brink, P., Wogram, J., Grimm, V., and Grimm, Volker

Abstract

Ecological modelling has the potential to become a standard tool in higher tier risk assessments of pesticides. However, most stakeholders involved are not familiar with the rationale and methods of ecological modelling, and as a consequence, they do not know how to assess models and when models are to be trusted. Therefore, I here give a short introduction to ecological modelling. After presenting the three main model types of population models relevant for pesticide risk assessment, I explain why choice of model type and structure should not be ad hoc, but instead be determined by a detailed specification of the model's purpose. Finally, I recommend that modellers offer short courses where non-modellers from industry and regulatory authorities are introduced to ecological modelling in more detail, and where modellers can learn more about the specific requirements of the regulatory process.

Published
2010

43. Executive summary of the LEMTOX workshop: lessons learned and steps to be taken

Author

Thorbek, P., Forbes, V., Heimbach, F., Hommen, U., Thulke, H.-H., van den Brink, P., Wogram, J., Grimm, V., Grimm, Volker, Thulke, Hans-Hermann, van den Brink, P.J., Thorbek, P., Forbes, V., Heimbach, F., Hommen, U., Thulke, H.-H., van den Brink, P., Wogram, J., Grimm, V., Grimm, Volker, Thulke, Hans-Hermann, and van den Brink, P.J.

Abstract

The LEMTOX workshop had the aim to bring together experts from industry, academia and regulatory authorities to discuss (1) the benefits of ecological models (EMs) for pesticide risk assessment, (2) to identify issues that so far have prevented a wider use of EMs in the regulatory context, and (3) to agree on the next steps to be taken to establish EMs as a more widely used tool for or pesticide risk assessment. During the workshop, in a series of keynote lectures the perspectives of industry, academia and regulatory authorities were summarized, and three example models were presented. In breakout group and plenary discussions, the three topics of the workshop were discussed. There was general consensus that EMs have a high potential, or might even be the only way, to achieve risk assessments that are more ecologically relevant. A major challenge in establishing EMs as a common tool is the lack of a guidance document defining Good Modelling Practice. The next steps to be taken in order to establish EMs in pesticide registration are to build a core group of stakeholders to organize a follow-up workshop where a draft guidance document on Good Modelling Practice is produced, and to perform carefully selected case studies that follow the guidance document and which clearly demonstrate the added value of risk assessments that are supported by ecological models.

Published
2010

45. Ecological models in support of regulatory risk assessment of pesticides: developing a strategy for the future

Author

Forbes, V.E., Hommen, U., Thorbek, P., Heimbach, F., van den Brink, P.J., Wogram, J., Thulke, Hans-Hermann, Grimm, Volker, Forbes, V.E., Hommen, U., Thorbek, P., Heimbach, F., van den Brink, P.J., Wogram, J., Thulke, Hans-Hermann, and Grimm, Volker

Abstract

This brief communication reports on the main findings of the LEMTOX workshop, held from 9 to 12 September 2007, at the Helmholtz Centre for Environmental Research (UFZ) in Leipzig, Germany. The workshop brought together a diverse group of stakeholders from academia, regulatory authorities, contract research organizations, and industry, epresenting Europe, the United States, and Asia, to discuss the role of ecological modeling in risk assessments of pesticides, particularly under the European regulatory framework. The following questions were addressed: What are the potential benefits of using ecological models in pesticide registration and risk assessment? What obstacles prevent ecological modeling from being used routinely in regulatory submissions? What actions are needed to overcome the identified obstacles? What recommendations should be made to ensure good modeling practice in this context? The workshop focused exclusively on population models, and discussion was focused on those categories of population models that link effects on individuals (e.g., survival, growth, reproduction, behavior) to effects on population dynamics. The workshop participants concluded that the overall benefits of ecological modeling are that it could bring more ecology into ecological risk assessment, and it could provide an excellent tool for exploring the importance of, and interactions among, ecological complexities. However, there are a number of challenges that need to be overcome before such models will receive wide acceptance for pesticide risk assessment, despite having been used extensively in other contexts (e.g., conservation biology). The need for guidance on Good Modeling Practice (on model development, analysis, interpretation, evaluation, documentation, and communication), as well as the need for case studies that can be used to explore the added value of ecological models for risk assessment, were identified as top priorities. Assessing recovery potential of exposed no

Published
2009

47. The minimum detectable difference (MDD) and the interpretation of treatment-related effects of pesticides in experimental ecosystems.

Author

Brock, T., Hammers-Wirtz, M., Hommen, U., Preuss, T., Ratte, H-T., Roessink, I., Strauss, T., and Brink, P.

Subjects
MINIMUM detectable activity, PESTICIDES, ECOSYSTEMS, EXPERIMENTAL design
Abstract

In the European registration procedure for pesticides, microcosm and mesocosm studies are the highest aquatic experimental tier to assess their environmental effects. Evaluations of microcosm/mesocosm studies rely heavily on no observed effect concentrations (NOECs) calculated for different population-level endpoints. Ideally, a power analysis should be reported for the concentration-response relationships underlying these NOECs, as well as for measurement endpoints for which significant effects cannot be demonstrated. An indication of this statistical power can be provided a posteriori by calculated minimum detectable differences (MDDs). The MDD defines the difference between the means of a treatment and the control that must exist to detect a statistically significant effect. The aim of this paper is to expand on the Aquatic Guidance Document recently published by the European Food Safety Authority (EFSA) and to propose a procedure to report and evaluate NOECs and related MDDs in a harmonised way. In addition, decision schemes are provided on how MDDs can be used to assess the reliability of microcosm/mesocosm studies and for the derivation of effect classes used to derive regulatory acceptable concentrations. Furthermore, examples are presented to show how MDDs can be reduced by optimising experimental design and sampling techniques. [ABSTRACT FROM AUTHOR]

Published
2015
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50. Seasonal dynamics of the standard test species Lemna sp. in outdoor microcosms.

Author

Arts GHP, van Smeden J, Wolters MF, Belgers JDM, Matser AM, Hommen U, Bruns E, Heine S, Solga A, and Taylor S

Subjects
Biomass, Water Pollutants, Chemical analysis, Herbicides toxicity, Herbicides analysis, Risk Assessment, Seasons, Araceae drug effects, Environmental Monitoring methods
Abstract

Lemna L. sp. is a free-floating aquatic macrophyte that plays a key role as a standard test species in aquatic risk assessment for herbicides and other contaminants. Population modeling can be used to extrapolate from laboratory to field conditions. However, there are insufficient data on longer-term seasonal dynamics of this species to evaluate such models. Therefore, several long-term growth experiments were conducted in outdoor microcosms (surface area 0.174 m 2 ). Monitoring parameters included biomass, frond numbers, water parameters, and weather data. Three different datasets were generated: frond numbers and biomass from weekly to monthly destructively sampled microcosms; a year-round dataset of frond numbers from five continuously monitored microcosms; and seasonal growth rates without the effect of density dependence over 1-2 weeks in freshly inoculated microcosms. Lemna sp. reached a maximum of approximately 500 000 fronds m -2 and 190 g dry weight m -2 . During the first winter, the microcosms were covered by ice for approximately four weeks, and Lemna sp. populations collapsed. The second winter was warmer, without any ice cover, and Lemna sp. populations maintained high abundance throughout the winter. Dry weight per frond was not constant throughout the year but was highest in autumn and winter. Growth rates without density dependence under outdoor environmental conditions reached 0.29 day -1 for frond number, 0.43 day -1 for fresh weight, and 0.39 day -1 for dry weight. In linear regressions, these growth rates were best explained by water temperature. For the populations continuously monitored throughout a year, the nitrogen-to-phosphorus ratio best explained the growth rate of frond numbers. This study yielded a relevant dataset for testing and refining Lemna population models used in chemical risk assessment as well as for managing ecosystems and combating the effects of eutrophication. Integr Environ Assess Manag 2024;20:1625-1638. © 2024 The Authors. Integrated Environmental Assessment and Management published by Wiley Periodicals LLC on behalf of Society of Environmental Toxicology & Chemistry (SETAC)., (© 2024 The Authors. Integrated Environmental Assessment and Management published by Wiley Periodicals LLC on behalf of Society of Environmental Toxicology & Chemistry (SETAC).)

Published
2024
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