Extrapolation of imidacloprid toxicity between soils by exposing Folsomia candida in soil pore water

Soil properties like organic matter (OM) content show great variation, making it hard to predict the fate and effects of a chemical in different soils. We therefore addressed the question: can we remove the complexity of the soil matrix and yet accurately predict soil toxicity from porewater exposur...

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Bibliographic Details
Published in:Ecotoxicology (London) 2018-10, Vol.27 (8), p.1107-1115
Main Authors: Ogungbemi, Afolarin O., van Gestel, Cornelis A. M.
Format: Article
Language:English
Subjects:
Animals
Arthropods - physiology
Clay
Clay minerals
Coefficients
Earth and Environmental Science
Ecology
Ecotoxicology
Environment
Environmental Management
Exposure
Extrapolation
Folsomia candida
Grasslands
Imidacloprid
Insecticides
Lethal Dose 50
Minerals
Mortality causes
Neonicotinoids - toxicity
Nitro Compounds - toxicity
Organic chemistry
Organic matter
Organic soils
Pore water
Soil
Soil - chemistry
Soil Pollutants - toxicity
Soil properties
Soil water
Soils
Toxicity
Toxicity Tests
Water pollution
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Summary:Soil properties like organic matter (OM) content show great variation, making it hard to predict the fate and effects of a chemical in different soils. We therefore addressed the question: can we remove the complexity of the soil matrix and yet accurately predict soil toxicity from porewater exposures? Folsomia candida was exposed to imidacloprid in natural (LUFA 2.2 [4.02% OM], Grassland [12.6% OM]) and artificial soils (OECD 5 [6.61% OM], OECD 10 [10.8% OM]), in pore water extracted from spiked LUFA 2.2 soil and in water. Toxicity decreased with increasing OM content except for Grassland soil, which had the highest OM content but the lowest clay content, suggesting a role of clay minerals in the binding of imidacloprid. Distribution coefficients for imidacloprid based on toxicity (Toxicity- K d ) were derived by comparing effect concentrations in LUFA 2.2 soil and in water. Using these Toxicity- K d s to recalculate soil LC 50 s/EC 50 s to porewater concentrations, the differences in LC 50 /EC 50 s almost disappeared. The recalculated porewater LC 50 s did not differ by more than a factor of 0.55–1.43 from the LC 50 obtained upon water exposure. This similarity suggests that the toxicity in the soil is dependent on porewater concentrations and can be obtained from water exposure. The porewater test and the corresponding “pore-water extrapolation concept” developed in this study may be used to predict the toxicity of chemicals in the soil and extrapolate among different soils.
ISSN:0963-9292
1573-3017
DOI:10.1007/s10646-018-1965-x