Abstract
BackgroundToxicants often occur simultaneously. Some combinations show synergistic combined effects that go far beyond what is predicted with current effect models. Up until now, only the combined additive effects of similar acting chemicals have been assessed accurately, whereas the combined effects of dissimilar acting chemicals have been greatly underestimated in many cases.ResultsHere, we use the individual tri-phasic concentration–response relationship of two toxicants with different modes of action to model their combined synergistic effect on Daphnia magna. The novel stress addition approach (SA) predicted the combined effects (LC50) of different esfenvalerate and prochloraz combinations with an uncertainty factor of 2.8 at most, while the traditional effect addition (EA) and concentration addition (CA) approaches underestimated the combined effect by a factor of up to 150 and 660, respectively. Data of the single substance concentration–response relationships and on their combined effects enable to determine the degree of synergism. For the evaluation of the combined toxicant effect, we provide the approach as R package and as Indicate model (http://www.systemecology.eu/indicate/).ConclusionAdding stressors arithmetically, considering non-monotonic cause–effect relationships, is a decisive component in predicting the combined effects of multiple stressors within test systems. However, the extent of the synergistic effects that multiple stressors exert on populations within the ecosystem context is still highly controversial. Various processes are relevant at the ecosystem level, which are not considered in laboratory studies. However, the present work serves as a building block for understanding the effects of multiple stressors in the field.
Highlights
The concentration–response relationships were fitted with the ECx-System stress (SyS) model [18] that allows to separately identify the toxicant and system stress (Fig. 1b, d)
Combined toxicant effects The combination of esfenvalerate and prochloraz acts highly synergistically. This experimentally observed combined effect on Daphnia magna was modeled on the basis of the concentration–response relationship of each pesticide using 3 different approaches: (i) the MultiTOX approach presented here with the basic assumption of stress addition (SA); (ii) the traditional concentration addition (CA) and (iii) the effect addition (EA)
Here we provide an approach that mechanistically quantifies the synergistic effects of toxicant mixtures with different modes of action
Summary
Some combinations show synergistic combined effects that go far beyond what is predicted with current effect models. Some combinations show combined synergistic effects that go far beyond what is expected when using current effect models This high degree of uncertainty makes it difficult to predict the biological effects of toxicant mixtures [1, 2]. For many (i) Combined effects of similar acting toxicants are usually assessed with the concentration addition approach (CA) [3]. The CA approach assumes that the concentrations of toxicants can be added if scaled by their toxicity This combined effect prediction of toxicant mixtures with the same mode of action mostly provides satisfactory results, whereby even mixtures with 16 different substances can be accurately predicted [4]
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