Extrapolating ecotoxicological effects from individuals to populations: a generic approach based on Dynamic Energy Budget theory and individual-based modeling
Authored by Volker Grimm, Thomas G Preuss, Roger M Nisbet, Tjalling Jager, Monika Hammers-Wirtz, Benjamin T Martin
Date Published: 2013
DOI: 10.1007/s10646-013-1049-x
Sponsors:
European Union
United States Environmental Protection Agency (EPA)
United States National Science Foundation (NSF)
Platforms:
NetLogo
Model Documentation:
ODD
Mathematical description
Model Code URLs:
Model code not found
Abstract
Individual-based models (IBMs) predict how dynamics at higher levels of
biological organization emerge from individual-level processes. This
makes them a particularly useful tool for ecotoxicology, where the
effects of toxicants are measured at the individual level but protection
goals are often aimed at the population level or higher. However, one
drawback of IBMs is that they require significant effort and data to
design for each species. A solution would be to develop IBMs for
chemical risk assessment that are based on generic individual-level
models and theory. Here we show how one generic theory, Dynamic Energy
Budget (DEB) theory, can be used to extrapolate the effect of toxicants
measured at the individual level to effects on population dynamics. DEB
is based on first principles in bioenergetics and uses a common model
structure to model all species. Parameterization for a certain species
is done at the individual level and allows to predict population-level
effects of toxicants for a wide range of environmental conditions and
toxicant concentrations. We present the general approach, which in
principle can be used for all animal species, and give an example using
Daphnia magna exposed to 3,4-dichloroaniline. We conclude that our
generic approach holds great potential for standardized ecological risk
assessment based on ecological models. Currently, available data from
standard tests can directly be used for parameterization under certain
circumstances, but with limited extra effort standard tests at the
individual would deliver data that could considerably improve the
applicability and precision of extrapolation to the population level.
Specifically, the measurement of a toxicant's effect on growth in
addition to reproduction, and presenting data over time as opposed to
reporting a single EC50 or dose response curve at one time point.
Tags
Mechanistic effect models
Protocol
Chemicals
Parameters
Daphnia-magna
End-points
Life-cycle
Ecological risk-assessment
Toxicity
3,4-dichloroaniline