Evaluating the ecological significance of laboratory response data to predict population‐level effects for the estruarine amphipod Ampelisca abdita

Ten‐day acute mortality of the benthic amphipod Ampelisca abdita is used in a number of regulatory, research, and monitoring programs to evaluate chemical contamination of marine sediments. Although this endpoint has proven to be valuable for characterizing the relative toxicities of sediments, the significance of acute mortality with respect to population viability has not yet been established. In this study, population modeling along with empirical extrapolation were used to describe a relationship between acute mortality and population‐level response of A. abdita . The research involved the performance of a standard 10‐d sediment toxicity bioassay and a 70‐d full life‐cycle chronic population (including reproduction) bioassay exposing A. abdita to sediments spiked with concentrations of the divalent metal cadmium (normalized to acid volatile sulfide) expected to produce a range of biological effects. These data provided age‐specific schedules of survival and fecundity that were used to parameterize an age‐classified projection matrix model for A. abdita . Measured exposure data and population growth rate estimates, obtained using the demographic information collected during the 70‐d assay, were used to develop exposure—response models. These data were also used to develop an empirical relationship between population growth rate (λ) and acute mortality. This relationship describes how acute data may be used to predict concentrations that produce population‐level effects. Model manipulations permit extrapolation of early life‐stage mortality (the acute endpoint) to changes in population growth rate. These relationships were used to evaluate a range of ecologically acceptable acute mortality for A. abdita .