FN Archimer Export Format PT J TI Dietary bioaccumulation of persistent organic pollutants in the common sole Solea solea in the context of global change. Part 1: Revisiting parameterisation and calibration of a DEB model to consider inter-individual variability in experimental and natural conditions. BT AF Mounier, Florence Pecquerie, Laure Lobry, Jérémy Sardi, Adriana E. Labadie, Pierre Budzinski, Hélène Loizeau, Veronique AS 1:1;2:3;3:1;4:4;5:4;6:4;7:2; FF 1:;2:;3:;4:;5:;6:;7:PDG-RBE-BE-LBCO; C1 INRAE, UR EABX, 50 av. de Verdun, 33612, Cestas CEDEX, France. Ifremer, LBCO, Plouzané, France Univ Brest, CNRS, IRD, Ifremer, LEMAR, F-29280 Plouzane, France UMR 5805 EPOC, Université de Bordeaux I, F-33405 Talence, France C2 INRAE, FRANCE IFREMER, FRANCE IRD, FRANCE UNIV BORDEAUX, FRANCE SI BREST SE PDG-RBE-BE-LBCO UM LEMAR IN WOS Ifremer UPR WOS Cotutelle UMR copubli-france copubli-p187 copubli-univ-france IF 2.974 TC 4 UR https://archimer.ifremer.fr/doc/00643/75499/76738.pdf LA English DT Article DE ;DEB parameter estimation;full life cycle;Solea solea;POP bioaccumulation;dietary contamination;inter-individual variability AB Studying adverse effects of chemical pressure on aquatic ecosystems needs a comprehensive knowledge of bioaccumulation mechanisms of pollutants in biota to predict internal concentrations, especially for Persistent Organic Pollutants (POPs). However, the large variability of responses in measured POP concentrations requires explicit consideration of both individual variability and environmental influences. Dynamic Energy Budget (DEB) theory provides a rigorous and generic conceptual framework for tackling these questions in a relevant mechanistic way. In the present study, parameterisation and calibration of previous DEB models for Solea solea were revisited in order to accurately represent the full life cycle with an original emphasis on larval stage, metamorphosis, reproduction rules and sexual differences. We first improved calibration thanks to the use of the estimation procedure developed by the DEB network coupled with a broad compilation of data from literature. Then, we validated this set of parameter estimates on independent datasets of i) individual monitoring of larval growth in controlled food conditions from a novel experiment, and ii) juvenile and adult growth, and female fecundity, from a natural population. Finally, we combined the DEB model developed in the present paper with we used a simple toxicokinetic (TK) model from literature. This TK model was also combined to a previous DEB model and was used to reproduce the mean trajectories of a growth and contamination dataset. We applied the same TK model with our DEB model considering inter-individual variability in food availability. This application highlighted the need to accurately consider inter-individual variability in ingestion to correctly estimate growth and contamination variability. The present work is the first step in the development of a mechanistic TK model that will be used in a companion paper for investigations of juvenile sole sensitivity to warming, nursery quality and prey contamination, in highly fluctuating estuarine environments. PY 2020 PD OCT SO Ecological Modelling SN 0304-3800 PU Elsevier BV VL 433 UT 000564687300007 DI 10.1016/j.ecolmodel.2020.109224 ID 75499 ER EF