Publication Details |
Category | Text Publication |
Reference Category | Journals |
DOI | 10.1016/j.chemosphere.2020.127048 |
Document | accepted manuscript |
Title (Primary) | Comparison of a simple and a complex model for BCF prediction using in vitro biotransformation data |
Author | Krause, S.; Goss, K.-U. |
Source Titel | Chemosphere |
Year | 2020 |
Department | AUC |
Volume | 256 |
Page From | art. 127048 |
Language | englisch |
Keywords | Bioaccumulation; Modeling in vitro - in vivo extrapolation; Biotransformation |
Abstract | A promising approach for bioaccumulation assessment with reduced animal use is the prediction of bioconcentration factors (BCFs) using in vitro biotransformation data. However, it has been recognized that the BCFs predicted using current models often are in poor agreement with experimental BCFs. Furthermore, extrahepatic biotransformation (e.g. in gill or GIT) is usually not accounted for. Here, we compare two BCF prediction models: a simple one-compartment and a more advanced multi-compartment model. Both models are implemented in a two-in-one calculation tool for the prediction of BCFs using in vitro data. Furthermore, both models were set up in a way that in vitro data for extrahepatic biotransformation can be easily considered, if desired. The models differ in their complexity: the one-compartment model is attractive because its simplicity, while the multi-compartment model is characterized by its refined closeness to reality. A comparison of the results shows that both models yield almost identical results for the presently evaluated cases with plausible physiological data. For regulatory purposes, there is thus no reason not to use the simple one-compartment model. However, if it is desired to represent special in vivo characteristics, e.g. first-pass effects or the direct GIT-to-liver blood flow, the multi-compartment model should be used. |
Persistent UFZ Identifier | https://www.ufz.de/index.php?en=20939&ufzPublicationIdentifier=23225 |
Krause, S., Goss, K.-U. (2020): Comparison of a simple and a complex model for BCF prediction using in vitro biotransformation data Chemosphere 256 , art. 127048 10.1016/j.chemosphere.2020.127048 |