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KINETIC MODELING OF B-CHLOROPRENE METABOLISM:II. THE APPLICATION OF PHYSIOLOGICALLY BASED MODELLING FOR CANCER DOSE RESPONSE ANALYSIS
Citation:
Himmelstein, M., S. C. Carpenter, M V. Evans, Hinderliter,PM, AND E M. Kenyon. KINETIC MODELING OF B-CHLOROPRENE METABOLISM:II. THE APPLICATION OF PHYSIOLOGICALLY BASED MODELLING FOR CANCER DOSE RESPONSE ANALYSIS. TOXICOLOGICAL SCIENCES. Society of Toxicology, RESTON, VA, 79(1):28-37, (2004).
Description:
ABSTRACT
beta-Chloroprene (2-chloro-1,3-butadiene, CD) which is used in the synthesis of polychloroprene, caused significant incidences of several tumor types in B6C3F1 mice and Fischer rats, but not in Wistar rats or Syrian hamsters. This project investigates the relevance of the bioassay lung tumor findings to human health risk by developing a physiologically-based toxicokinetic (PBTK) model and exploring a tissue specific exposure-dose-response relationship. Key steps included identification of the plausible genotoxic mode of action, experimental quantification of tissue-to-air partition coefficients, scaling of in vitro parameters of CD metabolism for input into the PBTK model, comparing the model with in vivo experimental gas uptake data, selecting an appropriate tissue dosimetric, and predicting a corresponding human exposure concentration. The total daily milligram amount of CD metabolized per gram of lung was compared with the animal bioassay response data, specifically combined bronchiolar adenoma/carcinoma. The faster rate of metabolism in mouse lung agreed with the markedly greater incidence of lung tumors compared with the other rodent species. A lung tissue dose was predicted for the combined rodent lung tumor bioassay data at a 10% benchmark response. A human version of the PBTK model predicted that the lung tissue dose in humans would be equivalent to continuous lifetime daily exposure of 23 ppm CD. PBTK model sensitivity analysis indicated greater dependence of model prediction of dosimetry on physiological than biochemical parameters. The combined analysis of lung tumor response across species using the PBTK-derived internal dose provides an improved alternative to default pharmacokinetic interspecies adjustments for application to human health risk assessment.