Route-Specific Differences in Distribution Characteristics of Octamethylcyclotetrasiloxane in Rats: Analysis Using PBPK Models

doi:10.1093/toxsci/71.1.41

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Toxicological Sciences 71, 41-52 (2003)
Copyright © 2003 by the Society of Toxicology

BIOTRANSFORMATION AND TOXICOKINETICS

Route-Specific Differences in Distribution Characteristics of Octamethylcyclotetrasiloxane in Rats: Analysis Using PBPK Models

Ramesh Sarangapani^*^,1, Justin Teeguarden, Melvin E. Andersen, Richard H. Reitz and Kathleen P. Plotzke^¶^,2

^* ICF Consulting, P.O. Box 14348, Research Triangle Park, North Carolina 27709; Environ Corporation, 933 Mesa Lane, Collegeville, Pennsylvania 19426; Department of Environmental Health, CETT/Foothills Campus, Colorado State University, Ft. Collins, Colorado 80523; RHR Toxicology Consulting Services, Midland, Michigan 48640; and ^¶ Toxicology, Health and Environmental Sciences, Dow Corning Corporation, Mail CO3101, Midland, Michigan 48686

Octamethylcyclotetrasiloxane (D₄) is used in selected consumerproducts and has a potential for human exposure from multipleroutes. Here we develop a physiologically based pharmacokinetic(PBPK) model to describe the tissue dosimetry, plasma concentration,and clearance in the rat following inhalation and dermal, oral,and iv exposure. An initial multiroute PBPK model, based ona previously published inhalation PBPK model for D₄, providedexcellent fits to the observed concentration time course ofD₄ metabolites in urine and D₄ exhalation rate following dermalexposures. However, the pharmacokinetics of D₄, following oraland iv exposure, were sensitive to the mode of entry into theblood compartment. A refined model, describing delivery of D₄from the GI tract to the nonexchangeable/deep blood compartment,provided the best fits to observed plasma D₄, exhaled D₄, andD₄ metabolites excreted in the urine following oral exposure.Pharmacokinetics following iv administration was best describedby delivery of D₄ directly into the deep blood compartment,possibly reflecting a kinetically identifiable characteristicof the administration of D₄ as an emulsion for the intravenousroute of exposure. This model-based analysis indicates thatthe pharmacokinetics of D₄ delivered by the inhalation or dermalroutes is similar, and is different from the iv or oral deliveryroutes.

Key Words: inhalation, oral; dermal; iv; multiroute; pharmacokinetics; PBPK model; siloxane.

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