Deltamethrin (DLT) is a type II pyrethroid insecticide widely used in agriculture and public health. DLT is a potent neurotoxin that is primarily cleared from the body by metabolism. To better understand the dosimetry of DLT in the central nervous system, a physiologically based pharmacokinetic (PBPK) model for DLT was constructed for the adult, male Sprague-Dawley rat that employed both flow-limited (brain, gastrointestinal [GI] tract, liver, and rapidly perfused tissues) and diffusion-limited (fat, blood/plasma, and slowly perfused tissues) rate equations. The blood was divided into plasma and erythrocytes. Cytochrome P450-mediated metabolism was accounted for in the liver and carboxylesterase (CaE)-mediated metabolism in plasma and liver. Serial blood, brain, and fat samples were taken for DLT analysis for up to 48 h after adult rats received 2 or 10 mg DLT/kg po. Hepatic biotransformation accounted for approximately 78% of these administered doses. Plasma CaEs accounted for biotransformation of approximately 8% of each dosage. Refined PBPK model forecasts compared favorably to the 2- and 10-mg/kg po blood, plasma, brain, and fat DLT profiles, as well as profiles subsequently obtained from adult rats given 1 mg/kg iv. DLT kinetic profiles extracted from published reports of oral and iv experiments were also used for verification of the model's simulations. There was generally good agreement in most instances between predicted and the limited amount of empirical data. It became clear from our modeling efforts that there is considerably more to be learned about processes that govern GI absorption and exsorption, transport, binding, brain uptake and egress, fat deposition, and systemic elimination of DLT and other pyrethroids. The current model can serve as a foundation for construction of models for other pyrethroids and can be improved as more definitive information on DLT kinetic processes becomes available.