Species differences exist in terms of drug oxidation activities, which are mediated mainly by cytochrome P450 (P450) enzymes. To overcome the problem of species extrapolation, transchromosomic mice containing a human P450 3A cluster or chimeric mice transplanted with human hepatocytes have been introduced into the human toxicology research area. In this review, drug metabolism and disposition mediated by humanized livers in chimeric mice are summarized in terms of biliary/urinary excretions of phthalate and bisphenol A and plasma clearances of the human cocktail probe drugs caffeine, warfarin, omeprazole, metoprolol, and midazolam. Simulation of human plasma concentrations of the teratogen thalidomide and its human metabolites is possible with a simplified physiologically-based pharmacokinetic model based on data obtained in chimeric mice, in accordance with reported clinical thalidomide concentrations. In addition, in vivo non-specific hepatic protein binding parameters of metabolically activated 14C-drug candidate and hepatotoxic medicines in humanized liver mice can be analyzed by accelerator mass spectrometry and are useful for predictions in humans.
1. The pharmacokinetic data of cytochrome P450 probes in humans can be extrapolated from corresponding data in cynomolgus monkeys, dogs and minipigs using simplified physiologically based pharmacokinetic (PBPK) modeling. In this study, the modeling methodology was further adapted to estimate human plasma concentrations of P450 probes based on data from mice transplanted with human hepatocytes or based on data from marmosets. 2. Using known species allometric scaling factors, the observed plasma concentrations of caffeine, warfarin, omeprazole, metoprolol, and midazolam in chimeric TK-NOG mice with humanized liver were scaled to human oral monitoring equivalents. Using the same approach, the previously reported pharmacokinetics of the five P450 probes in marmosets were also scaled to reported equivalents in humans using in vitro metabolic clearance data. 3. Human plasma concentration profiles of the five P450 probes estimated by simplified human PBPK models based on the observed pharmacokinetics in mice with humanized liver and on the reported pharmacokinetics in marmosets were consistent with previously published pharmacokinetic data in Caucasians. 4. These results suggest that mice with humanized liver and/or marmosets could be suitable pharmacokinetic models for humans during research into new drugs, especially when used in combination with simple PBPK models.
Pomalidomide has been shown to be potentially teratogenic in
thalidomide-sensitive animal species such as rabbits. Screening for
thalidomide analogs devoid of
teratogenicity/toxicity—attributable to metabolites formed
by cytochrome P450 enzymes—but having immunomodulatory
properties is a strategic pathway towards development of new
anticancer drugs.In this study, plasma concentrations of pomalidomide, its
primary 5-hydroxylated metabolite, and its glucuronide conjugate(s)
were investigated in control and humanized-liver mice. Following
oral administration of pomalidomide (100 mg/kg), plasma
concentrations of 7-hydroxypomalidomide and 5-hydroxypomalidomide
glucuronide were slightly higher in humanized-liver mice than in
control mice.Simulations of human plasma concentrations of pomalidomide
were achieved with simplified physiologically-based pharmacokinetic
models in both groups of mice in accordance with reported
pomalidomide concentrations after low dose administration in
humans.The results indicate that pharmacokinetic profiles of
pomalidomide were roughly similar between control mice and
humanized-liver mice and that control and humanized-liver mice
mediated pomalidomide 5-hydroxylation in vivo.
Introducing one aromatic amino group into thalidomide resulted in
less species differences in in vivo
pharmacokinetics in control and humanized-liver mice.
-Lenalidomide has been shown to be potentially teratogenic in thalidomide-sensitive animal species. Screening for thalidomide analogs devoid of teratogenicity/toxicity-attributable to drug metabolism and disposition, but having immunomodulatory properties-is a strategic pathway towards development of new anticancer drugs. Plasma concentrations of lenalidomide were investigated in immunodeficient control and humanized-liver mice following oral administration of lenalidomide (50 mg/kg). Plasma concentrations of lenalidomide (1-2 hr after administration) were slightly but significantly higher in humanized-liver mice than in control mice (p < 0.05). Human albumin mRNA, a liver-specific toxicity marker, was found in the blood of humanized-liver mice 24 hr after lenalidomide administration. Simulations of human plasma concentrations of lenalidomide were achieved with simplified physiologically-based pharmacokinetic models in control and humanized-liver mice or by the direct fitting analysis of reported human data, in accordance with reported lenalidomide concentrations after low dose administration in humans. The results indicate that pharmacokinetic profiles of lenalidomide, a compound resulting from introducing one aromatic amino group into thalidomide and removing one keto group, resulted in less species variation in in vivo pharmacokinetics in control and humanized-liver mice and that immunodeficient humanized-liver mice can serve as experimental model animals for human liver injury in drug development at high doses, with human albumin RNA analysis in plasma.
1. The partial glucokinase activator N,N-dimethyl-5-((2-methyl-6-((5-methylpyrazin-2-yl)carbamoyl)benzofuran-4-yl)oxy)pyrimidine-2-carboxamide (PF-04937319) is biotransformed in humans to N-methyl-5-((2-methyl-6-((5-methylpyrazin-2-yl)carbamoyl)benzofuran-4-yl)oxy)pyrimidine-2-carboxamide (M1), accounting for ∼65% of total exposure at steady state. 2. As the disproportionately abundant nature of M1 could not be reliably predicted from in vitro metabolism studies, we evaluated a chimeric mouse model with humanized liver on TK-NOG background for its ability to retrospectively predict human disposition of PF-04937319. Since livers of chimeric mice were enlarged by hyperplasia and contained remnant mouse hepatocytes, hepatic intrinsic clearances normalized for liver weight, metabolite formation and liver to plasma concentration ratios were plotted against the replacement index by human hepatocytes and extrapolated to those in the virtual chimeric mouse with 100% humanized liver. 3. Semi-physiological pharmacokinetic analyses using the above parameters revealed that simulated concentration curves of PF-04937319 and M1 were approximately superimposed with the observed clinical data in humans. 4. Finally, qualitative profiling of circulating metabolites in humanized chimeric mice dosed with PF-04937319 or M1 also revealed the presence of a carbinolamide metabolite, identified in the clinical study as a human-specific metabolite. The case study demonstrates that humanized chimeric mice may be potentially useful in preclinical discovery towards studying disproportionate or human-specific metabolism of drug candidates.
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