Preclinical metabolism and the disposition of vornorexant/TS-142, a novel dual orexin 1/2 receptor antagonist for the treatment of insomnia.

We investigated the metabolism and disposition of vornorexant, a novel dual orexin receptor antagonist, in rats and dogs, and clarified in vitro metabolite profiles in humans. Furthermore, we investigated the pharmacokinetics of active metabolites in rats and dogs and their CNS distribution in rats to elucidate its contribution to drug efficacy. [14 C]vornorexant was rapidly and mostly absorbed after the oral administration in rats and dogs. The drug-derived radioactivity, including metabolites, was distributed to major organs such as the liver, kidneys in rats, and was almost eliminated within 24 h post-dose in both species. Metabolite profiling revealed that main clearance mechanism of vornorexant was metabolism via multiple pathways by oxidation. The major circulating components were the cleaved metabolites (M10, M12) in rats, and the unchanged form in dogs, followed by M1, and then M3. Incubation with human hepatocytes resulted in formation of metabolites, including M1, M3, M10, and M12. The metabolic pathways were similar in all tested species. Resulting from the PK and CNS distribution of active metabolites (M1 and M3) with weaker pharmacological activity, the concentration of the unchanged form was higher than that of active metabolites in rat CSF and dog plasma, suggesting that the unchanged form mainly contributed to the drug efficacy. These findings demonstrate that vornorexant is absorbed immediately after administration, and vornorexant and its metabolites are rapidly and completely eliminated in rats and dogs. Thus, vornorexant may have favorable pharmacokinetic profiles as a hypnotic drug to provide rapid onset of action and minimal next-day residual effects in humans.

Drug-drug interaction potential and clinical pharmacokinetics of enerisant, a novel potent and selective histamine H3 receptor antagonist.

We evaluated the in vitro drug-drug interaction (DDI) potential of enerisant (TS-091), a histamine H3 receptor antagonist/inverse agonist, mediated by cytochrome P450 (CYP) and transporters, as well as the pharmacokinetics of enerisant in healthy male subjects.Enerisant did not inhibit CYP1A2, CYP2A6, CYP2B6, CYP2C8, CYP2C9, CYP2C19, CYP2D6, CYP2E1, or CYP3A4 and did not induce CYP1A2, CYP2B6, or CYP3A4. Enerisant inhibited organic cation transporter 2, multidrug and toxin extrusion protein (MATE) 1, and MATE2-K, but not P-glycoprotein (P-gp), breast cancer resistance protein, organic anion transporting polypeptide (OATP) 1B1, OATP1B3, organic anion transporter (OAT) 1, or OAT3. Enerisant was a substrate for P-gp, but not for eight other transporters.In healthy male subjects, enerisant was rapidly absorbed after oral administration, and the plasma concentration increased dose-dependently. The urinary excretion of enerisant within 48 h after administration was 64.5% to 89.9% of the dose, indicating that most of the absorbed enerisant was excreted in the urine without being metabolized.Based on the plasma concentrations at the estimated clinical dose, enerisant is unlikely to cause CYP-mediated, clinically relevant DDI. Although the possibility of transporter-mediated, clinically relevant DDI cannot be ruled out, there is little or no risk of side effects.

Usefulness of rat skin as a substitute for human skin in the in vitro skin permeation study.

Sprague-Dawley (SD) rats are broadly used in preclinical studies for drug development, so a lot of information for the rats can be obtained especially from pharmacokinetic, pharmacological and toxicological studies. The purpose of this study was to clarify whether SD rat skin can be used to predict human skin permeability. In vitro permeation studies of the three model drugs, nicorandil, isosorbide dinitrate, and flurbiprofen, through human skin and SD rat skin were performed using Franz-type diffusion cells. The permeation rates of the three model drugs through human skin and SD rat skin were determined, and their variations were evaluated. The inter-individual variations in SD rat skin permeability of the three model drugs were much lower than that in human skin permeability, although the permeation rates of the three model drugs through the SD rat skin were about twice those through human skin. In addition, no difference in the skin permeability coefficients of the three model drugs was obtained between fresh SD rat skin and frozen SD rat skin. The markedly smaller variation in the permeability through SD rat skin compared with that through human skin indicated that in vitro permeation studies using SD rat skin would be especially useful for evaluating differences in the skin permeability of the three model drugs as well as for predicting human skin permeability.

Variation assessment for in vitro permeabilities through Yucatan micropig skin.

The purpose of this study was to evaluate the variations in the in vitro Yucatan micropig (YMP) skin permeabilities of drugs and to clarify whether YMP skin can be used to predict human skin permeability. In vitro permeation studies of the three model drugs, nicorandil, isosorbide dinitrate and flurbiprofen, through YMP skin were performed using Franz-type diffusion cells. The permeation rates of the three model drugs were determined, and their variations were evaluated. The inter-individual variations in YMP skin permeability for the three model drugs were smaller than that in human skin permeability, and the permeation rates of the three model drugs through the YMP skin were approximately half that through human skin. In addition, the intra-individual variations in YMP skin permeability for nicorandil and flurbiprofen were much smaller than the inter-individual variations in YMP skin. The inter- and intra-regional variations in YMP skin permeability were very small. The markedly smaller variation in the permeability through YMP skin as compared with that through human skin indicated that in vitro permeation studies using YMP skin would be particularly useful for evaluating differences in the skin permeability of the three model drugs as well as for predicting human skin permeability.

Long-term pharmacokinetic efficacy and safety of low-dose ritonavir as a booster and atazanavir pharmaceutical formulation based on solid dispersion system in rats.

Atazanavir (ATV) is clinically coadministered with low-dose ritonavir (RTV), which boosts the oral bioavailability (BA) of ATV by inhibiting cytochrome P450 (CYP) 3A, and P-glycoprotein (Pgp) via the same metabolic pathway; however, it is well known that in the chronic phase, the inhibition effect of RTV on Pgp and CYP3A becomes an induction effect. In this study, we investigated the long-term efficacy and safety of RTV-boosted ATV in rats with a clinical relevant dosage of ATV and RTV, 7 mg/kg and 2 mg/kg, respectively, and drew a direct comparison with RTV-boosted ATV and the previously reported ATV pharmaceutical formulation based on a solid dispersion system (ATV-SLS SD+G). Rats received RTV-boosted ATV or ATV-SLS SD+G for 14 d in the pharmacokinetic study. In addition, after 14-d repeated administration of each formulation, cyclosporine A (CyA) was administered to rats and Western blot analysis of Pgp and CYP3A was performed to investigate the impact on pharmacokinetic interaction of each ATV formulation. After repeated administration of both formulations, there was no significant difference between ATV pharmacokinetic parameters on day 1 and 14; therefore, it was considered that the long-term efficacy of both ATV formulations was maintained. However, after treatment with RTV-boosted ATV, the Cmax and AUC0-infinity of the following CyA significantly decreased to 49% and 47% in comparison to the control, respectively, and the Pgp expression in the small intestine by Western blot analysis was approximately 2-fold higher than the control, whereas after treatment with ATV pharmaceutical formulation, neither significant alteration of CyA nor notable change in the expression of intestinal Pgp and hepatic CYP3A was observed. Therefore, it was considered that the BA of CyA after treatment with RTV-boosted ATV would decrease by the induction effect of RTV in chronic phase as described above. The results of this study revealed that the chronic use of low-dose RTV as a booster has great potential to compromise drug-drug interactions; therefore, it is recommended that the BA of protease inhibitors be improved by a pharmaceutical approach without pharmacokinetic interaction by RTV.

Pharmaceutical approach to HIV protease inhibitor atazanavir for bioavailability enhancement based on solid dispersion system.

Atazanavir (ATV) is a low oral bioavailability (BA) compound and, clinically, is generally coadministrated with ritonavir (RTV), which boosts the oral BA of ATV by inhibiting cytochrome P450 (CYP) 3A, and P-glycoprotein (Pgp) via the same metabolic pathway. However, depending on pharmacokinetic interaction, RTV-boosted ATV has great potential for other comedication. In this study we demonstrated the pharmaceutical approach to BA improvement of ATV without RTV in rats, based on the solid dispersion system using sodium lauryl sulfate (SLS) as a carrier and Gelucire 50/13 as an absorption enhancer. ATV solid dispersions in SLS were prepared by a conventional solvent method and, at ratios of ATV to SLS of 1 : 2 and 1 : 3, were demonstrated to form an amorphous state in powder X-ray diffraction (PXRD) analysis and exhibited 2.26- and 2.36-fold improvement in a dissolution test in comparison to bulk ATV, respectively. After oral administration to rats, ATV solid dispersion in SLS at a ratio of 1 : 2 showed a 3.5-fold increase in BA compared with bulk ATV. Moreover, the addition of Gelucire 50/13 to ATV solid dispersion, at a total ratio of Gelucire 50/13, ATV and SLS 1 : 1 : 2 gave 7.0- and 4.7-fold increase in Cmax and BA compared with bulk ATV, respectively, when the relative BA to RTV-boosted ATV reached 93%. The results in this study proved that a pharmaceutical approach could improve the bioavailability of ATV without pharmacokinetic interaction with RTV.

Effect of chronic administration of ritonavir on function of cytochrome P450 3A and P-glycoprotein in rats.

Ritonavir (RTV) is well known as an inhibitor of many drugs that are metabolized by cytochrome P450 (CYP) 3A or fluxed via P-glycoprotein (Pgp), although it is also reported that RTV is a potent inducer for them. In this study, to elucidate these contradictory phenomena, functional changes of CYP3A or Pgp during chronic administration of RTV were examined in rats. After pretreatment with RTV for indicated days (day 3-day 14), rats were used in the experiments. The area under the plasma drug concentration vs. time curve (AUC(0-infinity)) after oral administration of RTV (20 mg/kg) to these rats showed an RTV-treatment period-dependent decrease, and the mean AUC(0-infinity) of RTV in Day 14 rats decreased significantly by 57% as compared to the control. The AUC(0-infinity) after intravenous (i.v.) administration of RTV to Day 3 and Day 5 rats increased significantly by 28% and 22%, respectively, while there were no significant changes in the AUC(0-infinity) in Day 7 and Day 14 rats as compared to the control. As for i.v. administration of erythromycin (EM) or midazolam (MDZ) to RTV-treated rats, the AUC(0-infinity)in Day 3 and Day 5 rats increased significantly as compared to the control, while in Day 7 rats and rifampicin-treated rats, the AUC(0-infinity) of EM decreased significantly by 82% and 42%, respectively, as compared to the control. For MDZ, there were no significant changes in the AUC(0-infinity) in Day 7 or Day 14 rats. After i.v. administration of rhodamine123 (Rho123), the excretion clearances from blood circulation to the intestinal lumen and the biliary excretion clearances in Day 14 rats increased markedly by 2.2-fold and 2.6-fold as compared to the control. It has been confirmed that RTV is not only a potent inhibitor but also a potent inducer of CYP3A, and that RTV is a potent inducer of intestinal Pgp. This property of RTV is responsible for regulating the oral bioavailability of drugs that are mediated by CYP3A and Pgp.