Setsuko Komuro

Characterization of the enzymes involved in the in vitro metabolism of amrubicin hydrochloride

The in vitro metabolism of amrubicin by rat and human liver microsomes and cytosol was examined. The main metabolic routes in both species were reductive deglycosylation and carbonyl group reduction in the side-chain. In vitro metabolism of amrubicinol by rat and human liver microsomes and cytosol was also examined and the main metabolic route of this active metabolite was reductive deglycosylation. Metabolism of amrubicin in human liver microsomes was inhibited by TlCl3 and that in human liver cytosol was inhibited by dicumarol and quercetin. Generation of amrubicinol was inhibited only by quercetin. The results indicate that metabolism of amrubicin is mediated by NADPH-cytochrome P450 reductase, NADPH:quinone oxidoreductase and carbonyl reductase. In addition, generation of amrubicinol is mediated by carbonyl reductase. Metabolism of amrubicinol in human liver microsomes was inhibited by TlCl3 and that in human liver cytosol was inhibited by dicumarol. The results indicate that metabolism of amrubicinol is mediated by NADPH-cytochrome P450 reductase and NADPH:quinone oxidoreductase. To investigate the influence of cisplatin on the metabolism of amrubicin and amrubicinol, human liver microsomes and cytosol were pre-incubated with cisplatin. This did not change the rates of amrubicin and amrubicinol metabolism in either human liver microsomes or cytosol.

In vivo and in vitro pharmacokinetics and metabolism studies of 26,26,26,27,27,27-F6-1,25(OH)2 vitamin D3 (Falecalcitriol) in rat: induction of vitamin D3-24-hydroxylase (CYP24) responsible for 23S-hydroxylation in target tissues and the drop in serum levels.

1. 26,26,26,27,27,27-F6,-1,25(OH)2 vitamin D3, Falecalcitriol, the hexafluorinated analogue of 1,25(OH)2 vitamin D3, has been reported to be several times more potent than the parent compound regarding some vitamin D actions. The reason for enhanced biological activity appears related to F6-1,25(OH)2 vitamin D3 metabolism to F6-1,23S,25(OH)3 vitamin D3, a bioactive 23S-hydroxylated form which is resistant to further metabolism. 2. In the present in vivo studies, the repeated oral administration of [3H]F6-1,25(OH)2 vitamin D3 to rat resulted in a significant reduction of the radioactivity and the F6-1,25(OH)2 vitamin D3 concentrations in serum, especially at the 2 h maximum point after each dosing. Additionally, F6-1,23S,25(OH)3 vitamin D3 in the serum and small intestine was increased by the prior administration of F6-1,25(OH)2 vitamin D3. 3. Further in vitro investigation showed [3H]F6-1,25(OH)2 vitamin D3 to be metabolized to F6-1,23S,25(OH)3 vitamin D3 by kidney and small intestine homogenates of rat, the reaction being increased by the prior administration of F6-1,25(OH)2 vitamin D3. Moreover, this latter treatment was associated with a marked increase of CYP24 mRNA in the small intestine within 4 h after dosing. 4. The results indicate that in vivo metabolism of F6-1,25(OH)2 vitamin D3 to F6-1,23S,25(OH)3 vitamin D3 is catalysed by CYP24, the enzyme being induced by prior substrate exposure.

In vitro metabolism of perospirone in rat, monkey and human liver microsomes.

SummaryIn vitro metabolism of perospirone was examined with rat, monkey and human liver S9, human liver microsomes and yeast microsomes expressing human P450, using14C labeled perospirone. With rat liver S9, the major metabolites were MX9 and ID-11614, produced by cleavage at the butylene chain. However, some butylene non-cleavage and hydration of the cyclohexane ring were found, although limited in extent. Unknown metabolites accounted for about 10% of the total. After incubation for 10 minutes with monkey liver S9, the major metabolites were ID-15036 and MX11, hydrated in the cyclohexane ring. After incubation for 60 minutes, ID-15001, i.e. the butylene chain cleavage type increased. Unknown metabolites accounted for about 20%. After incubation for 10 minutes with human liver S9, the major metabolite was ID-15036, hydrated in the cyclohexane ring. In addition, MX11 and many unknown metabolites were evident. After incubation for 60 minutes, the butylene chain cleavage type and unknown metabolites increased. Individual differences were found in the metabolic reaction rate. With human liver microsomes, MX11, ID-15001 and unknown metabolites were again the major metabolites. With yeast microsomes expressing human P450 subtypes, CYP1A1, 2C8, 2D6, 3A4 were responsible for the metabolism in particular, and CYP3A4 contributes greatly. Therefore it is unlikely that genetic polymorphism will arise a present a problem with regard to the clinical drug.The results demonstrated that the main metabolic pathway in human liver S9 and liver microsomes involve oxidation at cyclohexane, oxidative cleavage of the butylene side chain and S-oxidation. The same was the case in rat and monkey S9, but species differences were found in the proportions of the metabolites produced.

Distribution and metabolism of F6-1,25(OH)2 Vitamin D3 and 1,25(OH)2 Vitamin D3 in the bones of rats dosed with tritium-labeled compounds

26,26,26,27,27,27-Hexafluo-1,25(OH)2 vitamin D3, the hexafluorinated analog of 1,25(OH)2 vitamin D3, has been reported to be several times more potent than the parent compound regarding some vitamin D actions. The reason for enhanced biologic activity in the kidneys and small intestine appears to be related to F6-1,25(OH)2 vitamin D3 metabolism to ST-232, 26,26,26,27,27,27-hexafluoro-1 alpha, 23S,25-trihydroxyvitamin D3, a bioactive 23S-hydroxylated form that is resistant to further metabolism. Since F6-1,25(OH)2 vitamin D3 is considered to prevent osteoporotic decrease in bone mass by suppressing bone turnover, we here compared the distribution and metabolism of [1 beta-3H]F6-1,25(OH)2 vitamin D3 and [1 beta-3H]1,25(OH)2 vitamin D3 in bones of rats by autoradiography and radio-HPLC. In the dosed groups, radioactivity was detected locally in the metaphysis, the modeling site in bones. As compared with the [1 beta-3H]1,25(OH)2 vitamin D3 case, [1 beta-3H]F6-1,25(OH)2 vitamin D3 was significantly retained in this site, and moreover, it mainly persisted as unchanged compound and ST-232. These findings indicate that the reason for the higher potency of F6-1,25(OH)2 vitamin D3 than 1,25(OH)2 vitamin D3 in bones are linked with increased distribution and reduced metabolism.

Long-term disposition of a novel lipophilic platinum complex SM-11355 in dog after intrahepatic arterial administration: highly sensitive detection of platinum and radioactivity

1. The disposition of SM-11355, an anticancer platinum complex for hepatocellular carcinoma, was investigated in dog by measuring platinum (Pt) and radioactivity levels following intrahepatic arterial administration of 14C-SM-11355 suspended in Lipiodol, an oily lymphographic agent. Plasma and excretion profiles were monitored in six animals, with tissue distribution studied after 1 day, 4 and 13 weeks (n = 2/time point). 2. SM-11355 was released very slowly into the systemic circulation from Lipiodol, resulting in very low levels of Pt compounds in plasma, urine, faeces and organs. Plasma levels of Pt and radioactivity declined with apparent half-lives of 5-7 weeks. Excretion continued even at 3 months after the administration with proportions excreted for Pt and radioactivity up to 30-60% in urine and 8-10% in faeces. 3. The Pt and radioactivity in the liver accounted for 80-100% of the dose at 1 day and for 20-50% at 13 weeks after the administration, predominately as intact SM-11355. The concentrations were highest in the left lobe of the liver, the administration site, but levels in the remainder of the liver were also markedly higher than those in plasma and other tissues. 4. The results strongly support the concept that SM-11355 targets the liver with highly selectivity and sustained release of Pt compounds.

In vitro drug-drug interactions with perospirone and concomitantly administered drugs in human liver microsomes

SummaryIn vitro metabolism studies were conducted to assess drug-drug interactions between perospirone, an antipsychotic agent, and concomitantly administered drugs — biperiden, flunitrazepam, haloperidol, and diazepam — using human liver microsomes. The metabolism of perospirone in the presence of 100 μg/ml drugs was decreased to 45–73% of that in their absence, whereas no effects were observed with any of the drugs at 1 μg/ml or lower. The effects of perospirone on the metabolism of concomitantly administered drugs were also assessed, and no inhibitory effect was observed. Thus, the metabolism of perospirone and concomitantly administered drugs did not demonstrate any marked mutual inhibition in the human liver microsomes. On the other hand, the perospirone metabolism was markedly reduced by ketoconazole indicating a major role for CYP 3A4. Based on the inhibition constant (Ki) for perospirone metabolism and the plasma unbound concentration of ketoconazole,in vivo perospirone clearance was estimated to be reduced to 64–90% of the control level. Thus careful attention should be paid to the possibility of increase in unchanged perospirone concentration when perospirone is co-administered with drugs that are known as CYP3A4 inhibitors, including macrolide antibiotics and other imidazole antifungals.

Distribution of Perospirone to Melanin in Pigmented Rats

SummaryFollowing the administration of [Carbonyl-14C]perospirone ([CO-14C]perospirone) and [isothiazolyl-3-14C]perospirone ([TH-14C]perospirone) to male-pigmented rats at a single oral dose of 10 mg/kg, serum radioactivity reached maxima of 499 ng eq./g and 446 ng eq./g, respectively, at 1 hour, then decreased rapidly to below 2 ng eq./g at 168 hours, and radioactivity in eyeballs reached maxima of 576 ng eq./g and 3449 ng eq./g, respectively, at 24 hours, then decreasing slowly to become 120 ng eq./g and 314 ng eq./g at 26 weeks. Apparent elimination half-lives of radioactivity in eyeballs were 197 and 126 days for [CO-14C]perospirone and [TH-14C]perospirone, respectively. With radioluminograms, radioactivity was detected specifically in the uvea, reaching maxima at 168 hours for [CO-14C]perospirone and at 24 hours for [TH-14C]perospirone.In addition to unchanged compound, many metabolites were found in serum and eyeballs, but those were also detectable in SD albino rats and cynomolgus monkeys. Among radioactive components in eyeballs after administration of [CO-14C]perospirone, ratios of ID-15036 and MX11 followed by unchanged compound and MX9 are high. After administration of [TH-14C]perospirone ID-11614 accounted for nearly half of the radioactivity. Values decreased in line with radioactivity in eyeballs over time and 26 weeks only a few polar metabolites could be detected.