Stereoselective inhibition of nortriptyline hydroxylation in man by quinidine.

1. Four volunteers phenotyped as extensive metabolizers of sparteine took 25 mg nortriptyline hydrochloride and collected urine for 72-80 h. Total free and conjugated 10-hydroxynortriptyline (10-OH-NT) accounted for 54-58% of the dose and it was reduced to 25-40% when 50 mg quinidine sulphate was ingested on the first and second day. 2. Of the four isomers of 10-OH-NT, (-)-E-10-OH-NT was selectively decreased in quantity by quinidine coadministration, while the (+)-isomer and (-)- and (+)-Z-10-OH-NT were found in unchanged or slightly increased quantities. The contribution of (-)-E-10-OH-NT to total E-10-OH-NT and the E-/Z-ratio in total 10-OH-NT were significantly reduced. 3. The quantity of the phenol, 2-hydroxynortriptyline in urine was decreased by quinidine; the relative amounts of metabolites with a primary amino group were not affected. 4. Liver microsomes from a donor in which cytochrome P450IID6 was shown to be present by in vitro phenotyping metabolized NT to E-10-OH-NT containing 86% of the (-)-isomer. Quinidine reduced the hydroxylation rate in (-)-E-10-position much more than that in (+)-E-10-position. 5. Since quinidine selectively impairs the function of cytochrome P450IID6, it is concluded that this isoform catalyses NT hydroxylation predominantly in (-)-E-10- and in 2-position.     

Lack of inhibition of tolbutamide hydroxylation by cimetidine in man

Summary We have investigated the influence of cimetidine on the disposition of tolbutamide in 7 healthy subjects, who received 250 mg tolbutamide daily for 4 days followed by the concomitant intake of cimetidine 400 mg twice daily for a further 4 days.Cimetidine had no effect on the disposition of tolbutamide, including the unbound hydroxylation clearance rate (324 ml·min^–1, tolbutamide alone; 316 ml·min^–1, tolbutamide plus cimetidine). The total urinary recovery of carboxy- and hydroxy-tolbutamide metabolites was 85.7±20.3% of the dose when tolbutamide was given alone and 78.9±14.3% when given with cimetidine.This lack of a pharmacokinetic interaction suggests selectivity of cimetidine-induced inhibition of Phase I drug oxidation.Dawes, Curren and Hughes Research Fellow, Royal Adelaide Hospital     

Stereospecific hydroxylation of nortriptyline in man in relation to interindividual differences in its steady-state plasma level

Summary Thecis andtrans isomers of 10-hydroxynortriptyline (10-OH-NT), the major metabolite of nortriptyline (NT) in man, have been separated and quantitated in urine from 6 healthy volunteers who received NT orally, 0.4 mg/kg body weight, three times daily. The isomers were separated by preparative thin layer chromatography and quantitatively determined by gas chromatography as the 10,11-dehydronortriptyline heptafluorobutyryl derivative. The structure of these derivatives producedin vitro was confirmed by gas chromatography — mass spectrometry. Less than 1% of totally excreted 10-OH-NT was accounted for as 10,11-dehydronortriptyline. — Despite interindividual differences in the mean steady-state plasma concentration of NT, the ratio between the two isomers was constant in all subjects (1:4–5). The isomers were both optically active and circular dichroism spectra showed that the asymmetric carbon atoms in the two compounds have different configurations. — It is concluded that NT undergoes stereospecific hydroxylation in man and that there is no correlation between the mean steady-state plasma concentration of NT and the proportion of thecis andtrans isomers formed.     

Stereoselective glucuronidation and hydroxylation of etodolac by UGT1A9 and CYP2C9 in man

1.?In vitro metabolic studies with etodolac were performed. S- and R-etodolac were converted to the acylglucuronide and hydroxylated metabolites by UDP-glucuronosyltransferase (UGT) and cytochrome P450 in microsomes. However, the stereoselectivities of UGT and P450 for the isomers were opposite. S-etodolac was glucuronidated preferentially than R-etodolac by UGT. In contrast, R-etodolac was hydroxylated preferentially than S-etodolac by P450.

2.?Of several human P450 enzymes, CYP2C9 had the greatest activity for hydroxylation of R-etodolac. Sulfaphenazole, an inhibitor of CYP2C9, and anti-CYP2C9 antibody inhibited the hydroxylation of R-etodolac in human liver microsomes. CYP2C9 therefore contributes to the stereoselective hydroxylation of R-etodolac.

3.?Of several human UGT enzymes, UGT1A9 had the greatest activity for glucuronidation of S-etodolac. Propofol and thyroxine, inhibitors of UGT1A9, inhibited the glucuronidation of S-etodolac in human liver microsomes. Therefore, UGT1A9 is mainly responsible for the stereoselective glucuronidation of S-etodolac.

4.?Because S-etodolac was metabolized more rapidly than R-etodolac in human cryopreserved hepatocytes, the stereoselectivities of UGT1A9 for etodolac substantially influenced the overall metabolism of S- and R-etodolac in man.     

Stereoselective glucuronidation and hydroxylation of etodolac by UGT1A9 and CYP2C9 in man

1. In vitro metabolic studies with etodolac were performed. S- and R-etodolac were converted to the acylglucuronide and hydroxylated metabolites by UDP-glucuronosyltransferase (UGT) and cytochrome P450 in microsomes. However, the stereoselectivities of UGT and P450 for the isomers were opposite. S-etodolac was glucuronidated preferentially than R-etodolac by UGT. In contrast, R-etodolac was hydroxylated preferentially than S-etodolac by P450. 2. Of several human P450 enzymes, CYP2C9 had the greatest activity for hydroxylation of R-etodolac. Sulfaphenazole, an inhibitor of CYP2C9, and anti-CYP2C9 antibody inhibited the hydroxylation of R-etodolac in human liver microsomes. CYP2C9 therefore contributes to the stereoselective hydroxylation of R-etodolac. 3. Of several human UGT enzymes, UGT1A9 had the greatest activity for glucuronidation of S-etodolac. Propofol and thyroxine, inhibitors of UGT1A9, inhibited the glucuronidation of S-etodolac in human liver microsomes. Therefore, UGT1A9 is mainly responsible for the stereoselective glucuronidation of S-etodolac. 4. Because S-etodolac was metabolized more rapidly than R-etodolac in human cryopreserved hepatocytes, the stereoselectivities of UGT1A9 for etodolac substantially influenced the overall metabolism of S- and R-etodolac in man.     

Enantioselective hydroxylation of nortriptyline in human liver microsomes, intestinal homogenate, and patients treated with nortriptyline

The enantioselectivity of hydroxylation of nortriptyline (NT) to E-10-hydroxynortriptyline (E-10-OH-NT) was studied in human liver microsomes, intestinal homogenate, and patients treated with NT. The rate of formation of (-)-E-10-OH-NT was higher than that of (+)-E-10-OH-NT both in the liver microsomes and in the intestinal homogenate. Quinidine, a prototype competitive inhibitor of the cytochrome P450IID6 ("debrisoquin hydroxylase"), inhibited the formation of (-)-E-10-OH-NT in a concentration-dependent manner in liver microsomes, while the formation of (+)-E-10-OH-NT was hardly affected. This indicates that P450IID6 catalyzes the hydroxylation of NT in a highly enantioselective manner to (-)-E-10-OH-NT in the liver. Another P450 isozyme besides IID6 seems to be responsible for the formation of the (+)-enantiomer in the liver. In intestinal homogenate, the formation of both enantiomers of E-10-OH-NT was inhibited to about the same extent by quinidine, the maximum inhibition being much less than in the liver. In the urine of six patients treated with NT, the (-)-enantiomer accounted for 91 +/- 2% of the unconjugated E-10-OH-NT, and for 78 +/- 6% of the glucuronide conjugates. The study shows that NT is hydroxylated in a highly enantioselective way, probably catalyzed by the polymorphic P450IID6, to (-)-E-10-OH-NT both in vitro in human liver as well as in vivo in patients treated with the drug.     

Stereoselective and regiospecific hydroxylation of ketamine and norketamine

1. The objective was to determine the cytochrome P450s (CYPs) responsible for the stereoselective and regiospecific hydroxylation of ketamine [(R,S)-Ket] to diastereomeric hydroxyketamines, (2S,6S;2R,6R)-HK (5a) and (2S,6R;2R,6S)-HK (5b) and norketamine [(R,S)-norKet] to hydroxynorketamines, (2S,6S;2R,6R)-HNK (4a), (2S,6R;2R,6S)-HNK (4b), (2S,5S;2R,5R)-HNK (4c), (2S,4S;2R,4R)-HNK (4d), (2S,4R;2R,4S)-HNK (4e), (2S,5R;2R,5S)-HNK (4f).

2. The enantiomers of Ket and norKet were incubated with characterized human liver microsomes (HLMs) and expressed CYPs. Metabolites were identified and quantified using LC/MS/MS and apparent kinetic constants estimated using single-site Michaelis–Menten, Hill or substrate inhibition equation.

3. ?5a was predominantly formed from (S)-Ket by CYP2A6 and N-demethylated to 4a by CYP2B6. 5b was formed from (R)- and (S)-Ket by CYP3A4/3A5 and N-demethylated to 4b by multiple enzymes. norKet incubation produced 4a, 4c and 4f and minor amounts of 4d and 4e. CYP2A6 and CYP2B6 were the major enzymes responsible for the formation of 4a, 4d and 4f, and CYP3A4/3A5 for the formation of 4e. The 4b metabolite was not detected in the norKet incubates.

4. ?5a and 4b were detected in plasma samples from patients receiving (R,S)-Ket, indicating that 5a and 5b are significant Ket metabolites. Large variations in HNK concentrations were observed suggesting that pharmacogenetics and/or metabolic drug interactions may play a role in therapeutic response.

     

Stereoselective and regiospecific hydroxylation of ketamine and norketamine

The objective was to determine the cytochrome P450s (CYPs) responsible for the stereoselective and regiospecific hydroxylation of ketamine [(R,S)-Ket] to diastereomeric hydroxyketamines, (2S,6S;2R,6R)-HK (5a) and (2S,6R;2R,6S)-HK (5b) and norketamine [(R,S)-norKet] to hydroxynorketamines, (2S,6S;2R,6R)-HNK (4a), (2S,6R;2R,6S)-HNK (4b), (2S,5S;2R,5R)-HNK (4c), (2S,4S;2R,4R)-HNK (4d), (2S,4R;2R,4S)-HNK (4e), (2S,5R;2R,5S)-HNK (4f). The enantiomers of Ket and norKet were incubated with characterized human liver microsomes (HLMs) and expressed CYPs. Metabolites were identified and quantified using LC/MS/MS and apparent kinetic constants estimated using single-site Michaelis-Menten, Hill or substrate inhibition equation. 5a was predominantly formed from (S)-Ket by CYP2A6 and N-demethylated to 4a by CYP2B6. 5b was formed from (R)- and (S)-Ket by CYP3A4/3A5 and N-demethylated to 4b by multiple enzymes. norKet incubation produced 4a, 4c and 4f and minor amounts of 4d and 4e. CYP2A6 and CYP2B6 were the major enzymes responsible for the formation of 4a, 4d and 4f, and CYP3A4/3A5 for the formation of 4e. The 4b metabolite was not detected in the norKet incubates. 5a and 4b were detected in plasma samples from patients receiving (R,S)-Ket, indicating that 5a and 5b are significant Ket metabolites. Large variations in HNK concentrations were observed suggesting that pharmacogenetics and/or metabolic drug interactions may play a role in therapeutic response.     

Stereoselective disposition of talinolol in man

The disposition of the beta-blocking drug talinolol is controlled by P-glycoprotein in man. Because talinolol is marketed as a racemate, we reevaluated the serum-concentration time profiles of talinolol of a previously published study with single intravenous (30 mg) and repeated oral talinolol (100 mg for 14 days) before and after comedication of rifampicin (600 mg per day for 9 days) in eight male healthy volunteers (age 22-26 years, body weight 67-84 kg) with respect to differences in the kinetic profiles of the two enantiomers S(-) talinolol and R(+) talinolol. Additionally, the metabolism of talinolol in human liver microsomes was examined. After oral administration, S(-) talinolol was slightly less absorbed and faster eliminated than R(+) talinolol. The absolute bioavailabilty of the R(+) enantiomer of talinolol was slightly but significantly higher than of its S(-) enantiomer. Coadministration of rifampicin further intensified this difference in the disposition of R(+) and S(-) talinolol (p < 0.05). Formation of 4-trans hydroxytalinolol was the major metabolic pathway in human liver microsomes. All Cl(int) values of S(-) were higher than of R(+) talinolol; 0.1 microM ketoconazole inhibited the formation of all metabolites. In conclusion, the stereoselectivity of talinolol disposition is of minor importance, and most likely caused by presystemic biotransformation via CYP3A4. The less active R(+) talinolol might be suitable for phenotyping P-glycoprotein expression in man.     

Stereoselective inhibition of synaptosomal catecholamine uptake by nomifensine

The effects of the two enantiomers of the antidepressant nomifensine on catecholamine uptake were investigated using rat brain synaptosomes. According to the results from in vitro and ex vivo/in vitro studies, the inhibitory activity on catecholamine uptake resides entirely in the (+)-form of nomifensine. Further studies comparing the antidepressant effects of the two enantiomers might help to clarify the validity of the catecholamine hypothesis of depression.     

In vitro inhibition of midazolam and quinidine metabolism by flavonoids

Studies in humans in vivo have demonstrated that substances found in grapefruit juice may increase the bioavailability of dihydropyridine derivatives as a result of the inhibition of liver enzyme activities by flavonoids found in grapefruit. Since the metabolism of dihydropyridine drugs is mediated by cytochrome P-450 (CYP) 3A4, it has been hypothesized that flavonoids may also influence the metabolism of other drugs, such as midazolam and quinidine, which are biotransformed by the same CYP isoform. Three flavonoids, kaempferol, naringenin and quercetin, are found in grapefruit juice but not in orange juice. The effect of these substances on the metabolism of midazolam and quinidine has been investigated in human liver microsomes. In the concentration range 10–160 M the inhibitory potential of flavonoids was the same for both of the tested drugs; it decreased in the order quercetin kaempferol > naringenin. The data suggest that the flavonoids found in grapefruit juice may influence the kinetics of midazolam and quinidine in man.     

Stereoselective disposition of mexiletine in man.

The pharmacokinetics of S-(+)- and R-(-)-mexiletine and of the corresponding conjugates were investigated in six healthy young volunteers after administration of a single 200 mg oral dose of racemic mexiletine hydrochloride. The values for the distribution rate constants as well as for the elimination half-lives of the two enantiomers were similar but the AUC of the S-(+)-enantiomer was always significantly higher (P less than 0.01) than that of the opposite enantiomer. The mean R/S ratios for unchanged mexiletine in serum and in urine were 0.78 +/- 0.12 (s.d.) and 0.80 +/- 0.21, respectively. Urinary excretion of mexiletine conjugates consisted mainly of the R-(-)-enantiomer; the mean R/S enantiomeric ratio over 48 h was 9.65 +/- 3.10. Serum concentrations of the conjugates were measured in three subjects. The mean R/S AUC ratio was 2.94 +/- 0.48 and the renal clearance of the R-(-)-enantiomer was significantly higher (P less than 0.02) than that of the S-(+)-enantiomer.     

The specificity of inhibition of debrisoquine 4-hydroxylase activity by quinidine and quinine in the rat is the inverse of that in man

The kinetics of inhibition of debrisoquine 4-hydroxylase activity by quinidine and quinine in rat and human liver microsomes have been compared. Quinidine is a potent inhibitor of debrisoquine 4-hydroxylase activity of human liver (IC50: 3.6 microM). However, its stereoisomer, quinine, is some 60 times less potent (IC50:223 microM). Both compounds are able to inhibit greater than 95% of 4-hydroxylase activity. In rat liver microsomes quinine is approximately 50 times more potent an inhibitor (IC50:2.4 microM) than quinidine (IC50:137 microM). Again, 4-hydroxylase activity is inhibited by greater than 95%. Inhibition of debrisoquine 4-hydroxylase activity by both quinine and quinidine in human and rat liver is competitive. Values of Ki for quinidine in human and rat were 0.6 microM and 50 microM, whereas with quinidine the Ki values were 13 microM and 1.7 microM, respectively. The data in this paper are consistent with 4-hydroxylation of debrisoquine in both rat and human liver catalysed by a specific form of cytochrome P-450. Although both quinidine and quinine are competitive inhibitors of debrisoquine 4-hydroxylase activity in rat and man, their potency is reversed. This suggests that the nature of the active site of cytochrome P-450dbl differs between the two species, and indicates that data on the specificity of this isoenzyme in the rat should be extrapolated to man with extreme caution.     

Stereoselective pharmacokinetics of disopyramide enantiomers in man

The plasma protein binding and pharmacokinetics of S(+)-disopyramide and R(-)-disopyramide following infusions of 100 mg were compared in five healthy human volunteers. The binding of S(+)-disopyramide was higher than that of R(-)-disopyramide at similar unbound concentrations in all subjects. The association constant characterizing the interaction between plasma protein and the S(+)- and R(-)-enantiomers was 17.1 X 10(5) M-1, and 7.68 X respectively. The unbound clearance and half-life of S(+)-disopyramide averaged 604 ml/min and 3.67 hr, respectively, and differed from that of R(-)-disopyramide, which averaged 401 ml/min and 4.62 hr, respectively. Both enantiomers appear to undergo active tubular secretion. The unbound renal clearance of the S(+)- and R(-)-enantiomers averaged 338 and 182 ml/min, respectively (p = 0.05). The unbound steady-state volume of distribution of S(+)- and R(-)-disopyramide averaged 172 and 141 liters, respectively (p = 0.14). The renal clearance of the mono-N-dealkylated metabolite of disopyramide following the administration of S(+)- and R(-)-disopyramide averaged 345 and 170 ml/min, respectively (p less than 0.05).