Pharmacogenetics of mephenytoin: a new drug hydroxylation polymorphism in man

Polymorphic cytochromes P450 and drugs used in psychiatry

1. The cytochrome P450 monooxygenases, CYP2D6, CYP2C19, and CYP2C9, display polymorphism. CYP2D6 and CYP2C19 have been studied extensively, and despite their low abundance in the liver, they catalyze the metabolism of many drugs. 2. CYP2D6 has numerous allelic variants, whereas CYP2C19 has only two. Most variants are translated into inactive, truncated protein or fail to express protein. 3. CYP2C9 is expressed as the wild-type enzyme and has two variants, in each of which one amino acid residue has been replaced. 4. The nucleotide base sequences of the cDNAs of the three polymorphic genes and their variants have been determined, and the proteins derived from these genes have been characterized. 5. An absence of CYP2D6 and/or CYP2C19 in an individual produces a poor metabolizer (PM) of drugs that are substrates of these enzymes. 6. When two drugs that are substrates for a polymorphic CYP enzyme are administered concomitantly, each will compete for that enzyme and competitively inhibit the metabolism of the other substrate. This can result in toxicity. 7. Patients can be readily phenotyped or genotyped to determine their CYP2D6 or CYP2C19 enzymatic status. Poor metabolizers (PMs), extensive metabolizers (EMs), and ultrarapid metabolizers (URMs) can be identified. 8. Numerous substrates and inhibitors of CYP2D6, CYP2C19, and CYP2C9 are identified. 9. An individual's diet and age can influence CYP enzyme activity. 10. CYP2D6 polymorphism has been associated with the risk of onset of various illnesses, including cancer, schizophrenia, Parkinson's disease, Alzheimer's disease, and epilepsy.

CYP2C19 genotype does not represent a genetic predisposition in idiopathic systemic lupus erythematosus

BACKGROUND

The aetiology of systemic lupus erythematosus (SLE) is still unknown. In several cases, however, chemicals or drugs were identified as aetiological agents and associations with certain phenotypes of drug metabolising enzymes have been reported. The purpose of this study was to discover if there is an association between CYP2C19 polymorphism and susceptibility to SLE.

METHODS

Racemic mephenytoin (100 mg orally) was given to healthy volunteers (n = 161) and SLE patients (n = 37) and then S-mephenytoin and R-mephenytoin were determined in eight hour urine samples. A 10 ml blood sample was obtained from healthy volunteers (n = 80) and SLE patients (n = 69) for genotypic assay. Each blood sample was tested for the detection of CYP2C19*1 and CYP2C19*2 (formerly wt and m1 respectively) by oligonucleotide ligation assay.

RESULTS

The ratio of S/R-mephenytoin ranged from < 0.1 to 1.293 in healthy subjects and from < 0.1 to 1.067 in SLE patients. PM phenotype was observed in 2 of 37 patients with idiopathic SLE (5.4%) and 6 of 161 healthy subjects (3.7%). There were no significant differences in the frequency of PM phenotypes between the groups (Fisher's exact test, p = 0.64) or in the frequency distribution profiles of ratios of S-mephenytoin to R-mephenytoin. No significant differences in distribution of overall genotypes and in allele frequencies were observed between the two groups. No significant relation was found between clinical features and the overall genotype.

CONCLUSION

The results of this study indicate that CYP2C19 genotype does not represent a genetic predisposition in idiopathic SLE patients.

Genetic polymorphisms of human N-acetyltransferase, cytochrome P450, glutathione-S-transferase, and epoxide hydrolase enzymes: relevance to xenobiotic metabolism and toxicity

In this review, an overview is presented of the current knowledge of genetic polymorphisms of four of the most important enzyme families involved in the metabolism of xenobiotics, that is, the N-acetyltransferase (NAT), cytochrome P450 (P450), glutathione-S-transferase (GST), and microsomal epoxide hydrolase (mEH) enzymes. The emphasis is on two main topics, the molecular genetics of the polymorphisms and the consequences for xenobiotic metabolism and toxicity. Studies are described in which wild-type and mutant alleles of biotransformation enzymes have been expressed in heterologous systems to study the molecular genetics and the metabolism and pharmacological or toxicological effects of xenobiotics. Furthermore, studies are described that have investigated the effects of genetic polymorphisms of biotransformation enzymes on the metabolism of drugs in humans and on the metabolism of genotoxic compounds in vivo as well. The effects of the polymorphisms are highly dependent on the enzyme systems involved and the compounds being metabolized. Several polymorphisms are described that also clearly influence the metabolism and effects of drugs and toxic compounds, in vivo in humans. Future perspectives in studies on genetic polymorphisms of biotransformation enzymes are also discussed. It is concluded that genetic polymorphisms of biotransformation enzymes are in a number of cases a major factor involved in the interindividual variability in xenobiotic metabolism and toxicity. This may lead to interindividual variability in efficacy of drugs and disease susceptibility.

Canadian Native Indians exhibit unique CYP2A6 and CYP2C19 mutant allele frequencies

Many human cytochromes P450 (CYP) enzymes are polymorphically expressed, resulting in interindividual and interethnic differences in the metabolism of substrate drugs. Little is known about the genetic variation of CYP enzymes in Canadian Native Indians. We therefore determined the CYP2C19 and CYP2A6 mutant allele frequencies in 159 Canadian Native Indians and compared them with white and Asian subjects. Canadian Native Indians differed significantly from both white and Asian populations in allelic patterns of both CYP2C19 (19.1% CYP2C19*2 and 0% CYP2C19*3) and CYP2A6 (0.9% CYP2A6*2 and 13.9% CYP2A6*3). In addition, analysis of the Canadian Native Indian data suggested that there may be an association between the presence of the CYP2C19 and CYP2A6 mutant alleles such that the co-occurrence of these 2 alleles is higher than would be predicted on the basis of their individual frequencies in this population.

The visceral and somatic antinociceptive effects of dihydrocodeine and its metabolite, dihydromorphine. A cross-over study with extensive and quinidine-induced poor metabolizers

AIMS

Dihydrocodeine is metabolized to dihydromorphine via the isoenzyme cytochrome P450 2D6, whose activity is determined by genetic polymorphism. The importance of the dihydromorphine metabolites for analgesia in poor metabolizers is unclear. The aim of this study was to assess the importance of the dihydromorphine metabolites of dihydrocodeine in analgesia by investigating the effects of dihydrocodeine on somatic and visceral pain thresholds in extensive and quinidine-induced poor metabolizers.

METHODS

Eleven healthy subjects participated in a double-blind, randomized, placebo-controlled, four-way cross-over study comparing the effects of single doses of placebo and slow-release dihydrocodeine 60 mg with and without premedication with quinidine sulphate 50 mg on electrical, heat and rectal distension pain tolerance thresholds. Plasma concentrations and urinary excretion of dihydrocodeine and dihydromorphine were measured.

RESULTS

In quinidine-induced poor metabolizers the plasma concentrations of dihydromorphine were reduced between 3 and 4 fold from 1.5 h to 13.5 h after dosing (P < 0.005) and urinary excretion of dihydromorphine in the first 12 h was decreased from 0.91% to 0.28% of the dihydrocodeine dose (P < 0.001). Dihydrocodeine significantly raised the heat pain tolerance thresholds (at 3.3 h and 5 h postdosing, P < 0.05) and the rectal distension defaecatory urge (at 3.3 h and 10 h postdosing, P < 0.02) and pain tolerance thresholds (at 3.3 h and 5 h postdosing, P < 0.05) compared with placebo. Premedication with quinidine did not change the effects of dihydrocodeine on pain thresholds, but decreased the effect of dihydrocodeine on defaecatory urge thresholds (at 1.5 h, 3.3 h and 10 h postdosing, P < 0.05).

CONCLUSIONS

In quinidine-induced poor metabolizers significant reduction in dihydromorphine metabolite production did not result in diminished analgesic effects of a single dose of dihydrocodeine. The metabolism of dihydrocodeine to dihydromorphine may therefore not be of clinical importance for analgesia. This conclusion must however, be confirmed with repeated dosing in patients with pain.

Characterization of CYP2C19 and CYP2C9 from human liver: respective roles in microsomal tolbutamide, S-mephenytoin, and omeprazole hydroxylations

Individuals with drug metabolism polymorphisms involving CYP2C enzymes exhibit deficient oxidation of important therapeutic agents, including S-mephenytoin, omeprazole, warfarin, tolbutamide, and nonsteroidal anti-inflammatory drugs. While recombinant CYP2C19 and CYP2C9 proteins expressed in yeast or Escherichia coli have been shown to oxidize these agents, the capacity of the corresponding native P450s isolated from human liver to do so is ill defined. To that end, we purified CYP2C19, CYP2C9, and CYP2C8 from human liver samples using conventional chromatographic techniques and examined their capacity to oxidize S-mephenytoin, omeprazole, and tolbutamide. Upon reconstitution, CYP2C19 metabolized S-mephenytoin and omeprazole at rates that were 11- and 8-fold higher, respectively, than those of intact liver microsomes, whereas neither CYP2C9 nor CYP2C8 displayed appreciable metabolic activity with these substrates. CYP2C19 also proved an efficient catalyst of tolbutamide metabolism, exhibiting a turnover rate similar to CYP2C9 preparations (2.0-6.4 vs 2.4-4.3 nmol hydroxytolbutamide formed/min/nmol P450). The kinetic parameters of CYP2C19-mediated tolbutamide hydroxylation (Km = 650 microM, Vmax = 3.71 min-1) somewhat resembled those of the CYP2C9-catalyzed reaction (Km = 178-407 microM, Vmax = 2.95-7.08 min-1). Polyclonal CYP2C19 antibodies markedly decreased S-mephenytoin 4'-hydroxylation (98% inhibition) and omeprazole 5-hydroxylation (85% inhibition) by human liver microsomes. CYP2C19 antibodies also potently inhibited (>90%) microsomal tolbutamide hydroxylation, which was similar to the inhibition (>85%) observed with antibodies to CYP2C9. Moreover, excellent correlations were found between immunoreactive CYP2C19 content, S-mephenytoin 4'-hydroxylase activity (r = 0.912; P < 0. 001), and omeprazole 5-hydroxylase activity (r = 0.906; P < 0.001) in liver samples from 13-17 different subjects. A significant relationship was likewise observed between microsomal tolbutamide hydroxylation and CYP2C9 content (r = 0.664; P < 0.02) but not with CYP2C19 content (r = 0.393; P = 0.184). Finally, immunoquantitation revealed that in these human liver samples, expression of CYP2C9 (88. 5 +/- 36 nmol/mg) was 5-fold higher than that of CYP2C19 (17.8 +/- 14 nmol/mg) and nearly 8-fold higher than that of CYP2C8 (11.5 +/- 12 nmol/mg). Our results, like those obtained with recombinant CYP2C enzymes, indicate that CYP2C19 is a primary determinant of S-mephenytoin 4'-hydroxylation and low-Km omeprazole 5-hydroxylation in human liver. Despite its tolbutamide hydroxylase activity, the low levels of hepatic CYP2C19 expression (relative to CYP2C9) may preclude an important role for this enzyme in hepatic tolbutamide metabolism and any polymorphisms thereof.

Pharmacokinetics and effect on caffeine metabolism of the proton pump inhibitors, omeprazole, lansoprazole, and pantoprazole

AIMS

To study the pharmacokinetics of three proton pump inhibitors, omeprazole, lansoprazole, and pantoprazole, as well as any potential influence on CYP1A2 activity (measured by means of rate of caffeine metabolism) of these compounds at single dose and repeated dose administration.

METHODS

Fourteen healthy males, classified as 12 extensive metabolizers (EMs) and two poor metabolizers (PMs) according to the urinary S/R mephenytoin ratio, completed this open, randomized, three-way cross-over study. In each of the three 7-day treatment periods either omeprazole (20 mg), lansoprazole (30 mg) or pantoprazole (40 mg) in therapeutically recommended doses was administered once daily, and the pharmacokinetics of the proton pump inhibitors as well as the rate of caffeine metabolism was measured on days 1 and 7.

RESULTS

In the EMs there was an increase in AUC from day 1 to day 7 for omeprazole. In the PMs the AUC of both omeprazole and lansoprazole was unchanged during repeated dosing, while for pantoprazole there was a tendency to a slight decrease. The AUC at steady state was for all three proton pump inhibitors 5 fold higher in PMs compared with EMs, indicating that the same proportion of the dose, irrespective of compound, is metabolized by CYP2C19. No induction of CYP1A2 was evident for any of the compounds in either EMs or PMs.

CONCLUSIONS

The approximately 5 fold difference in AUC between EMs and PMs indicates that approximately 80% of the dose for all three proton pump inhibitors is metabolized by the polymorphically expressed CYP2C19. None of the three proton pump inhibitors, administered in therapeutically recommended doses, is an inducer of CYP1A2--neither in PMs nor in EMs.

Metabolic disposition of pantoprazole, a proton pump inhibitor, in relation to S-mephenytoin 4'-hydroxylation phenotype and genotype

OBJECTIVES

To assess the possible relationship between the metabolic disposition of pantoprazole and genetically determined S-mephenytoin 4'-hydroxylation phenotype and genotype.

METHODS

The pharmacokinetic disposition of pantoprazole was investigated in 14 Japanese male volunteers (seven extensive and seven poor metabolizers of S-mephenytoin). All subjects received a single 40 mg oral dose of pantoprazole as the enteric-coated formulation.

RESULTS

An interphenotypic difference in the metabolic disposition of pantoprazole was observed: the mean values for area under the concentration-time curve (AUC), elimination half-life (t1/2), and apparent oral clearance were significantly (p < 0.01) greater, longer, and lower, respectively, in the poor metabolizers than in the extensive metabolizers. The mean AUC of pantoprazole sulfone was greater (p < 0.01) in the poor metabolizers than in the extensive metabolizers, whereas the mean AUC of the main demethylated metabolite (M2) was lower (p < 0.01) in the poor metabolizers than in the extensive metabolizers. A significant negative correlation was observed between the individual values for log10% urinary excretion of 4'-hydroxymephenytoin and AUC of pantoprazole (rs = -0.816; p < 0.005). The CYP2C19 genotyping test results were found to be in a complete accordance with the phenotypes.

CONCLUSION

These data indicated that the metabolic disposition of pantoprazole is under the pharmacogenetic control of S-mephenytoin 4'-hydroxylase (CYP2C19).

Determination of p-aminosalicylic acid and its N-acetylated metabolite in human urine by capillary zone electrophoresis as a measure of in vivo N-acetyltransferase 1 activity

A capillary zone electrophoresis method has been developed for the determination of p-aminosalicylic acid (PAS) and its metabolite, N-acetyl-p-aminosalicylic acid (N-acetyl-PAS), in urine. A linear relationship was observed between time-normalized peak area and the concentration of the parent and metabolite with correlation coefficients greater than 0.9990. The method could be applied to the determination of PAS and N-acetyl-PAS in human urine without any sample pretreatment. A good separation of the analytes is achieved in a run time of 12 min (15 min total, including capillary wash). Using PAS as a probe for N-acetyltransferase 1 activity, 20 healthy volunteers were phenotyped after oral administration of a 1 g dose. The preliminary results seem to indicate a bimodal distribution of N-acetyl-PAS/PAS molar ratios.

N-acetylation among HIV-positive patients and patients with AIDS: when is fast, fast and slow, slow?

BACKGROUND

The discrepancy between genotype and expressed phenotype of the polymorphic N-acetyltransferase (NAT2) has been suggested by separate genotypic and phenotypic studies in populations with human immunodeficiency virus (HIV). Only one study has examined both genotype and phenotype in the same population, and no discrepancies were observed.

METHODS

In a cross-sectional study, 105 HIV-positive patients and patients with acquired immunodeficiency syndrome (AIDS) were phenotyped for NAT2 activity with use of caffeine as an in vivo probe; 50 of these patients were also genotyped by restriction mapping and allele-specific amplification. In a longitudinal study, 23 patients were phenotyped at least twice during the 2-year study.

RESULTS

The distribution of the NAT2 phenotype among the 105 patients was unimodal and skewed toward slow acetylators as opposed to the bimodal distribution observed in healthy white populations. The genotype distribution was 26:24 slow:fast. There were 18 discrepancies between genotype and phenotype: 12 slow acetylators with fast genotypes and six fast acetylators with slow genotypes. No drug-related effects on NAT2 activity were apparent, but the role of disease progression was evident. Among the slow acetylators whose genotype was fast, the incidence of AIDS was higher (six of 12) than that among the fast acetylators whose genotype was fast (two of 14). Among patients phenotyped more than once (mean time between samples, 10.4 months) changes in phenotype from fast to slow were associated with progression of HIV infection.

CONCLUSIONS

Disease progression in HIV infection and AIDS may alter expression of the NAT2 gene. The genotype and the phenotype are not interchangeable measurements. In the HIV population, to know the genotype is useful only if the phenotype is also known and vice versa.

Characterization of stereoselectivity and genetic polymorphism of the debrisoquine hydroxylation in man via analysis of urinary debrisoquine and 4-hydroxydebrisoquine by capillary electrophoresis

Using capillary zone electrophoresis with a phosphate buffer at pH 2.5 containing 50 mM heptakis-(2,3,6-tri-O-methyl)-beta-CD as chiral selector, the separation of the enantiomers of the main metabolite of debrisoquine (DEB), 4-hydroxydebrisoquine (4-OHDEB), is reported. For extraction of underivatized urinary DEB, S-4-OHDEB and R-4-OHDEB, a procedure using disposable cartridges containing a polystyrene-based polymer was developed. A few nL of the extracts were analyzed in a 60 cm fused-silica capillary of 50 microns ID and solute detection was effected at 195 nm. For all three compounds, a mean (n = 5) recovery of about 73% and a detection limit of about 150 ng/mL were noted. Data obtained with urines that were received for routine phenotyping with DEB and mephenytoin confirmed the almost exclusive formation of S-4-OHDEB. Under the described conditions, no R-4-OHDEB could be detected. With these data and those obtained employing no chiral selector in the buffer, differentiation between extensive metabolizer phenotypes (EM) and poor metabolizer phenotypes (PM) for DEB was unambiguously possible by the presence of a significant peak and no (or minor) peak for 4-OHDEB, respectively. Data obtained for ten EM subjects and five PM subjects were found to agree with those generated by the routine assay based on gas chromatography. The capillary electrophoretic assays described are simple, reproducible (relative standard deviation of peak area ratios < 3%), require no sample derivatization, consume no halogenated organic solvents, and operate with inexpensive separation columns as well as small amounts of chemicals.

Effects of genetic defects in the CYP2C19 gene on the N-demethylation of imipramine, and clinical outcome of imipramine therapy

The relationship between the genetic polymorphism of S-mephenytoin 4'-hydroxylation catalyzed by CYP2C19 and the N-demethylation of imipramine was examined in 10 Japanese depressed patients. Five patients, who were poor metabolizers of S-mephenytoin, were determined to be either homozygous for a mutation in exon 5 or heterozygous for mutations in exon 4 and exon 5 of the CYP2C19 gene. In contrast, five patients, who were extensive metabolizers, had no mutations. The demethylation index (the desipramine/imipramine ratio) was significantly lower in patients with genetic defects. Plasma levels of imipramine and 2-hydroxyimipramine normalized by the daily dose (mg) per weight (kg) were significantly higher in patients with genetic defects. This suggests that the N-demethylation of imipramine is impaired in patients with genetic defects in the CYP2C19 gene, and that genotype determination may be useful in preventing side effects induced by unexpectedly elevated levels of imipramine.

Enantioselective hydroxylation of omeprazole catalyzed by CYP2C19 in Swedish white subjects

Stereoselective disposition of omeprazole and its formed 5-hydroxy metabolite were studied in five poor metabolizers and five extensive metabolizers of S-mephenytoin. After a single oral dose of omeprazole (20 mg), the plasma concentrations of the separate enantiomers of the parent drug and the 5-hydroxy metabolite were determined for 10 hours after drug intake. In poor metabolizers, the area under the plasma concentration versus time curve [AUC(0-8)] of (+)-omeprazole was larger and that of the 5-hydroxy metabolite of this enantiomer was smaller than the AUC(0-8) values in extensive metabolizers (p < 0.001). The mean AUC(0-8) of the (-)-enantiomer of omeprazole was also higher in poor metabolizers than in extensive metabolizers, but only 3.1-fold compared with 7.5-fold for (+)-omeprazole. The rate of formation of the hydroxy metabolite from (-)-omeprazole was low and not significantly different in poor and extensive metabolizers. These results show that (+)-omeprazole is to a major extent hydroxylated by CYP2C19. Also (-)-omeprazole may partly be metabolized by this enzyme but is mainly metabolized by another enzyme, presumably CYP3A4, to the achiral sulfone metabolite. The plasma concentration ratio of omeprazole to 5-hydroxyomeprazole obtained 3 hours after the drug intake has been used to distinguish between extensive and poor metabolizer phenotypes. With use of the ratio between the (+)-enantiomers of the parent drug and the metabolite, a better discrimination between phenotypes was obtained. The ratio between the (-)-enantiomers also separated the phenotypes but was less discriminatory. For the future, measurement of total concentrations will suffice for phenotyping.

Metabolic disposition of lansoprazole in relation to the S-mephenytoin 4'-hydroxylation phenotype status

OBJECTIVE

To assess the possible involvement of CYP2C19 in the metabolism of lansoprazole in vivo.

METHODS

Sixteen male Korean subjects, who had been phenotyped as extensive metabolizers and poor metabolizers of S-mephenytoin 4'-hydroxylation polymorphism (n = 8 each) with racemic mephenytoin with use of the 8-hour urine analysis of 4'-hydroxymephenytoin, took an oral dose of 30 mg lansoprazole, and blood samples were collected up to 48 hours after dosing. Lansoprazole and its metabolites were measured by high-performance liquid chromatography with ultraviolet detection.

RESULTS

The mean lansoprazole area under the concentration-time curve (AUC), elimination half-life (t1/2), and apparent oral clearance (CLoral) were significantly (p < 0.001) greater, longer, and lower, respectively, in the poor metabolizer than in the extensive metabolizer group. The mean values for the AUC of hydroxylansoprazole and AUC ratio of hydroxylansoprazole to lansoprazole were significantly (p < 0.01 to p < 0.001) less in the poor metabolizer than in the extensive metabolizer group, whereas those for the AUC of lansoprazole sulfone and ratio of lansoprazole sulfone to lansoprazole were greater (p < 0.001) in the former than in the latter group. In addition, the log10 4'-hydroxymephenytoin excreted in urine correlated significantly (p < 0.01) with the CLoral of lansoprazole.

CONCLUSIONS

These results suggest that the hydroxylation of lansoprazole cosegregates with the genetically determined S-mephenytoin 4'-hydroxylation (CYP2C19) polymorphism in the Korean subjects.

Genetic polymorphisms in human drug-metabolizing enzymes: potential uses of reverse genetics to identify genes of toxicological relevance

The human mind was engaged with fundamental questions on the nature of heredity long before the study of genetics became a scientific discipline. Many traits, such as height, eye color, blood pressure, or cancer susceptibility, have been known to run in families, although the genes or combination of genes that underlie these observable characteristics remain unknown in most cases. Differences in susceptibility to environmental agents in humans are likewise determined by variations in genetic background--genetic polymorphisms. In this article, we review the current status of studies on human polymorphisms in drug-metabolizing enzymes and discuss various approaches to the analysis of genetic polymorphisms. We expect that in the near future, novel methods in genetic analysis of human populations will be likely to play a key role in the identification of genes of toxicological relevance.

Pharmacogenetics: a laboratory tool for optimizing therapeutic efficiency

Pharmacogenetics is the study of the linkage between an individual’s genotype and that individual’s ability to metabolize a foreign compound. Differences in metabolism of therapeutics can lead to severe toxicity or therapeutic failure by altering the relation between dose and blood concentration of the pharmacologically active drug. Phenotypes exhibiting poor and ultraextensive metabolism result from genetic variance (polymorphism) of enzymes involved in metabolism. Thus, in pharmacogenetic studies one applies genotyping of polymorphic alleles encoding drug-metabolizing enzymes to the identification of an individual’s drug metabolism phenotype. This knowledge, when applied to dosing or drug selection, can avoid adverse reactions or therapeutic failure and thus enhance therapeutic efficiency. More than 25 commonly prescribed medicines are metabolized by the cytochrome P-4502D6 (CYP2D6) isoenzyme, and polymorphism of the CYP2D6 gene affects the therapeutic management of up to 17% of individuals in some ethnic groups. In this review, we summarize and update information concerning drug-metabolizing genotypes with emphasis on CYP2D6 genotyping techniques that can be applied by the clinical laboratory for linking human genetics to therapeutic management.

Genetic predisposition to drug-induced hepatotoxicity

Drug-induced hepatitis is uncommon and generally unpredictable. Hepatotoxicity may be related to the drug itself, or to chemically reactive metabolites which can bind covalently to hepatic macromolecules and may lead to either idiosyncratic, toxic hepatitis or to immunoallergic hepatitis. There is now evidence indicating that genetic variations in systems of biotransformation or detoxication may modulate either the toxic or sensitizing effects of some drugs. Thus, the genetic deficiency in a particular hepatic cytochrome P 450 isozyme (CYP 2D6) is involved in per-hexiline liver injury. The deficiency in CYP 2C19 might also contribute to Atrium hepatotoxicity. Slow acetylation related to N-acetyltransferase 2 deficiency contributes to sulfonamide hepatitis. The genetic deficiency in glutathione synthetase may increase the susceptibility to several drugs including acetaminophen. A constitutional deficiency in another cell defense mechanism, still not characterized, seems to increase significantly the risk of hepatotoxicity with halothane, phenytoin, carbamazepine, phenobarbital, sulfamides and amineptine.

Clinically relevant pharmacology of selective serotonin reuptake inhibitors. An overview with emphasis on pharmacokinetics and effects on oxidative drug metabolism

This paper presents an overview of the clinically relevant pharmacology of selective serotonin reuptake inhibitors (SSRIs) with an emphasis on their pharmacokinetics and effects on cytochrome P450 (CYP) enzymes. The SSRIs are potent inhibitors of the neuronal reuptake pump for serotonin (5-hydroxytryptamine; 5-HT) and have minimal effects on a number of other sites of actions (e.g. neuroreceptors and fast sodium channels). For this reason, drugs in this class have remarkable similarity as regards acute and maintenance antidepressant efficacy and tolerability profile. However, individual members of this class differ substantially in their pharmacokinetics and effects on CYP enzymes. Most SSRIs have a half-life (t1/2) of approximately 1 day. Fluoxetine, however, has a longer t1/2 of 2 to 4 days, and its active metabolite, norfluoxetine, has an extended t1/2 of 7 to 15 days. Fluoxetine, paroxetine and, to a lesser extent, fluvoxamine inhibit their own metabolism. That is not the case for citalopram or sertraline. There are nonlinear increases in paroxetine plasma concentrations with dosage increases, but proportional changes with citalopram and sertraline. Indirect data suggest that fluoxetine and fluvoxamine also have nonlinear pharmacokinetics over their usual dosage range. Age-related increases in plasma drug concentrations for citalopram (approximately 130%) and paroxetine (approximately 50 to 100%) have been observed in healthy elderly (65 to 75 years) persons versus those who are younger. There is an age-gender interaction for sertraline, with its plasma concentrations being 35 to 40% lower in young men than in elderly or young females or elderly males. While there is no apparent change in fluvoxamine plasma levels as a function of age, plasma drug concentrations are 40 to 50% lower in males than in females. Limited data from clinical trials suggest that age-related differences with fluoxetine may be comparable to those of citalopram and paroxetine. Marked differences exist between the SSRIs with regard to effects on specific CYP enzymes and, thus, the likelihood of clinically important pharmacokinetic drug-drug interactions. The most extensive in vitro and in vivo research has been done with fluoxetine, fluvoxamine and sertraline; there has been less with paroxetine and citalopram. The available in vivo data at each drug's usually effective antidepressant dose are summarised below. Citalopram produces mild inhibition of CYP2D6. Fluvoxamine produces inhibition (which would be expected to be clinically meaningful) of two CYP enzymes. CYP1A2 and CYP2C19, and probably a third, CYP3A3/4. Fluoxetine substantially inhibits CYP2D6 and probably CYP2C9/10, moderately inhibits CYP2C19 and mildly inhibits CYP3A3/4. Paroxetine substantially inhibits CYP2D6 but doses not appear to inhibit any other CYP enzyme. Sertraline produces mild inhibition of CYP2D6 but has little, if any, effect on CYP1A2, CYP2C9/10, CYP2C19 or CYP3A3/4. Understanding the similarities and differences in the pharmacology of SSRIs can aid the clinician in optimal use of this important class of antidepressants.

Molecular mechanisms of genetic polymorphisms of drug metabolism

One of the major causes of interindividual variation of drug effects is genetic variation of drug metabolism. Genetic polymorphisms of drug-metabolizing enzymes give rise to distinct subgroups in the population that differ in their ability to perform certain drug biotransformation reactions. Polymorphisms are generated by mutations in the genes for these enzymes, which cause decreased, increased, or absent enzyme expression or activity by multiple molecular mechanisms. Moreover, the variant alleles exist in the population at relatively high frequency. Genetic polymorphisms have been described for most drug metabolizing enzymes. The molecular mechanisms of three polymorphisms are reviewed here. The acetylation polymorphism concerns the metabolism of a variety of arylamine and hydrazine drugs, as well as carcinogens by the cytosolic N-acetyltransferase NAT2. Seven mutations of the NAT2 gene that occur singly or in combination define numerous alleles associated with decreased function. The debrisoquine-sparteine polymorphism of drug oxidation affects the metabolism of more than 40 drugs. The poor metabolizer phenotype is caused by several "loss of function" alleles of the cytochrome P450 CYP2D6 gene. On the other hand, "ultrarapid" metabolizers are caused by duplication or amplification of an active CYP2D6 gene. Intermediate metabolizers are often heterozygotes or carry alleles with mutations that decrease enzyme activity only moderately. The mephenytoin polymorphism affects the metabolism of mephenytoin and several other drugs. Two mutant alleles of CYP2C19 have so far been identified to cause this polymorphism. These polymorphisms show recessive transmission of the poor or slow metabolizer phenotype, i.e. two mutant alleles define the genotype in these individuals. Simple DNA tests based on the primary mutations have been developed to predict the phenotype. Analysis of allele frequencies in different populations revealed major differences, thereby tracing the molecular history and evolution of these polymorphisms.

Cytochrome P450 enzymes: interpretation of their interactions with selective serotonin reuptake inhibitors. Part II

The SSRIs have been used as an example to show how one might interpret the available evidence to draw conclusions about the relationships between drugs and P450s. Under what circumstances might one apply the knowledge of such relationships? First, the clinical implications must be considered when drugs with a narrow therapeutic index are coprescribed with other drugs that may affect P450s. For example, good clinical practice demands that before a TCA is coprescribed with another drug, the physician be aware of the potential for the second drug to interact with CYP2D6. Second, it may be helpful to consider P450 enzymes when adverse events occur during polypharmacy. It may happen that a known side effect of one drug occurs. Rather than attributing this to patient sensitivity, the physician should consider the possibility that a pharmacokinetic drug interaction increased plasma drug concentration, which in turn enhanced the probability of such an occurrence. Even when a pharmacokinetic drug interaction is considered as a possible cause, an appreciation of the role of P450s may lead to the realization that an interaction was not only possible but that it was likely. Finally, copharmacy can be used intentionally to produce controlled interactions. Indeed, planned pharmacokinetic drug interactions at the level of P450s have been proposed to reduce cyclosporine dosage requirements, to reduce variability of TCA levels, and to manipulate the contribution of alternative metabolic pathways to minimize toxic effects. As long as pharmaceuticals are metabolized by the P450 system, interactions with the various isozymes will be inescapable. It is fortunate that understanding them is becoming more tractable.

Genotype analysis of the CYP2C19 gene in the Japanese population

A polymorphic CYP2C19 gene was analyzed in 233 Japanese subjects, including 63 with Parkinson's disease, 92 with chronic liver diseases (35 chronic hepatitis, 19 liver cirrhosis, 16 hepatocellular carcinoma, 10 primary biliary cirrhosis and 12 autoimmune hepatitis), 14 with lung cancer (squamous cell carcinoma) and 64 healthy subjects to determine the genotype distributions of the CYP2C19 gene and to investigate its involvement in the diseases. Among Japanese healthy subjects 14.1% are predicted to be poor metabolizers (PM) of mephenytoin. The frequencies of the m1 and the m2 mutations of the CYP2C19 gene in the healthy subjects were 21.9% and 11.7%, respectively. Though the number of patients was small, patients with lung cancer (squamous cell carcinoma) are believed to have reduced enzyme activities of CYP2C19.

Determination of CYP2C19 phenotype in black Americans with omeprazole: correlation with genotype

BACKGROUND

Our objective was to study omeprazole as a single-dose oral probe in the determination of CYP2C19 phenotype in black subjects and to determine the correlation between phenotype and genotype.

METHODS

This single-dose, open-label outpatient study was conducted at a community-based, university-affiliated teaching hospital outpatient clinic. Study subjects were 100 healthy, unrelated black adults (age range, 18 to 50 years) who were receiving no medications. Baseline omeprazole and 2-hour postingestion omeprazole and 5'-hydroxyomeprazole concentrations were measured for phenotype determination. Identification of CYP2C19m1 genotypes were performed with use of the polymerase chain reaction.

RESULTS

Results were obtained for 28 men and 72 women. Ninety-eight subjects were found to be phenotypically extensive metabolizers and two to be poor metabolizers (one man; one smoker). Genotype determination revealed that the two poor metabolizers of omeprazole were homozygous for a single base pair mutation (m1/m1) in exon 5 of CYP2C19. Twenty-eight of the extensive metabolizers were heterozygous (m1/wt) and the remaining 70 were homozygous (wt/wt). No side effects were reported.

CONCLUSIONS

The 2% prevalence rate of poor CYP2C19 metabolizers in this healthy black population residing in the Midwestern United States is similar to that reported in white subjects and in the Shona population of Zimbabwe but much less than in Asian subjects. Omeprazole is a safe and specific probe of the CYP2C19 enzyme system that correlates well with genotype.

Pharmacokinetics, metabolism and interactions of acid pump inhibitors. Focus on omeprazole, lansoprazole and pantoprazole

This review updates and evaluates the currently available information regarding the pharmacokinetics, metabolism and interactions of the acid pump inhibitors omeprazole, lansoprazole and pantoprazole. Differences and similarities between the compounds are discussed. Omeprazole, lansoprazole and pantoprazole are all mainly metabolished by the polymorphically expressed cytochrome P450 (CYP) isoform S-mephenytoin hydroxylase (CYP2C19), which means that within a population a few individuals (3% of Caucasians) metabolise the compounds slowly compared with the majority of the population. For all 3 compounds, the area under the plasma concentration-versus-time curve (AUC) for a slow metaboliser is, in general, approximately 5 times higher than that in an average patient. Since all 3 compounds are considered safe and well tolerated, and no dosage-related adverse drug reactions have been identified, this finding seems to be of no clinical relevance. The acid pump inhibitors seem to be similarly handled in the elderly, where a somewhat slower elimination can be demonstrated compared with young individuals. In patients with renal insufficiency, omeprazole is eliminated as in healthy individuals, whereas the data on lansoprazole and pantoprazole are unresolved. In patients with hepatic insufficiency, as expected, the elimination rates of all 3 compounds are substantially decreased. No clinically relevant effects on specific endogenous glandular functions, such as the adrenal (cortisol), the gonads or the thyroid, were demonstrated for omeprazole and pantoprazole, whereas a few minor concerns have been raised regarding lansoprazole. The absorption of some compounds, e.g. digoxin, might be altered as a result of the increased gastric pH obtained during treatment with acid pump inhibitors, and, accordingly, similar effects are expected irrespective of which acid pump inhibitor is given. The effect of the acid pump inhibitors on enzymes in the liver has been intensely debated, and some authors have claimed that lansoprazole and pantoprazole have less potential than omeprazole to interact with other drugs metabolised by CYP. However, after assessment of available data in this area, the conclusion is that all 3 acid pump inhibitors have a very limited potential for drug interactions at the CYP level. In addition, the small effects on CYP reported for these compounds are rarely of any clinical relevance, considering the normal intra- (and inter-)individual variations in metabolism observed for most drugs. In conclusion, omeprazole, lansoprazole and pantoprazole are structurally very similar, and an evaluation of available data indicates that also with respect to pharmacokinetics, metabolism and interactions in general they demonstrate very similar properties, even though omeprazole has been more thoroughly studied with regard to different effects.

Genetic analysis of the cytochrome P-45OIIC18 (CYP2C18) gene and a novel member of the CYP2C subfamily

The CYP2C18 gene was investigated in order to characterize its molecular basis in the CYP2C subfamily. A mutation of the CYP2C18 gene was identified at the 5'-flanking region of the gene, which could be detected by digestion with DdeI. The allele frequency of the mutant CYP2C18 gene was 21.4%. Genotypes of the polymorphic DdeI site of the CYP2C18 gene were found to be completely consistent with that of the polymorphic CYP2C19 gene (the m1 mutant). The CYP2C18 and CYP2C19 genes were suggested to be linked and located close together on the chromosome. Clones containing the 5'-flanking region of a member of the CYP2C subfamily were obtained from the PCR products from human genomic DNA. The nucleotide sequence of the clone proved to be 90.5% identical to the corresponding region of the CYP2C18 gene. This is very likely to be a novel member of the CYP2C subfamily.

The effect of age and concomitant treatment with other psychoactive drugs on serum concentrations of citalopram measured with a nonenantioselective method

We measured citalopram and desmethylcitalopram concentrations in serum from 169 psychiatric patients, who were treated with common therapeutic drug doses. Altogether 202 serum samples were assayed by a nonenantioselective high-performance liquid chromatography (HPLC) method. The results indicate that the kinetic variability (maximum concentration/minimum concentration) in dose- and weight-related serum citalopram (10.6-fold) and desmethylcitalopram (7.2-fold) is large even during monotherapy. Log serum citalopram (r = 0.36, p < 0.05) and desmethylcitalopram (r = 0.51, p < 0.01) concentrations of individual patients increased significantly with increasing drug doses. Dose- and weight-related (calculated as mg/kg dose basis) log serum citalopram (r = 0.29) but not desmethylcitalopram (r = 0.06) concentrations increased with aging (p < 0.001). No sex-related differences were found. Nineteen patients (19 samples) had concomitant treatment with neuroleptics, 84 patients (101 samples) with benzodiazepines, and 18 patients (28 samples) with tricyclic antidepressants. The concentrations in these patients were compared with those of 48 nonsmoking patients (54 samples) without any concomitant psychotropic drug treatment. None of the single neuroleptics alone had a significant effect on dose- and weight-related serum citalopram or desmethylcitalopram concentrations. However, citalopram concentrations increased by 121% (338 +/- 165 vs. 747 +/- 505, mean +/- SD; p < 0.01) and desmethylcitalopram by 85% (124 +/- 53 vs. 229 +/- 138; p < 0.05) when neuroleptics were pooled. Among single benzodiazepines, only alprazolam increased serum citalopram (338 +/- 165 vs. 391 +/- 267; p < 0.01) and desmethylcitalopram (124 +/- 53 vs. 186 +/- 175; p < 0.01) concentrations. When all the benzodiazepines were pooled, they still increased the serum concentration of the parent drug by 23% (338 +/- 165 vs. 414 +/- 303; p < 0.05) and those of the metabolite by 47% (124 +/- 53 vs. 182 +/- 163; p < 0.01). In patients who were simultaneously treated with clomipramine, serum citalopram (338 +/- 165 vs. 655 +/- 409; p < 0.001) and desmethylcitalopram (124 +/- 53 vs. 435 +/- 347; p < 0.001) concentrations were consistently higher than those of the controls. Even when the tricyclic antidepressants were pooled, they increased citalopram concentrations by 44% (338 +/- 165 vs. 486 +/- 312; p < 0.001) and desmethylcitalopram concentrations by 111% (124 +/- 53 vs. 261 +/- 260; p < 0.001). The results suggest that interindividual variability in serum citalopram concentrations is pronounced and that increased serum citalopram levels are related to advancing age and concomitant treatment with other psychotropic drugs. The citalopram dose should therefore ideally be individualized by therapeutic drug monitoring.

Investigation of xenobiotic metabolism by CYP2D6 and CYP2C19: importance of enantioselective analytical methods

Investigations into the genetic polymorphism of drug metabolism have involved specific models to screen poor and extensive metabolisers of xenobiotics. Debrisoquine, sparteine, S-mephenytoin and dextromethorphan are particularly well known. They have been extensively described in the literature and are used to phenotype human subjects before performing investigations with new drugs which are believed to be under the control of a genetic polymorphism. Dextromethorphan, debrisoquine and sparteine are good substrates for CYP2D6, whereas the S-enantiomer of mephenytoin is a good substrate for CYP2C19, both being two isozymes of cytochrome P-450. In many drugs, the hepatic microsomal oxidative metabolism involving stereogenic centres congregates either with CYP2D6 or with CYP2C19 or, in certain cases, with both of them. The availability of both CYP2D6 from poor and extensive metabolisers and an enantioselective assay would allow genetic polymorphism in drug biotransformation to be investigated in vitro ex vivo at an early stage of drug development before the IND (investigational new drug). Single-dose investigations in vivo can also be performed when only minimal pre-clinical toxicological data are available and produce more reliable results than in vitro studies. This paper focuses on the problem of genetic polymorphism in drug development and specifically discusses some relevant knowledge gained in the last two decades on enantioselective bioassays. Specific examples are given.

Characterization of the genetic polymorphism of dihydrocodeine O-demethylation in man via analysis of urinary dihydrocodeine and dihydromorphine by micellar electrokinetic capillary chromatography

The genetic polymorphism of dihydrocodeine O-demethylation in man via analysis of urinary dihydrocodeine (DHC) and dihydromorphine (DHM) by micellar electrokinetic capillary chromatography is described. Ten healthy subjects which are known to be extensive metabolizers for debrisoquine ingested 60 mg of DHC and collected their 0-12 h urines. In these samples, about 1% of the administered DHC equivalents are shown to be excreted as DHM. Premedication of 50 mg quinidine sulfate to the same subjects is demonstrated to significantly reduce (3-4 fold) the amount of O-demethylation of DHC, a metabolic step which is thereby demonstrated to co-segregate with the hydroxylation of debrisoquine. Thus, in analogy to codeine and other substrates, extensive and poor metabolizer phenotypes for DHC can be distinguished. Using the urinary DHC/DHM metabolic ratio to characterize the extent of O-demethylation, the metabolic ratio ranges of extensive and poor metabolizers in a frequency histogram are shown to partially overlap. Thus, classification of borderline values is not unequivocal and DHC should therefore not be employed for routine pharmacogenetic screening purposes. Nevertheless, the method is valuable for metabolic research and preliminary data demonstrate that the same assay could also be used to explore the metabolism of codeine.

Bioavailability and efficacy of omeprazole given orally and by nasogastric tube

We compared the bioavailability and the efficacy of omeprazole provided either as encapsulated enteric-coated granules or as enteric-coated granules delivered via a nasogastric tube in 10 healthy subjects. Omeprazole reduced mean pentagastrin-stimulated peak gastric acid secretion by 85.5% +/- 23.7% when delivered orally and by 79.6% +/- 32.1% when delivered by nasogastric tube; the mean plasma omeprazole concentration area under the curve (AUC) was 2.02 +/- 0.79 after oral delivery and 1.74 +/- 1.89 after nasogastric tube delivery. There was no significant difference in these parameters between the two routes of administration, and there was excellent intrasubject correlating between oral and nasogastric percent acid suppression and AUC. There was a close correlation between AUC and percent acid suppression at AUC values below 0.6, and complete acid suppression at AUC values above 0.6, regardless of the delivery route. We conclude that omeprazole delivered as enteric-coated granules via nasogastric tube provides equal bioavailability and gastric acid suppression as omeprazole given orally in its proprietary formulation.

Simple and selective assay of 4-hydroxymephenytoin in human urine using solid-phase extraction and high-performance liquid chromatography with electrochemical detection and its preliminary application to phenotyping test

A simple and selective HPLC method for the determination of 4-hydroxymephenytoin (4-OH-M) in human urine, using a controlled potential coulometric detector equipped with a dual working electrode cell of fully porous graphite, has been developed. After acid hydrolysis of urine, 4-OH-M and the internal standard (I.S.), 5-hydroxy-1-tetralone, were extracted from urine by means of a Bond Elut Certify LRC column. The extracts were chromatographed on a reversed-phase mu Bondapak C18 column using methanol-50 mM KH2PO4 (pH 4.0) (30:70, v/v) as the mobile phase at a flow-rate of 1.0 ml/min. Electrochemical detection at applied potential of 800 mV resulted in a limit of quantitation of 0.76 micrograms/ml. The method showed a satisfactory sensitivity, precision, accuracy, recovery and selectivity. The present method was applied to the phenotyping test in thirteen Japanese healthy volunteers who received an oral 100-mg racemic mephenytoin. The phenotypes determined by the present method were found to be in agreement with those obtained with the reported customary assay based on gas chromatography.

Relationship between mephenytoin, phenytoin and tolbutamide hydroxylations in healthy African subjects

Mephenytoin, phenytoin and tolbutamide are metabolised by the cytochrome P-450 (CYP) 2C family. Recently, it has been shown that phenytoin and tolbutamide are metabolised by CYP2C9/10 whereas mephenytoin is metabolised by CYP2C19. Until now, in vivo studies were only undertaken in Caucasian subjects and showed a strong relationship between phenytoin and tolbutamide metabolism but no significant relationship between the two drug metabolisms and that of mephenytoin. The metabolism of the three drugs was investigated in eight black Africans by urinary analysis. In this ethnic group, a strong relationship was found between phenytoin and tolbutamide oxidations (rs = -0.83, P = 0.01). On the other hand, no significant relationship was found between mephentoin oxidation and phenytoin or tolbutamide oxidations (rs = 0.31 and rs = -0.33, respectively). This study suggests that, in black Africans, phenytoin and tolbutamide but not mephenytoin are also hydroxylated by similar CYP enzyme(s).

S-mephenytoin hydroxylation phenotypes in a Jordanian population

We tested the ability of 194 unrelated, healthy Jordanian volunteers to metabolize S-mephenytoin. Mephenytoin (100 mg) was coadministered with debrisoquin (10 mg) orally and urine was collected for 8 hours. Mephenytoin metabolism was tested according to three measures: the amount of 4-hydroxymephenytoin, the S/R enantiomeric ratio, and the presence of a polar, acid-labile metabolite in urine collected for 8 hours after the dose. The S/R ratio and the presence of the acid-labile metabolite were determined in the urine of 16 patients who had low amounts of 4-hydroxymephenytoin (log hydroxylation index > or = 1). On examination of these three parameters of oxidation status, nine subjects were found to be poor metabolizers of mephenytoin by all three parameters. Thus 4.6% (95% confidence interval of 1.6% to 7.6%) of Jordanian subjects studied were poor metabolizers of mephenytoin. According to the Hardy-Weinberg Law, the frequency of the recessive autosomal gene controlling the poor metabolizer status of mephenytoin was predicted to be 0.215% (95% confidence interval of 0.146% to 0.283%). These results are on the same order of magnitude as those determined in European white populations and constitute the first report in Arab populations.

Effect of 5-(p-hydroxyphenyl)-5-phenylhydantoin (p-HPPH) enantiomers, major metabolites of phenytoin, on the occurrence of chronic-gingival hyperplasia: in vivo and in vitro study

The purpose of this study was to assess the possible role of the (R)- and (S)- enantiomers of the phenytoin metabolite p-HPPH in the pathogenesis of gingival hyperplasia (GH). About 98% of circulating p-HPPH is in the (S)-form. There were significant differences between patients with and without GH in (R)-p-HPPH level (0.055 vs 0.042 microgram.ml-1), both enantiomer/racemate level ratios, and R/S enantiomeric ratio (0.0313 vs 0.0232); an increase in serum (R)-p-HPPH level was observed in patients with GH. In separate experiments, the effect of p-HPPH enantiomers on the proliferation of the normal human dermal fibroblast was studied. The in vitro study showed that (R)-p-HPPH selectively stimulated fibroblast growth. The results suggest that the least abundant metabolite, (R)-p-HPPH, is the most toxic with respect to gingival hyperplasia.

Genetic analysis of the S-mephenytoin polymorphism in a Chinese population

The 4'-hydroxylation of S-mephenytoin exhibits a polymorphism in humans, with the poor metabolizer phenotype exhibiting a lower frequency in white (3% to 5%) than in Oriental populations (13% to 23%). Two mutations in CYP2C19 (CYP2C19m1 and CYP2C19m2) have recently been described that account for approximately 85% of white and 100% of Japanese poor metabolizers. This study examines whether these mutations account for the poor metabolizer phenotype in the Chinese population. The metabolism of S-mephenytoin exhibited a bimodal distribution in 244 unrelated Chinese subjects, although the distribution of the two phenotypes overlapped. In 75 selected Chinese subjects, CYP2C19 genotype analysis predicted the phenotype with 100% accuracy. The frequency of the poor metabolizer phenotype was approximately 11% (95% confidence interval 7% to 15%). The frequency of the CYP2C19m1 allele was 0.289, whereas that of CYP2C19m2 was 0.044. Homozygous extensive metabolizers had slightly lower ratios of S/R-mephenytoin compared with heterozygous extensive metabolizers, showing a gene-dosage effect. These data show the advantages of genotype analysis in investigations of the mephenytoin phenotype in Oriental subjects.

Amitriptyline metabolism in elderly depressed patients and normal controls in relation to hypothalamic-pituitary-adrenal system function

The pharmacokinetics of amitriptyline (AMI) have been extensively studied, and a large interindividual variability between oral dose and concentration of the drug in plasma has been documented. The aim of this study was twofold: first, to compare AMI kinetics in depressed patients with those of healthy controls and, second, to describe the relationship between AMI levels in plasma and hypothalamic-pituitary-adrenal (HPA) system changes during depression. Thirty-eight patients with a DSM-III-R diagnosis of major depression and 13 healthy control persons received 75 mg of AMI daily for 6 weeks. Levels of AMI and nortriptyline in plasma were determined, and neuroendocrine testing with the combined dexamethasone-suppression/CRH-stimulation test (DST) was done before AMI administration and after weeks 1, 3, and 6 of medication. AMI levels in plasma were significantly higher in the patient group compared with controls during the entire treatment period, whereas nortriptyline levels did not differ between the two groups. Drug levels correlated significantly with age, but gender had no effect on the concentration of the drug in plasma. Twenty-two patients remitted after treatment. There was no difference in drug levels between responders and nonresponders. Fifteen patients were DST nonsuppressors before treatment; 23 patients and all controls suppressed cortisol after dexamethasone. DST suppressors had significantly higher AMI levels in plasma at weeks 3, 5, and 6 compared with DST nonsuppressors. In comparison to patients with high AMI levels in plasma, those with low drug concentration had higher postdexamethasone cortisol and adrenocorticotropic hormone levels and an increased hormone release after additional CRH.(ABSTRACT TRUNCATED AT 250 WORDS)

Comparison of the interaction potential of a new proton pump inhibitor, E3810, versus omeprazole with diazepam in extensive and poor metabolizers of S-mephenytoin 4'-hydroxylation

OBJECTIVE

To compare the interaction potential of E3810, [(+/-)-sodium 2-[[4-(3-methoxpropoxy)-3-methylpyridin-2-yl]methylsulfinyl] -1H-benzimidazole] a new proton pump inhibitor, and omeprazole with diazepam in relation to S-mephenytoin 4'-hydroxylation status.

STUDY DESIGN

Fifteen healthy male volunteers consisting of six poor metabolizers and nine extensive metabolizers of S-mephenytoin 4'-hydroxylation participated in the study, where two poor and three extensive metabolizers each as a group were randomly allocated to one of the three different treatment sequences with a 3-week washout period among the three trial phases. Each volunteer received an oral once-daily dose of E3810 (20 mg), omeprazole (20 mg), or placebo for 23 days and an intravenous dose (0.1 mg/kg) of diazepam on posttreatment day 8. Plasma concentrations of diazepam and demethyldiazepam were measured up to 16 days after the administration of diazepam.

RESULTS

Diazepam was more slowly metabolized in the poor metabolizers than in the extensive metabolizers. No significant effects of E3810 and omeprazole on any kinetic parameters of diazepam were observed in the poor metabolizers. In the extensive metabolizers, omeprazole significantly decreased the mean clearance of diazepam and increased its half-life, area under the plasma concentration-time curve, and mean residence time compared with E3810 and placebo (p < 0.05 or 0.01), whereas no changes in these kinetic parameters were observed during the treatment with E3810. Omeprazole significantly increased the mean area under the plasma concentration-time curve (0-16 days) of demethyldiazepam in the extensive metabolizers compared with placebo (p < 0.01), whereas E3810 significantly increased it in the poor metabolizers compared with omeprazole or placebo (p < 0.05).

CONCLUSION

The results indicate that E3810 as a substrate goes less toward S-mephenytoin 4'-hydroxylase (CYP2C19) and has a much weaker, if any, potential to interact with diazepam compared with omeprazole.

Comparison of the kinetic disposition and metabolism of E3810, a new proton pump inhibitor, and omeprazole in relation to S-mephenytoin 4'-hydroxylation status

We studied the kinetic disposition and metabolism of E3810 [(+/-)-sodium 2-[[4-(3-methoxypropoxy)-3-methylpyridin-2-yl]methylsulfinyl ]-1H- benzimidazole], a new proton pump inhibitor, and omeprazole in 15 Japanese male volunteers, six of whom were poor metabolizers and nine of whom were extensive metabolizers of S-mephenytoin. All received once-daily 20 mg doses of E3810 or omeprazole for 7 days in a randomized crossover manner, with a 3-week washout period between the two trial phases. The parent drugs and their principal metabolites in plasma and urine were measured on days 1 and 7 after drug administration. The mean values for area under the plasma concentration-time curve (AUC) of omeprazole were 6.3- and 4.4-fold greater, whereas those of E3810 were 1.8- and 1.9-fold greater in poor metabolizers than in extensive metabolizers after the first and final doses, respectively. Although the mean AUC values for both drugs were significantly (p < 0.01 or p < 0.05) greater in poor metabolizers than in extensive metabolizers, the difference in the AUC between the two groups was smaller after E3810 than after omeprazole administration. The AUC of omeprazole tended to increase with the repeated doses in extensive metabolizers, whereas no such change was observed for E3810. The urinary excretions of the principal metabolite(s) of two proton pump inhibitors also reflected the data derived from plasma samples in relation to S-mephenytoin 4'-hydroxylation status. We conclude that the metabolism of two proton pump inhibitors is under coregulatory control of S-mephenytoin 4'-hydroxylase (CYP2C19), but that the magnitude of CYP2C19-mediated metabolism appears to differ between the two drugs. In contrast to omeprazole, the metabolism of E3810 is less saturable in extensive metabolizers during the repetitive dosings.

Disposition and bioavailability of the beta 1-adrenoceptor antagonist talinolol in man

In an open randomized crossover study, the pharmacokinetics and bioavailability of the selective beta 1-adrenoceptor antagonist talinolol (Cordanum--Arzneimittelwerk Dresden GmbH, Germany) were investigated in twelve healthy volunteers (five female, seven male; three poor and nine extensive metabolizers of the debrisoquine hydroxylation phenotype) after intravenous infusion (30 mg) and oral administration (50 mg), respectively. Concentrations of talinolol and its metabolites were measured in serum and urine by HPLC or GC-MS. At the end of infusion a peak serum concentration (Cmax) of 631 +/- 95 ng mL-1 (mean +/- SD) was observed. The area under the serum concentration-time curve from zero to infinity (AUC0-infinity) was 1433 +/- 153 ng h mL-1. The following parameters were estimated: terminal elimination half life (t 1/2), 10.6 +/- 3.3 h; mean residence time, 11.6 +/- 3.1 h; volume of distribution, 3.3 +/- 0.5 L kg-1; and total body clearance, 4.9 +/- 0.6 mL min-1 kg-1. Within 36 h 52.8 +/- 10.6% of the administered dose was recovered as unchanged talinolol and 0.33 +/- 0.18% as hydroxylated talinolol metabolites in urine. After oral administration a Cmax of 168 +/- 67 ng mL-1 was reached after 3.2 +/- 0.8 h. The AUC0-infinity was 1321 +/- 382 ng h mL-1. The t 1/2 was 11.9 +/- 2.4 h. 28.1 +/- 6.8% of the dose or 55.0 +/- 11.0% of the bioavailable talinolol was eliminated as unchanged talinolol and 0.26 +/- 0.17% of the dose as hydroxylated metabolites by kidney. The absolute bioavailability of talinolol was 55 +/- 15% (95% confidence interval, 36-69%).(ABSTRACT TRUNCATED AT 250 WORDS)

High-performance liquid chromatographic determination of urinary 4'-hydroxymephenytoin, a metabolic marker for the hepatic enzyme CYP2C19, in humans

The preferential hydroxylation of (S)-mephenytoin to 4'-hydroxymephenytoin (4'-OH-M) displays a genetic polymorphism of drug metabolism in humans. Thus the excreted 4'-OH-M is considered to be an important marker for the hepatic (S)-mephenytoin 4'-hydroxylase. Accordingly, a mixture of urine containing total 4'-OH-M after enzymatic deconjugation and phenobarbital as internal standard (I.S.) was extracted with absolute diethyl ether. The residue remaining after evaporation was dissolved in 50 microliters of eluate and 20 microliters were injected into the chromatographic system. All components were separated isocratically on a reversed-phase column using acetonitrile-water (24:76, v/v) as the mobile phase at a flow-rate of 1.2 ml/min. The effluent was monitored at 204 nm. The retention times for 4'-OH-M and the I.S. were within 6 min. The absolute recovery was in the range 84-89% for 4'-OH-M and that of the I.S. was 75.9 +/- 4.2%. Quantification was performed by measuring the peak-height ratio compared with the ratio of the amount of 4'-OH-M divided by that of the I.S. The intra- and inter-day variations were less than 8% and 10%, respectively. The proposed method is simpler and more convenient than those reported previously. Its practical applicability was assessed by phenotyping the efficient and deficient hydroxylators among the Chinese minorities and Han Chinese populations.

Exploration of the metabolism of dihydrocodeine via determination of its metabolites in human urine using micellar electrokinetic capillary chromatography

After single-dose administration of 40 or 60 mg of dihydrocodeine (DHC, in a slow-release tablet) to four healthy individuals known to be extensive metabolizers of debrisoquine, the urinary excretion of DHC and its four major metabolites, dihydrocodeine-6-glucuronide, nordihydrocodeine, dihydromorphine and nordihydromorphine, was assessed using micellar electrokinetic capillary chromatography (MECC). DHC and two of its metabolites (dihydrocodeine-6-glucuronide and nordihydrocodeine) could be analyzed by direct urine injection, whereas the metabolic pattern was obtained by copolymeric bonded-phase extraction of the solutes from both plain and hydrolyzed urine specimens prior to analysis. The total DHC equivalents excreted within 8 and 24 h were determined to be 30.4 +/- 7.7% (n = 5) and 63.8 +/- 6.1% (n = 2), respectively, and only about 4% of the excreted DHC equivalents were identified as morphinoids. Furthermore, almost no morphinoid metabolites of DHC could be found after administration of quinidine (200 mg of quinidine sulfate) 2 h prior to DHC intake.

The hydroxylation of omeprazole correlates with S-mephenytoin metabolism: a population study

We compared omeprazole and mephenytoin as probes for the CYP2C19 metabolic polymorphism. Single oral doses of omeprazole (20 mg) or mephenytoin (100 mg) were administered at least 1 week apart to 167 healthy volunteers. Mephenytoin metabolism was measured using the amount of 4'-hydroxymephenytoin and the S/R ratio of mephenytoin in an 8-hour urine collection. Omeprazole hydroxylation was measured using the ratio of omeprazole to 5'-hydroxyomeprazole in serum 2 hours after dosing. All three methods separated poor- or extensive-metabolizer phenotypes with complete concordance. Omeprazole hydroxylation correlated with the S/R ratio of mephenytoin in extensive metabolizers (r2 = 0.681; p < 0.001). Genotyping tests showed that six poor metabolizers of omeprazole were homozygous for a single base pair mutation in exon 5 of CYP2C19. These results support the hypothesis that omeprazole 5'-hydroxylation cosegregates with the CYP2C19 metabolic polymorphism.

Phenotyping and genotyping of S-mephenytoin hydroxylase (cytochrome P450 2C19) in a Shona population of Zimbabwe

The S-mephenytoin hydroxylase has recently been identified as cytochrome P450 2C19 (CYP2C19). This enzyme metabolizes mephenytoin, diazepam, omeprazole, and citalopram and has been shown to be polymorphically distributed. One clinical implication of CYP2C19-dependent drug metabolism for persons who reside in tropical regions is in the use of the antimalarial drug chloroguanide hydrochloride, which is apparently biotransformed to its active metabolite by this isozyme. In this investigation we studied mephenytoin metabolism in 103 black Zimbabwean Shona subjects. Four were identified as poor metabolizers (4%). This prevalence is comparable to that in white subjects (2% to 5%) but lower than the 15% to 20% incidence of poor metabolizers among Oriental subjects. Of the subjects phenotyped, 84 were genotyped for the G-->A mutation in exon 5 of CYP2C19, which creates a cryptic splice site, causing the production of a nonfunctional protein. Three of the four poor metabolizers were homozygous for this mutation, whereas the fourth one was heterozygous. The G-->A mutation has been shown to predict the incidence more than 60% of poor metabolizers among white subjects and Japanese subjects, and in the current investigation we also obtained a similar relationship in the black population.

Pharmacogenetics in clinical pharmacology and toxicology

This subject was particularly important to discuss in the presence of Werner Kalow, 77 years young, who is considered as one of the grandfathers of this unique combination of medical research fields. It has become increasingly appreciated that dozens of human drug metabolism polymorphisms exist. The interindividual variabilities in drug metabolism discussed at this symposium do not represent small differences such as 50% or 3-fold but, rather, represent 10- to greater than 1000-fold differences. When attributed to a single gene, dramatic differences can be seen among family members, just as blue and brown eyes can occur in siblings. These differences can result in acute drug toxicity. In addition, there are chronic effects: over one's lifetime, striking differences in the metabolism of drugs, occupationally hazardous chemicals, and other environmental pollutants can lead to interindividual differences in the buildup of DNA damage (e.g., mutations, chromosomal breaks, rearrangements) leading to toxicity and tumor initiation, as well as leading to a buildup in nongenotoxic signals (signal transduction pathways without DNA damage) important for toxicity, tumor promotion, and tumor progression. The human UDP glucuronosyltransferase (UGT superfamily is known to comprise more than 10 genes in humans, and probably in other mammalian species. Breakthroughs in UGT gene mutations responsible for the Crigler-Najjar syndrome and Gilbert's disease have recently been reported. The human cytochrome P450 termed CYP3A4 is a major P450 enzyme in the liver and gastrointestinal tract, and the full impact of the CYP3A4 polymorphism has yet to be fully appreciated.(ABSTRACT TRUNCATED AT 250 WORDS)

Individual and group dose-responses to intravenous omeprazole in the first 24 h: pH-feedback-controlled and fixed-dose infusions

1. Individual responses to intravenous boli of omeprazole have shown considerable variability. Data on the individual responses to the new omeprazole infusion formulation are lacking. 2. Individual dose-responses in the first 24 h of fixed-dose and pH-feedback-controlled infusions of omeprazole were assessed in two randomised, third-party blinded, cross-over studies, using two separate groups of eight healthy subjects. In study A, feedback-controlled infusions of omeprazole (target pH 5, dose range 0-12 mg h-1) and fixed-dose infusions (8 mg h-1) were compared, both with an initial bolus of 80 mg. Omeprazole plasma concentrations were measured. Study B assessed the effect on individual pH-control of a loading bolus of either 40 mg or 80 mg omeprazole, followed by feedback-controlled infusions. 3. Study A: the median % time of pH > 5 was 71.2 (total range: 48.9-83.2) with feedback infusions and 57.9 (28.0-95.3) with fixed-dose infusions (P = 0.06). The mean 24 h infusion doses were 173.1 mg (44.5-253.1) in the feedback group and 192 mg in the fixed-dose group. The AUC of omeprazole plasma concentrations ranged widely, but correlated with the % time of pH > 5 during fixed-dose infusions. Study B: initial boli of 40 mg and 80 mg of omeprazole resulted in similar 24 h median % of time with pH > 5, 69.2 (49.9-78.8) and 69.6 (44.4-87.7), respectively. Mean omeprazole doses infused by feedback pump were 187.6 mg (83.1-253.6) after 40 mg boli and 159.9 mg (61.8-227.0) after 80 mg boli.(ABSTRACT TRUNCATED AT 250 WORDS)

Possible association between poor metabolism of mephenytoin and hepatotoxicity caused by Atrium, a fixed combination preparation containing phenobarbital, febarbamate and difebarbamate

Drug hepatotoxicity is partially determined by genetic factors involved in drug metabolism, which may involve the debrisoquine oxidation polymorphism mediated by cytochrome (CYP) 2D6. The purpose of this study was to assess the relationship between drug hepatotoxicity and another genetic polymorphism of drug oxidation, namely that of S-mephenytoin metabolism mediated by CYP2CMP. Mephenytoin hydroxylation capacity was assessed by a hydroxylation index in 24 patients with drug-induced hepatitis and in 23 healthy controls. Hydroxylation index was calculated as the ratio of S-mephenytoin dose to the (0-10 h) urinary excretion of 4-hydroxymephenytoin after oral administration of 100 mg racemic mephenytoin. The test was performed following the patient's recovery. In three patients, hepatitis was related to Atrium, a drug containing phenobarbital, febarbamate and difebarbamate. The mean hydroxylation index (+/- SD) value in patients with Atrium hepatitis (12.4 +/- 8.3) was markedly higher than that found in healthy controls (1.8 +/- 0.4) or in patients with other drug-induced hepatitis (2.5 +/- 3.3). Mean hydroxylation index values were similar in the two latter groups. Considered individually, oxidation capacity was low (hydroxylation index > 9) in two of the three patients with Atrium hepatitis and intermediate (hydroxylation index between 4 and 9) in the third patient. In contrast, all 23 healthy subjects exhibited a high oxidation capacity (hydroxylation index < 4). In the 21 patients with other drug-induced hepatitis, oxidation capacity was high in 19 subjects, intermediate in one subject with chlorpromazine hepatitis, and low in one subject with dapsone hepatitis.(ABSTRACT TRUNCATED AT 250 WORDS)

Fluorescence in situ hybridization analysis of chromosomal localization of three human cytochrome P450 2C genes (CYP2C8, 2C9, and 2C10) at 10q24.1

Chromosomal localization of three human cytochrome P450 genes belonging to the CYP2C subfamily (CYP2C8, 2C9, and 2C10) was identified by fluorescence in situ hybridization (FISH). An original MP-8 clone was used as a DNA probe for the assignment of the CYP2C10 gene, while two cDNA probes, a 1.37 kb fragment of CYP2C8 and a 1.19 kb fragment of CYP2C9, were obtained after amplifying the predicted fragments (MP-20 and MP-4 clones, respectively) by polymerase chain reaction using a single human liver cDNA library. The results showed that three human CYP2C8, 2C9, and 2C10 cDNAs were located at the same subchromosomal region, 10q24.1.

Diazepam metabolism by human liver microsomes is mediated by both S-mephenytoin hydroxylase and CYP3A isoforms

1. The primary metabolism of diazepam was studied in human liver microsomes in order to investigate the kinetics and to identify the cytochrome P450 (CYP) isoforms responsible for the formation of the main diazepam metabolites, temazepam and N-desmethyldiazepam. 2. The formation kinetics of both metabolites were atypical and consistent with the occurrence of substrate activation. A sigmoid Vmax model equivalent to the Hill equation was used to fit the data. The degree of sigmoidicity was greater for temazepam formation than for N-desmethyldiazepam formation, so that the ratio of desmethyldiazepam:temazepam formation increased as the substrate (diazepam) concentration decreased. 3. alpha-Naphthoflavone activated both reactions but with a greater effect on temazepam formation than on N-desmethyldiazepam formation. In the presence of 25 microM alpha-naphthoflavone the kinetics for both pathways were approximated by Michaelis-Menten kinetics. 4. Studies with a series of CYP isoform selective inhibitors and with an inhibitory anti-CYP2C antibody indicated that temazepam formation was carried out mainly by CYP3A isoforms, whereas the formation of N-desmethyldiazepam was mediated by both CYP3A isoforms and S-mephenytoin hydroxylase.