Can the genotype or phenotype of two polymorphic drug metabolising cytochrome P450-enzymes identify oral lichenoid drug eruptions?

BACKGROUND: Lichenoid drug eruptions (LDE) in the oral cavity are adverse drug reactions (ADR) that are impossible to differentiate from oral lichen planus (OLP) as no phenotypic criteria exist. Impaired function of polymorphic cytochrome 450-enzymes (CYPs) may cause increased plasma concentration of some drugs resulting in ADR/LDE. In an earlier study we did not find more patients with OLP (OLPs) with impaired CYP-genotype. OBJECTIVES: To test if more OLPs have an impaired CYP-phenotype than to be expected from the CYP-genotype and to find clinical criteria characterising oral LDE. METHODS: One hundred and twenty OLPs were genotyped for the most common polymorphisms of CYP2D6 and CYP2C19 that result in impaired function. One hundred and ten did a phenotype test of both enzymes. The exposure to drugs and polypharmacy and the CYP metabolism of the drugs were evaluated. The OLP manifestations were registered. RESULTS: The only difference in OLP manifestations was that patients with a CYP2D6 genotype with less than two fully functional alleles presented more asymmetrical OLP distribution in particular in non-medicated patients (P < 0.05). No more OLPs than expected from the genotype had a phenotype with reduced function. However, the established phenotypic categories could not differentiate between the genotypes with two or one fully functional allele. Nevertheless, among the patients with a phenotype with normal function the patients with only one functional allele had a statistically significant higher metabolic ratio compared to patients with two fully functional alleles (P < 0.05). CONCLUSION: It was not possible to identify LDE by impaired function of polymorphic CYPs.

Liver disease selectively modulates cytochrome P450--mediated metabolism.

BACKGROUND: The liver plays a significant role in drug metabolism; thus it would be expected that liver disease may have a detrimental effect on the activity of cytochrome P450 (CYP) enzymes. The extent to which the presence and severity of liver disease affect the activity of different individual drug-metabolizing enzymes is still not well characterized. The purpose of this study was to assess the effect of liver disease on multiple CYP enzymes by use of a validated cocktail approach. METHODS: The participants in this investigation were 20 patients with different etiologies and severity of liver disease and 20 age-, sex-, and weight-matched healthy volunteers. Liver disease severity was categorized by use of the Child-Pugh score. All participants received a cocktail of 4 oral drugs simultaneously, caffeine, mephenytoin, debrisoquin (INN, debrisoquine), and chlorzoxazone, as in vivo probes of the drug-metabolizing enzymes CYP1A2, CYP2C19, CYP2D6, and CYP2E1, respectively. The primary end points were measurements of specific CYP metabolism indexes for each enzyme. RESULTS: Mephenytoin metabolism was significantly decreased in both patients with mild liver disease (Child-Pugh score of 5/6) (-63% [95% confidence interval (CI), -86% to -40%]; P = .0003) and patients with moderate to severe liver disease (Child-Pugh score >6) (-80% [95% CI, -95% to -64%]; P = .0003). In comparison with control subjects, the caffeine metabolic ratio was 69% lower (95% CI, -85% to -54%; median, 0.14 versus 0.62; P = .0003), the debrisoquin recovery ratio was 71% lower (95% CI, -96% to -47%; median, 0.10 versus 0.65; P = .012), and the chlorzoxazone metabolic ratio was 60% lower (95% CI, -91% to -29%; median, 0.21 versus 0.83; P = .0111) in patients with moderate to severe liver disease. All 4 drugs showed significant negative relationships with the Child-Pugh score. CONCLUSIONS: CYP enzyme activity is differentially affected by the presence of liver disease. We propose that the data can be explained by the "sequential progressive model of hepatic dysfunction," whereby liver disease severity has a differential effect on the metabolic activity of specific CYP enzymes.

Genetic predisposition to bladder cancer: ability to hydroxylate debrisoquine and mephenytoin as risk factors.

The hypothesis that the frequency distribution of indices of oxidative drug-metabolizing activity is different between patients with bladder cancer (n = 98) and age, sex-matched control subjects (n = 110) has been investigated. Urinary recovery ratios of debrisoquine and R/S ratios of mephenytoin have been measured in an 8-h urine sample after simultaneous administration of debrisoquine (10 mg) and racemic mephenytoin (100 mg). In addition, alcohol consumption, smoking habit, and acetylation phenotype (using 100 mg dapsone as a substrate) have been measured. Patients with bladder cancer were classified on histological criteria as having aggressive (Stage III) (34%) or nonaggressive (Stages I and II) (66%) disease. The median of the frequency distribution of the debrisoquine urinary recovery ratio in patients with aggressive bladder cancer was greater than in control subjects, and only four patients had recovery ratios lower than the mean of the control group. Using logistic regression analysis, efficient debrisoquine metabolism and a synergistic interaction between smoking and ethanol consumption were significant, independent risk factors, while S-mephenytoin hydroxylation and acetylation phenotype were not significant risk factors. In contrast, patients with non-aggressive bladder cancer had a significant, but weaker, association with rapid hydroxylation of S-mephenytoin, which was independent of a significant synergistic interaction between smoking and alcohol consumption. Acetylation phenotype and debrisoquine urinary recovery ratio were not associated with increased risk of nonaggressive cancer. These results are consistent with the concept that oxidative isozymes might be responsible for conversion of environmental agents to proximate bladder carcinogens in nonindustrial-related bladder cancer. They also suggest that different etiological factors are involved in the pathogenesis of aggressive and nonaggressive bladder cancer.

An S-mephenytoin cysteine conjugate identified in urine of extensive but not of poor metabolizers of S-mephenytoin.

A conjugate of S-mephenytoin excreted in urine of extensive but not of poor metabolizers of S-mephenytoin has previously been reported. This conjugate, which is easily hydrolysed back to S-mephenytoin, has now been isolated and identified in urine from one extensive metabolizer after a single dose of 100 mg racemic mephenytoin. High performance liquid chromatography purification, followed by gas chromatographic, mass spectrometric and amino acid analyses showed that the isolated compound is a cysteine conjugate of S-mephenytoin. The significant mass spectrometric ions have been confirmed in three additional extensive metabolizers of S-mephenytoin, but were not detectable in urine from three poor metabolizer subjects. The exact structure of the conjugate is unknown, but we suggest that an S-N bond between cysteine and S-mephenytoin is formed via an oxidative radical mechanism catalyzed by CYP2C19.

A methodological investigation on the estimation of the S-mephenytoin hydroxylation phenotype using the urinary S/R ratio.

After a single oral dose of racemic mephenytoin the S/R ratio in urine can be used to phenotype extensive (EM) and poor metabolizers (PM) of S-mephenytoin. We confirmed the increased S/R ratio by storage time in EM because of the hydrolysis of a conjugate of S-mephenytoin excreted in EM, but not in PM. The S/R ratio in the 0-8 h urine increased 8- to 127-fold (from 0.22 +/- 0.16 to 9.9 +/- 11.3) after acid treatment of urine from 30 EM, but there was no effect of acid in that of 12 PM. We suggest that the phenotype of mephenytoin in combination with debrisoquine can be determined in the 0-8 h urine by estimating the mephenytoin S/R ratio before and after acid treatment.

Mephenytoin phenotyping: lack of haematologic effect and timing of urine collections.

Mephenytoin is the prototype substrate for the genetically regulated, polymorphically distributed cytochrome P450, mephenytoin hydroxylase. Mephenytoin is an anticonvulsant which has been associated with leukopenia when used chronically. The haematologic effects of a single dose of oral mephenytoin, as is typically used to determine drug metabolism phenotype for this polymorphism, have not been reported. We administered 100 mg oral racemic mephenytoin to 30 healthy male volunteers and measured complete blood count three times weekly for 23 days. The time dependency of the urinary ratio of S to R mephenytoin in five serial urine samples (0-4, 4-8, 8-16, 16-24 and 24-32 h after the dose) was evaluated. There were no significant decreases from baseline in any subject in leukocyte count, haematocrit or platelet count. Two of the 30 subjects both of Indian extraction, were poor metabolizers of mephenytoin. The S:R ratio decreased with time (p = 0.001). Using the 0-4 h urine, one subject would have been misphenotyped as a poor metabolizer; phenotype assignments were in agreement with each other based on all subsequent urine collections. We conclude that there is no evidence that single dose mephenytoin is associated with haematologic toxicity in healthy male volunteers, and that the 4-8 h post-dose urine is as reliable as the 24-32 h collection for assignment of phenotype.

S-mephenytoin 4-hydroxylase is inherited as an autosomal-recessive trait in Japanese families.

The 4-hydroxylation of S-mephenytoin exhibits polymorphism in both whites and Japanese such that the populations can be divided into extensive and poor metabolizers. To determine whether genetic constitution is a primary determinant in the expression of such metabolism, four extended Japanese families containing 13 sets of parent/offspring relationships were phenotyped for their mephenytoin 4-hydroxylation activity using the 8-hour urinary ratio of unchanged R- and S-mephenytoin as the trait measurement. The incidence of the poor metabolizer phenotype in these families was 2.2 times greater than that in an unrelated Japanese population. In three families in which both parents were poor metabolizers of mephenytoin, all six children also exhibited the poor metabolizer trait. The phenotype distribution for each family studied was consistent with the hypothesis that mephenytoin 4-hydroxylation activity is under diallelic, monogenic control, with the poor metabolizer phenotype being the autosomal recessive homozygous genotype and the extensive metabolizer phenotype including both the autosomal dominant and heterozygous genotypes.

Sparteine and mephenytoin oxidation: genetic polymorphisms in east and west Greenland.

The oxidation of sparteine and mephenytoin was examined in a group of subjects living in Greenland: 300 in East Greenland and 171 in West Greenland. The distribution of the ratio between the chromatographic peak areas of S- and R-mephenytoin in the urine, the S/R ratio was clearly bimodal in both populations. Thus 9.3% of the East Greenlanders had S/R ratios of 0.9 or more and were phenotyped as poor metabolizers of mephenytoin. In the West Greenlanders, 2.9% of the sample had S/R ratios of 0.90 or more and were accordingly phenotyped as poor metabolizers. The intraethnic difference with regard to the frequency of the mephenytoin poor metabolizer is probably attributable in part to a much higher proportion of admixed Caucasian genes in the West Greenlanders than in the East Greenlanders. In both the East and the West Greenlanders, the sparteine metabolic ratio displayed marked interindividual differences without a clear bimodal distribution. Poor metabolizers arbitrarily defined as subjects with an metabolic ratio of 20 or more made up 3.3% of the East Greenlanders and 2.3% of the West Greenlanders, but the difference between the two groups was not statistically significant.

Polymorphic metabolism of mephenytoin in man: pharmacokinetic interaction with a co-regulated substrate, mephobarbital.

The simultaneous dosing of two drugs with co-regulated genetic polymorphisms determined by a single cytochrome P-450 isozyme could result in competitive inhibition of metabolism. We investigated this hypothesis in vivo by studying the interaction of mephobarbital and mephenytoin in eight normal subjects with wide variability in S-mephenytoin 4-hydroxylation. Each received oral racemic mephenytoin (100 mg) alone and, on a separate occasion, 1 hour after oral racemic mephobarbital (200 mg). After mephenytoin dosing alone, the 8-hour urinary enantiomeric (R/S) ratio indicated one poor (PM), one intermediate (IM), and six extensive (EM) metabolizers. Total intrinsic clearance of S-mephenytoin varied more than 100-fold, whereas the range for R-mephenytoin was only twofold. The urinary R/S ratio correlated (r = 0.92) with the enantiomeric ratio of the plasma AUCs over the same period, indicating no stereoselectivity in renal clearance. When mephenytoin was taken in the presence of mephobarbital, peak levels and AUC of S-mephenytoin increased while those of the R-enantiomer remained unchanged. Accordingly, the R/S ratios in both plasma and urine were reduced, with the change rank order-related to the control value of the total intrinsic clearance of S-mephenytoin (i.e., greatest in the most extensive EM). Thus the urinary R/S ratio can be used as a measure of the enantiomeric ratio of the plasma concentrations over the same time period of collection. Moreover, this ratio may be used to detect drug interactions that involve the cytochrome P-450 isozyme(s) responsible for the polymorphic 4-hydroxylation of mephenytoin.(ABSTRACT TRUNCATED AT 250 WORDS)

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.

Mephenytoin hydroxylation deficiency in Caucasians: frequency of a new oxidative drug metabolism polymorphism.

The ability of normal subjects to hydroxylate mephenytoin (100 mg) or debrisoquine (10 mg) after oral dosing was investigated in 156 unrelated Caucasians living in middle Tennessee. Urinary recovery of 4-hydroxymephenytoin (4-OH-M) and the urinary S:R enantiomeric ratio of mephenytoin measured in an 8-hr urine sample were investigated as phenotypic traits for mephenytoin, and the urinary metabolic ratio of debrisoquine was used to determine the debrisoquine hydroxylase phenotype. Both urinary 4-OH-M and the S:R ratio of mephenytoin discriminated between extensive (EM) and poor (PM) metabolizers of mephenytoin. The frequencies of PMs for mephenytoin and debrisoquine hydroxylation activity were 2.6% and 7.0%. These two defects in oxidative metabolism were not observed in the same subjects, which suggests that 4-hydroxylation of mephenytoin is a new polymorphism independent of that for debrisoquine.

Interethnic differences in genetic polymorphism of debrisoquin and mephenytoin hydroxylation between Japanese and Caucasian populations.

Interethnic differences in debrisoquin and mephenytoin hydroxylation have been compared between normal white (n = 183) and Japanese (n = 100) subjects with the 8-hour urinary metabolic ratio of debrisoquin and the urinary S/R enantiomeric ratio of mephenytoin to identify extensive (EM) and poor (PM) metabolizers. In white subjects the frequency of PMs was 8.7% and 2.7% for debrisoquin and mephenytoin, respectively. In contrast, in Japanese subjects no PMs of debrisoquin were identified, while the incidence of PMs of mephenytoin was 18%. These substantial differences (P less than 0.001) in polymorphic distributions of oxidative drug metabolizing ability have implications for interethnic efficacy and toxicity of drugs and other xenobiotics that are metabolized by the involved cytochrome P-450 isozymes.

Stereoselective mephobarbital hydroxylation cosegregates with mephenytoin hydroxylation.

The 8-hour urinary recovery of 4-hydroxy-mephobarbital has been measured after oral administration of racemic mephobarbital (90 mg) in 17 extensive (EM) and six poor (PM) metabolizer phenotypes of mephenytoin. The recovery of this metabolite was measurable in every EM and ranged from 2.5% to 48% (10.9% +/- 1.9% of dose), but was not detected in any PM (less than 1% of dose). In EMs, the 8-hour urine recovery of 4-OH-mephobarbital after mephobarbital was approximately half that of 4-OH-mephenytoin over the same time after mephenytoin administration. One EM received similar doses of R- and S-mephobarbital on separate occasions. Urinary recovery of 4-OH-mephobarbital was 33% and less than 1%, respectively. These results suggest that mephobarbital is stereoselectively hydroxylated by the same drug metabolizing enzyme that is responsible for the stereoselective aromatic hydroxylation of mephenytoin.

Mephenytoin and sparteine pharmacogenetics in Canadian Caucasians.

The frequency of genetically deficient hydroxylation of mephenytoin (M-defect) was studied in 83 healthy Caucasians living in Toronto. The M-defect was compared with the widely studied genetic polymorphism of sparteine/debrisoquine oxidations (S-defect). After ingestion of mephenytoin and sparteine, urine samples (0 to 24 hr) were analyzed for p(4')-hydroxymephenytoin and urine samples over 0 to 12 hr were analyzed for sparteine and 2-and 5-dehydrosparteine by gas chromatographic methods. Nirvanol, the N-demethylation product of mephenytoin, was determined by a newly developed gas chromatographic/mass spectrometric method. Frequency distributions of both p-hydroxymephenytoin and dehydrosparteine excreted in urine were discontinuous (bimodal), while nirvanol and sparteine data were normally distributed. Two poor metabolizers of mephenytoin excreted 2% to 3% of the dose as p-hydroxymephenytoin and excreted normal amounts of nirvanol, but they were extensive metabolizers of sparteine. Six poor metabolizers of sparteine were found to be extensive metabolizers of mephenytoin (34% to 42% excreted in urine as p-hydroxyme-phenytoin). Thus the M-defect occurs among Canadian Caucasians with a frequency of 2% (0.0% to 7.5% with a confidence limit of 99%) and is independent of the S-defect.

Enantioselective amitriptyline metabolism in patients phenotyped for two cytochrome P450 isozymes.

In 26 hospitalized patients with depression, a combined pharmacogenetic test with dextromethorphan, a substrate of cytochrome P450IID6, and mephenytoin, the S-form of which is hydroxylated by a P450IIC isozyme, was carried out before amitriptyline therapy. Metabolites were determined in 24-hour urine samples collected on treatment day 8, and the contributions of individual compounds, including the four isomers of 10-hydroxyamitriptyline and 10-hydroxynortriptyline to total excretion were calculated. Formation of (-)-E-10-hydroxyamitriptyline and (-)-E-10-hydroxynortriptyline apparently depends on the activity of cytochrome P450IID6 because negative correlations existed between the log metabolic ratio of dextromethorphan and the relative quantities of these enantiomers. In contrast, correlations were positive for nortriptyline, (+)-E-10-hydroxynortriptyline, (-)-Z-10-hydroxynortriptyline, and (+)-Z-10-hydroxynortriptyline. The mephenytoin hydroxylase seems to participate in side-chain demethylation to the secondary and primary amines, because the log metabolic ratio of mephenytoin correlated negatively with the relative quantity of E-10-hydroxydidesmethylamitriptyline and positively with that of amitriptyline and its N-glucuronide.

Incidence of S-mephenytoin hydroxylation deficiency in a Korean population and the interphenotypic differences in diazepam pharmacokinetics.

We studied the genetically determined hydroxylation polymorphism of S-mephenytoin in a Korean population (N = 206) and the pharmacokinetics of diazepam and demethyldiazepam after an oral 8 mg dose of diazepam administered to the nine extensive metabolizers and eight poor metabolizers recruited from the population. The log10 percentage of 4-hydroxymephenytoin excreted in the urine 8 hours after administration showed a bimodal distribution with an antimode of 0.3. The frequency of occurrence of the poor metabolizers was 12.6% in the population. In the panel study of diazepam in relation to the mephenytoin phenotype, there was a significant correlation between the oral clearance of diazepam and log10 urinary excretion of 4-hydroxymephenytoin (rs = 0.777, p less than 0.01). The plasma half-life of diazepam in the poor metabolizers was longer than that in the extensive metabolizers (mean +/- SEM, 91.0 +/- 5.6 and 59.7 +/- 5.4 hours, p less than 0.005), and the poor metabolizers had the lower clearance of diazepam than the extensive metabolizers (9.4 +/- 0.5 and 17.0 +/- 1.4 ml/min, p less than 0.001). In addition, the plasma half-life of demethyldiazepam showed a statistically significant (p less than 0.001) difference between the extensive metabolizers (95.9 +/- 11.3 hours) and poor metabolizers (213.1 +/- 10.7 hours), and correlated with the log10 urinary excretion of 4-hydroxymephenytoin (rs = -0.615, p less than 0.01). The findings indicate that the Korean subjects have a greater incidence of poor metabolizer phenotype of mephenytoin hydroxylation compared with that reported from white subjects and that the metabolism of diazepam and demethyldiazepam is related to the genetically determined mephenytoin hydroxylation polymorphism in Korean subjects.

Mephenytoin disposition and serum bile acids as indices of hepatic function in chronic viral hepatitis.

BACKGROUND AND OBJECTIVES: The effect of chronic viral hepatitis on liver function may vary from none to hepatic failure. Changes in function are usually the result of impaired hepatocyte function or altered vascular flow and architecture. Conventional liver function tests usually cannot distinguish contributions from these mechanisms or indicate degree of hepatic metabolic dysfunction. An alternative approach is to measure the hepatic metabolism of a highly extracted compound whose oral clearance and systemic bioavailability are dependent on both hepatocyte function and degree of portosystemic shunt. METHODS: The stereoselective metabolism of racemic mephenytoin (100 mg oral dose) was investigated in 35 patients with chronic viral hepatitis and compared with 153 healthy subjects. The mephenytoin R/S enantiomeric ratio and cumulative excretion of the 4'-hydroxymephenytoin metabolite in a 0- to 8-hour urine sample were used in addition to serum bile acid levels and pathologic examination of biopsy specimens to assess the severity of hepatic dysfunction and portosystemic shunting. RESULTS: The patients as a group excreted less 4'-hydroxymephenytoin and had a smaller R/S enantiomeric ratio of mephenytoin. The two measures were discriminatory between the patient groups classified by either serum cholylglycine level or pathologic examination of biopsy specimens. Combination of the two measures of mephenytoin metabolism allowed the patients to be classified into three groups: normal hepatocyte function without portosystemic shunt, normal hepatocyte function with portosystemic shunt, and low hepatocyte function with or without portosystemic shunt. CONCLUSION: This study has shown the potential usefulness of mephenytoin metabolism as a sensitive indicator of hepatic pathologic condition with an ability to discriminate between contributory alternative mechanisms.

Comparison of chloroguanide and mephenytoin for the in vivo assessment of genetically determined CYP2C19 activity in humans.

OBJECTIVES: The main objective of this study was to examine the relations between chloroguanide (proguanil) and mephenytoin metabolic ratios to determine whether or not chloroguanide could replace mephenytoin as a probe for the indirect in vivo measurement of CYP2C19 activity. An additional objective was to examine the interactions between chloroguanide, omeprazole, and mephenytoin, which are three substrates of CYP2C19. METHODS: Twenty healthy volunteers received 200 mg chloroguanide orally on three separate occasions in an open, randomized-sequence crossover design: once alone, once 2 hours before the oral administration of 100 mg mephenytoin, and once after oral administration for 7 days of 40 mg/day omeprazole. During one additional period, 100 mg mephenytoin was administered orally. The chloroguanide to cycloguanil ratio was determined in plasma 4 hours after drug administration; it was determined in urine collected over 4, 8, and 24 hours. The mephenytoin hydroxylation index was also measured in urine. RESULTS: All subjects were extensive metabolizers of chloroguanide and mephenytoin. We found no correlation between the mephenytoin hydroxylation index and the chloroguanide to cycloguanil ratio in any of the urine samples collected or in plasma. In the presence of chloroguanide, mephenytoin hydroxylation index increased from a baseline value of 1.2 +/- 0.2 to 1.7 +/- 1.0 (p < 0.05). In the presence of omeprazole, the chloroguanide to cycloguanil metabolic ratio in 24-hour urine increased from 2.2 +/- 1.0 to 5.6 +/- 3.2 (p < 0.001). CONCLUSION: Chloroguanide inhibits the CYP2C19-dependent 4'-hydroxylation of mephenytoin. The bioactivation of chloroguanide to cycloguanil is inhibited by the CYP2C19 substrate omeprazole. However, the chloroguanide to cycloguanil metabolic ratio does not reflect the same array of S-mephenytoin hydroxylase activities found in extensive metabolizers as that show by the mephenytoin hydroxylation index.

Phenotypic-genotypic analysis of CYP2C19 in the Jewish Israeli population.

OBJECTIVES: Evaluation of CYP2C19 activity and the frequency of CYP2C19 alleles in the Jewish Israeli population. METHODS: One hundred forty Jewish Israeli subjects received 100 mg racemic mephenytoin and collected urine for 8 hours. Urinary concentrations of mephenytoin enantiomers and 4'-hydroxymephenytoin were determined by gas-liquid chromatography and HPLC, respectively. CYP2C19 activity was derived from urinary S/R-ratio and 8-hour urinary excretion of 4'-hydroxymephenytoin. Mutations were identified by polymerase chain reaction and enzyme digestion with SmaI (CYP2C19*2) and BamHI (CYP2C19*3). RESULTS: Deficient mephenytoin hydroxylation was found in 4 subjects (2.9%; 95% confidence interval [CI], 0.1% to 5.7%) who were homozygous for CYP2C19*2. CYP2C19*2 was the major deactivating allele accounting for 15% (95% CI, 11% to 19%) of CYP2C19 alleles, whereas CYP2C19*3 was identified in 2 subjects (1%; 95% CI, 0% to 2%). Among 136 extensive metabolizers, 99 were homozygous for CYP2C19*1 and 37 were compound heterozygous CYP2C19*1/CYP2C19*2 (35 subjects) or CYP2C19*1/CYP2C19*3 (2 subjects). Gene dose effect was noted so that the S/R-ratio was significantly greater and urinary excretion of 4'-hydroxymephenytoin was significantly lower in compound heterozygous than in homozygous extensive metabolizers (0.310+/-0.209 versus 0.225+/-0.176, P < .04 and 48.6%+/-19.2% versus 56.3%+/-16.0%, P < .03, respectively). Female extensive metabolizers had a significantly lower excretion of 4'-hydroxymephenytoin than male extensive metabolizers (49.5%+/-17.6% versus 58.4%+/-16.7%, respectively, P < .005). CONCLUSION: The frequency of poor metabolizers of CYP2C19 and CYP2C19*2 allele in the Jewish Israeli population resembles findings in non-Asian populations. Complete concordance was noted between phenotypic and genotypic findings. CYP2C19 genotyping may enable subclassification of extensive metabolizers into subjects with high and low activity.

Chloroguanide metabolism in relation to the efficacy in malaria prophylaxis and the S-mephenytoin oxidation in Tanzanians.

S-Mephenytoin and chloroguanide (proguanil) oxidation was studied in 216 tanzanians. The mephenytoin S/R ratio in urine ranged from <0.1 to 1.16. The distribution was skewed to the right, without evidence of a bimodal distribution. Ten subjects (4.6%, 2.2% to 8.3%, 95% CI) with an S/R mephenytoin ratio >0.9, were arbitrarily defined as poor metabolizers of mephenytoin. The chloroguanide/cycloguanil ratio ranged from 0.82 to 249. There was a significant correlation between the mephenytoin S/R ratio and the chloroguanide/cycloguanil ratios (rs = 0.73; p<0.00001). This indicates that cytochrome P4502C19 or CYP2C19 is a major enzyme that catalyzes the bioactivation of chloroguanide to cycloguanil. Chloroguanide is a pro-drug, and hence a low CYP2C19 activity may lead to prophylactic failure caused by inadequate formation of cycloguanil. Fifty-eight women who previously took either 200 mg chloroguanide daily (n = 26) or 200 mg chloroguanide daily plus 300 mg chloroquine weekly (n = 32) in a malaria chemoprophylaxis study showed that there was significant correlation between the number of earlier breakthrough parasitemia episodes and the chloroguanide/cycloguanil ratio (rs = 0.30; p = 0.02). The breakthrough rate did not correlate with the S/R mephenytoin ratio. However, other factors, such as exposure to mosquitoes and sensitivity of the plasmodium to cycloguanil, are probably more important.