Amitriptyline pharmacokinetics and clinical response: II. Metabolic polymorphism assessed by hydroxylation of debrisoquine and mephenytoin

A subgroup of 16 out of 30 endogenous depressive inpatients (cf. part I), treated for 3 weeks with 150 mg amitriptyline (AT) daily, participated in a pharmacogenetic study: all were phenotyped with debrisoquine and 3 of them with mephenytoin. Four patients were found to be poor metabolizers (PMs) of debrisoquine and one of mephenytoin. Plasma levels of AT + NT (nortriptyline) were highest in the PMs of debrisoquine, but the ratio of hydroxylated metabolites to the parent compounds appeared to be lower in these subjects. From these data, it is speculated that, in the PM of mephenytoin, the demethylation of AT is impaired. In 12 patients, free plasma 10-hydroxy-AT (ATOH) and 10-hydroxy-NT (NTOH) were found to be bound to a similar extent to plasma proteins, but not so firmly as their parent compounds, by a factor of 6 and 4 respectively. While mean total plasma ATOH reached only 15% of the value of AT, total plasma NTOH was as high as NT. ATOH correlated significantly with its parent compound, but NTOH did not correlate with NT. No drug plasma levels/clinical relationship was found in this small group of patients, even when the hydroxylated metabolites were taken into account. Both poor and extensive metabolizers of debrisoquine responded to treatment. The debrisoquine-test appears to be a useful clinical tool for detecting in patients a genetic deficiency in the hydroxylation of AT-type drugs.     

Pharmacogenetics of mephenytoin: A new drug hydroxylation polymorphism in man

Summary Inherited deficiency in mephenytoin hydroxylation was observed in a family study. It is important that the propositus was of the extensive metabolizer phenotype for the genetically controlled hydroxylation of debrisoquine. Thus, a genetic polymorphism of drug hydroxylation was suspected for mephenytoin. A population study of mephenytoin hydroxylation, combined with identification of extensive and poor debrisoquine hydroxylation phenotypes, was carried out in 221 unrelated normal volunteers. Twelve of them (5%) exhibited defective aromatic hydroxylation of mephenytoin, and 23 (10%) could be identified as poor metabolizers of debrisoquine. Amongst these 35 subjects with a drug hydroxylation deficiency, 3 (or 0.5%; 1 female, 2 males) displayed both defects simultaneously. A panel study of 10 extensive and 10 poor metabolizers of mephenytoin showed that the ability to perform aromatic hydroxylation of the demethylated mephenytoin metabolite nirvanol (5-phenyl-5-ethylhydantoin) was co-inherited with the mephenytoin hydroxylation polymorphism. Family studies suggested that poor metabolizer phenotypes of nirvanol and mephenytoin were most likely to have the homozygous genotype for an autosomal recessive allele of deficient aromatic drug hydroxylation. Intra-subject comparison of the debrisoquine and mephenytoin hydroxylation phenotypes in these subjects indicated that deficiency in the two drug hydroxylations occurred independently. Consequently, the co-inheritance of extensive and poor hydroxylation of mephenytoin and nirvanol, respectively, represents a new drug hydroxylation polymorphism in man.     

Lack of pharmacokinetic interaction between retigabine and phenobarbitone at steady-state in healthy subjects

AIMS: To evaluate potential pharmacokinetic interactions between phenobarbitone and retigabine, a new antiepileptic drug. METHODS: Fifteen healthy men received 200 mg of retigabine on day 1. On days 4-32, phenobarbitone 90 mg was administered at 22.00 h. On days 26-32, increasing doses of retigabine were given to achieve a final dose of 200 mg every 8 h on day 32. The pharmacokinetics of retigabine were determined on days 1 and 32, and those for phenobarbitone on days 25 and 31. RESULTS: After administration of a single 200 mg dose, retigabine was rapidly absorbed and eliminated with a mean terminal half-life of 6.7 h, a mean AUC of 3936 ng x ml(-1) x h and a mean apparent clearance of 0.76 l x h(-1) x kg(-1). Similar exposure to the partially active acetylated metabolite (AWD21-360) of retigabine was observed. After administration of phenobarbitone dosed to steady-state, the pharmacokinetics of retigabine at steady-state were similar (AUC of 4433 ng x ml(-1) x h and t1/2 of 8.5 h) to those of retigabine alone. The AUC of phenobarbitone was 298 mg x l(-1) x h when administered alone and 311 mg x ml(-1) x h after retigabine administration. The geometric mean ratios and 90% confidence intervals of the AUC were 1.11 (0.97, 1.28) for retigabine, 1.01 (0.88, 1.06) for AWD21-360 and 1.04 (0.96, 1.11) for phenobarbitone. Individual and combined treatments were generally well tolerated. One subject was withdrawn from the study on day 10 due to severe abdominal pain. Headache was the most commonly reported adverse event. No clinically relevant changes were observed in the electrocardiograms, vital signs or laboratory measurements. CONCLUSIONS: There was no pharmacokinetic interaction between retigabine and phenobarbitone in healthy subjects. No dosage adjustment is likely to be necessary when retigabine and phenobarbitone are coadministered to patients.     

Acetylation of maprotiline and desmethylmaprotiline in depressive patients phenotyped with sulfamidine, debrisoquine, and mephenytoin

A gas chromatographic/mass spectrometric method (using either electron impact or chemical ionisation with methane or ammonia) is described for the quantitative analysis of maprotiline (MP, Ludiomil), N-acetylmaprotiline (AcMP) and N-acetyldesmethylmaprotiline (AcDMP) in whole blood or plasma. In two groups (A and B) of 82 and 53 depressive patients treated clinically with MP for 10 and 21 days, respectively, plasma and whole blood MP was monitored during the treatment. In group A, all subjects were phenotyped with debrisoquine and mephenytoin, and 44 with sulfamidine. 5 patients were poor metabolizers of debrisoquine and 2 of mephenytoin; 18 subjects were fast acetylators of sulfamidine. Traces of AcMP were found only in two patients. AcDMP was present in levels below 2 ng/ml in the plasma of most of the patients in group A. In group B, AcDMP levels between 2.4-14.6 ng/ml of whole blood were found in 9 patients. The mass spectral data suggest the presence of another, unknown MP metabolite interfering partly with the analysis of AcDMP. The presence of AcDMP seemed not to be related to the phenotype of the patients as determined by the pharmacogenetic tests.     

Lack of relationship between glibenclamide metabolism and debrisoquine or mephenytoin hydroxylation phenotypes.

The pharmacokinetics of a single oral dose of 1.75 mg glibenclamide were studied in 15 healthy Caucasians including five poor metabolisers of debrisoquine and five poor metabolisers of S-mephenytoin. Plasma glibenclamide concentrations and the urinary concentrations of trans-4- and cis-3-hydroxyglibenclamide were analyzed by h.p.l.c. Thirty-six +/- 6% (mean +/- s.d., n = 15) of the given dose of glibenclamide was excreted in 48 h urine as hydroxylated metabolites, 27 +/- 4% as trans-4-hydroxyglibenclamide and 8 +/- 2% as cis-3-hydroxyglibenclamide. There were no differences in the plasma pharmacokinetics of glibenclamide or in the urinary excretion of the metabolites between poor and extensive metabolisers of debrisoquine, neither between the two mephenytoin hydroxylator phenotypes. The study thus indicates that the disposition of glibenclamide is not influenced by these two independent polymorphisms of drug oxidation.     

Debrisoquine and mephenytoin oxidation in Sinhalese: a population study.

The frequency distributions of the 0-8 h urinary metabolic ratios of debrisoquine and mephenytoin were measured in 111 healthy, unrelated Sinhalese resident in Sri Lanka. Blood samples were taken from 77 of these subjects for CYP2D6 genotyping. Bimodality in the distribution of the log10 debrisoquine/4-hydroxydebrisoquine ratio was not evident from visual inspection and by kernel density analysis. The results of genotyping indicated that 82% of the population were either homozygous for the wild-type CYP2D6 gene or heterozygous for the wild type allele and the whole gene deletion. Eighteen per cent of the Sinhalese population were heterozygous for the CYP2D6B mutation and the wild-type allele. All of these genotypes give rise to the extensive metaboliser phenotype in white Caucasians. No CYP2D6A mutations were identified and no individuals who were homozygous for the mutant alleles were detected, which is in accord with an absence of phenotypic poor metabolisers of debrisoquine. The mutant CYP2D6 allele frequency in Sinhalese (9%) is only half that observed in white Caucasians. The S/R-mephenytoin ratio ranged from 0.09 to 2.27 (median 0.38). By visual inspection and kernel density analysis the distribution of the S/R-mephenytoin ratio was bimodal and, using a value of 0.9 for the antimode, 16 (14%) subjects were poor metabolisers. In conclusion, the prevalence of the poor metaboliser phenotype in Sinhalese appears much lower for debrisoquine and higher for mephenytoin than in white Caucasians. These findings are similar to those observed in Indians living in Bombay and in Oriental populations.     

Brain concentrations of phenytoin,phenobarbitone and primidone in epileptic patients

Summary Plasma, brain, lumbar CSF, skeletal muscle, skin and bone concentrations of phenytoin, phenobarbitone and primidone have been measured in specimens from patients undergoing temporal lobectomy for chronic epilepsy. A good correlation was found between the plasma and brain concentrations of each drug. Similarly, a good correlation was found between the plasma and CSF concentrations of each drug. Assuming that CSF is an ultrafiltrate of plasma, the percentage of phenytoin, phenobarbitone and primidone which was unbound in plasma was 10–14%, 43% and 81% respectively. Skeletal muscle concentrations of phenytoin and phenobarbitone and the skin concentration of phenytoin, also correlated with the plasma concentrations, but the remaining tissues did not give significant correlations.     

Bioavailability of three phenytoin preparations in healthy subjects and in epileptics

Summary Serum phenytoin concentrations have been studied in epileptic patients and healthy subjects taking tablets of phenytoin calcium (Desitin), A, phenytoin acid (Desitin), B, and phenytoin acid (Nordmark), C. Retrospective data and prospective investigation of hospitalized patients on long-term phenytoin treatment showed that significantly higher serum concentrations of phenytoin were produced by the phenytoin acid preparations B and C than by the phenytoin calcium preparation A. In a cross over study six volunteers received 200 mg/day of preparations A, B, and C for three weeks. In this study, too, higher phenytoin serum concentrations were produced by B and C than by A, although the differences were not statistically significant. The reasons for the discrepancies between the studies in healthy and epileptic subjects are discussed.Dedicated to the memory of the late Friedrich v. Bodelschwingh (1902–1977)     

The activation of the biguanide antimalarial proguanil co-segregates with the mephenytoin oxidation polymorphism--a panel study.

The activation of the antimalarial drug proguanil (PG) to the active metabolite cycloguanil (CG) has been evaluated in a panel of 18 subjects. These subjects had previously been screened and classified as mephenytoin poor (PMm) or extensive metabolisers (EMm) and sparteine poor (PMs) or extensive metabolisers (EMs). Five subjects had the phenotype PMm/EMs, one was PMm/PMs, six subjects were EMm/PMs and six were EMm/EMs. The PG/CG ratio in urine (8 h) was significantly higher in PMm than in EMm (P = 0.0013). This study shows that the P450-isozyme involved in the polymorphic oxidation of mephenytoin is of critical importance in the activation of PG to CG and this may explain the large intersubject variability in CG concentrations in man. PMm make up about 3% of Caucasians, but up to about 20% of Orientals. From the present study, it may be anticipated that the antimalarial effect of PG is absent or impaired in this phenotype. The sparteine polymorphism appeared not to influence the activation of PG to CG significantly.     

Evaluation of a pharmacokinetic interaction between remacemide hydrochloride and phenobarbitone in healthy males

AIMS: To determine whether there is a pharmacokinetic interaction between the antiepileptic drugs remacemide and phenobarbitone. METHODS: In a group of 12 healthy adult male volunteers, the single dose and steady-state kinetics of remacemide were each determined twice, once in the absence and once in the presence of phenobarbitone. The effect of 7 days remacemide intake on initial steady-state plasma phenobarbitone concentrations was also investigated. RESULTS: Apparent remacemide clearance (CL/F) and elimination half-life values were unchanged after 7 days intake of the drug in the absence of phenobarbitone (1.25 +/- 0.32 vs 1.18 +/- 0.22 l kg(-1) h(-1) and 3.29 +/- 0.68 vs 3.62 +/- 0.85 h, respectively). Concomitant administration of remacemide with phenobarbitone resulted in an increase in the estimated CL/F of remacemide (1.25 +/- 0.32 vs 2.09 +/-0.53 l kg-1 h-1), and a decreased remacemide half-life (3.29 +/- 0.68 vs 2.69 +/- 0.33 h). The elimination of the desglycinyl metabolite of remacemide also appeared to be increased after the phenobarbitone intake (half-life 14.72 +/- 2.82 vs 9.61 +/- 5.51 h, AUC 1532 +/- 258 vs 533 +/- 281 ng ml(-1) h). Mean plasma phenobarbitone concentrations rose after 7 days of continuing remacemide intake (12.67 +/- 1.31 vs 13.86 +/- 1.81 microgram ml(-1)). CONCLUSIONS: Phenobarbitone induced the metabolism of remacemide and that of its desglycinyl metabolite. Remacemide did not induce its own metabolism, but had a modest inhibitory effect on the clearance of phenobarbitone.     

Serum protein binding and free concentration of phenytoin and phenobarbitone in pregnancy.

1 The effect of pregnancy on the binding of phenytoin and phenobarbitone to serum proteins was studied in normal women and in drug treated epileptic women. 2 The binding of both drugs was reduced during pregnancy. The reduction correlated positively with the gestational age and negatively with the serum albumin concentration. 3 In spite of the increase in unbound fraction, both the total and free serum concentrations of phenytoin were decreased in late pregnancy.     

The elimination of diazepam in Chinese subjects is dependent on the mephenytoin oxidation phenotype

1 The disposition of diazepam and desmethyldiazepam was studied in 21 healthy male Chinese subjects who were phenotyped with mephenytoin. Four poor metabolizers (PM) were identified by phenotyping with mephenytoin and by genotyping for CYP2C19 .
2 Serum diazepam and desmethyldiazepam concentrations were measured by high performance liquid chromatography in samples drawn up to 24 days after administration.
3 The plasma elimination half-lives of diazepam (100.8±32.3  h) and desmethyldiazepam (219.9±62.7  h) in PMs were significantly longer than those (34.7±23.0  h for diazepam, 103.1±25.9  h for desmethyldiazepam) of the 17 phenotyped extensive metabolizers (EM), and those (30.8±24.9  h for diazepam, 103.1±27.5  h for desmethyldiazepam) of the five genotyped EMs.
4 The mephenytoin S/R ratios were significantly correlated with the plasma half-lives of diazepam ( r =0.543, P <0.05) and desmethyldiazepam ( r =0.522, P <0.05), and with the clearance ( r =−0.524, P <0.05) of diazepam in 21 subjects.
5 These results are compatible with the conclusion that both diazepam and desmethyldiazepam are metabolized by cytochrome P450 CYP2C19 in the Chinese population.
6 The mephenytoin S/R ratios in nine EMs who drank alcohol frequently were significantly higher than those of seven EMs who were non-drinkers, but the plasma kinetics of diazepam and desmethyldiazepam were not significantly different between the two groups. The explanation for these finding is not clear.     

Extent of urinary excretion of p-hydroxyphenytoin in healthy subjects given phenytoin

Urinary excretion of p-hydroxyphenytoin and its glucuronide conjugate was measured in eight healthy young adults in a comparative bioavailability study of oral sodium phenytoin (approximately 5 mg/kg/dose). Among these subjects the percentage of the phenytoin dose converted to p-hydroxyphenytoin and appearing in urine was relatively similar (mean 79%, range 67-88%). The great majority of the p-hydroxyphenytoin appeared in urine as conjugates; only 1.4-3.4% of the excreted p-hydroxyphenytoin was in the form of unconjugated metabolite. The proportion of a single phenytoin dose excreted in urine as p-hydroxyphenytoin or its conjugate increased from the first dose (mean +/- SD) 74.9 +/- 4.6% to the second dose, given 2 weeks later 79.3 +/- 4.6% (p less than 0.05). This finding suggests that autoinduction of phenytoin metabolism may occur after relatively brief exposure to the drug.     

Concomitant use of mirtazapine and phenytoin: a drug-drug interaction study in healthy male subjects

OBJECTIVE: The objectives of this study were to assess the effect of mirtazapine on steady-state pharmacokinetics of phenytoin and vice versa and to assess tolerability and safety of the combined use of mirtazapine and phenytoin. METHODS: This was an open-label, randomised, parallel-groups, single-centre, multiple-dose pharmacokinetic study. Seventeen healthy, male subjects completed either treatment A [nine subjects: daily 200 mg phenytoin for 17 days plus mirtazapine (15 mg for 2 days continuing with 30 mg for 5 days) from day 11 to day 17] or treatment B [eight subjects: mirtazapine, daily 15 mg for 2 days continuing with 30 mg for 15 days plus phenytoin 200 mg from day 8 to day 17]. Serial blood samples were taken for kinetic profiling on the 10th and 17th days of treatment A and on the 7th and 17th days of treatment B. Induction of CYP 3A by phenytoin was evaluated by measuring the ratio of 6 beta-hydroxycortisol over cortisol on the 1st, 7th and 17th days of treatment B. RESULTS: Co-administration of mirtazapine had no effect on the steady-state pharmacokinetics of phenytoin, i.e. the area under the plasma concentration-time curve (AUC)(0-24) and peak plasma concentration (C(max)) remained unchanged. The addition of phenytoin to an existing daily administration of mirtazapine resulted in a mean (+/-SD) decrease of the AUC(0-24) from 576+/-104 ng h/ml to 305+/-81.6 ng h/ml and a mean decrease of C(max) from 69.7+/-17.5 ng/ml to 46.9+/-10.9 ng/ml. Induction of CYP 3A by phenytoin is confirmed by the significantly ( P=0.001) increased 6beta-hydroxycortisol/cortisol ratio from 1.74+/-1.00 to 2.74+/-1.64. CONCLUSION: Co-administration of mirtazapine did not alter the steady-state pharmacokinetics of phenytoin. The addition of phenytoin to an existing daily administration of mirtazapine results in a decrease of the plasma concentrations of mirtazapine by 46% on average, most likely due to induction of CYP 3A3/4.     

Absence of CYP3A genetic polymorphism assessed by urinary excretion of 6 beta-hydroxycortisol in 102 healthy subjects on rifampicin.

A previous study has demonstrated that the urinary level of 6 beta-hydroxycortisol is a marker of liver CYP3A content after induction by rifampicin. To put in evidence an eventual genetic polymorphism for this cytochrome, the frequency distribution of 6 beta-hydroxycortisol excretion was investigated in 102 healthy Caucasians before and after 6 days of oral rifampicin administration (600 mg daily). After rifampicin treatment, a wide interindividual distribution was observed but no clear bimodality. Moreover the mean 6 beta-hydroxycortisol level was higher in women (n = 38) than in men (n = 64). These observations do not favour the existence of a CYP3A genetic polymorphism based on 6 beta-hydroxycortisol excretion but evoke a sexual dimorphism. However, CYP3A is composed of at least four enzymes and as the enzyme(s) responsible for cortisol 6 beta-hydroxylation is (are) not perfectly known, it can not be excluded that a genetic polymorphism does exist for one enzyme of this family.     

Effect of the CYP2C19 oxidation polymorphism on fluoxetine metabolism in Chinese healthy subjects

AIMS: The study was designed to investigate whether genetically determined CYP2C19 activity affects the metabolism of fluoxetine in healthy subjects. METHODS: A single oral dose of fluoxetine (40 mg) was administrated successively to 14 healthy young men with high (extensive metabolizers, n=8) and low (poor metabolizers, n = 6) CYP2C19 activity. Blood samples were collected for 5-7 half-lives and fluoxetine, and norfluoxetine were determined by reversed-phase high performance liquid chromatography. RESULTS: Poor metabolizers (PMs) showed a mean 46% increase in fluoxetine peak plasma concentrations (Cmax, P < 0.001), 128% increase in area under the concentration vs time curve (AUC(0, infinity), P < 0.001), 113% increase in terminal elimination half-life (t(1/2)) (P < 0.001), and 55% decrease in CLo (P < 0.001) compared with extensive metabolizers (EMs). Mean +/- (s.d) norfluoxetine AUC(0, 192 h) was significantly lower in PMs than that in EMs (1343 +/- 277 vs 2935 +/- 311, P < 0.001). Mean fluoxetine Cmax and AUC(0, infinity) in wild-type homozygotes (CYP2C19*1/CYP2C19*1) were significantly lower than that in PMs (22.4 +/- 3.9 vs 36.7 +/- 8.9, P < 0.001; 732 +/- 42 vs 2152 +/- 492, P < 0.001, respectively). Mean oral clearance in individuals with the wild type homozygous genotype was significantly higher than that in heterozygotes and that in PMs (54.7 +/- 3.4 vs 36.0 +/- 8.7, P < 0.01; 54.7 +/- 3.4 vs 20.6 +/- 6.2, P < 0.001, respectively). Mean norfluoxetine AUC(0, 192 h) in PMs was significantly lower than that in wild type homozygotes (1343 +/- 277 vs 3163 +/- 121, P < 0.05) and that in heterozygotes (1343 +/- 277 vs 2706 +/- 273, P < 0.001), respectively. CONCLUSIONS: The results indicated that CYP2C19 appears to play a major role in the metabolism of fluoxetine, and in particular its N-demethylation among Chinese healthy subjects.     

Relationship between phenytoin and tolbutamide hydroxylations in human liver microsomes.

1. The metabolic interaction of phenytoin and tolbutamide in human liver microsomes was investigated. 2. Phenytoin 4-hydroxylation (mean Km 29.6 microM, n = 3) was competitively inhibited by tolbutamide (mean Ki 106.2 microM, n = 3) and tolbutamide methylhydroxylation (mean Km 85.6 microM, n = 3) was competitively inhibited by phenytoin (mean Ki 22.6 microM, n = 3). 3. A significant correlation was obtained between phenytoin and tolbutamide hydroxylations in microsomes from 18 human livers (rs = 0.82, P less than 0.001). 4. Sulphaphenazole was a potent inhibitor of both phenytoin and tolbutamide hydroxylations with IC50 values of 0.4 microM and 0.6 microM, respectively. 5. Mephenytoin was a poor inhibitor of both phenytoin and tolbutamide hydroxylations with IC50 values greater than 400 microM for both reactions. 6. Anti-rabbit P450IIC3 IgG inhibited both phenytoin and tolbutamide hydroxylations in human liver microsomes by 62 and 68%, respectively. 7. These in vitro studies are consistent with phenytoin 4-hydroxylation and tolbutamide methylhydroxylation being catalysed by the same cytochrome P450 isozyme(s) in human liver microsomes.     

Interaction between tolbutamide and ketoconazole in healthy subjects.

A possible interaction between tolbutamide and ketoconazole was studied in seven healthy volunteers. Treatment for 1 week with 200 mg oral ketoconazole increased the elimination half-life (from mean +/- s.d. 3.7 +/- 0.4 to 12.3 +/- 1.9 h) and AUC(0.12 h) of tolbutamide (from 309 +/- 27 to 546 +/- 20 micrograms ml-1 h) by 25 +/- 64 and 66 +/- 15%, respectively. The percentage blood glucose reduction was also increased when tolbutamide and ketoconazole were coadministered.     

Effects of phenobarbitone and phenytoin on folate catabolism in the rat

The effects of phenobarbitone and phenytoin on the catabolism of oral [2-14C] and [3',5',7,9-3H] folic acid were investigated. Normal rats were found to excrete an excess of 3H-labelled compounds into the urine and 14C-labelled compounds into the faeces. Phenytoin abolished this urinary 3H imbalance and also delayed and prolonged the overall excretion of radioactive material. Phenobarbitone appeared to increase the amounts of urinary scission products in the first 24 hr but over the 0-72 hr period both anticonvulsants decreased folate polyglutamate catabolism. As the anticonvulsants used in these experiments decreased folate catabolism in the rat it is unlikely that the megaloblastic anaemia caused by chronic anticonvulsant therapy is due to induction of the enzymes responsible for folate breakdown in vivo.