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.

Amodiaquine, its desethylated metabolite, or both, inhibit the metabolism of debrisoquine (CYP2D6) and losartan (CYP2C9) in vivo.

OBJECTIVE: To study the extent of in vivo inhibition by the antimalarial drug amodiaquine, its active metabolite N-desethylamodiaquine, or both, of the metabolism of four probe drugs of the enzymes CYP2D6, CYP2C19, CYP2C9 and CYP1A2. METHODS: Twelve healthy Swedish volunteers received a cocktail of four probe drugs (debrisoquine, omeprazole, losartan and caffeine) to determine their baseline metabolic capacities. After a washout period, they received a 600 mg oral dose of amodiaquine hydrochloride; and 2-3 h later the cocktail was administered again. One week after the intake of amodiaquine, the subjects received the cocktail a third time. The levels of probe drugs and their metabolites as well as amodiaquine and its metabolite were determined by HPLC. RESULTS: Plasma levels of amodiaquine and N-desethylamodiaquine could be followed in all subjects for 6 h and 28 days, respectively. Among the 12 subjects, a 3-fold variation in amodiaquine AUC and a 2-fold variation in N-desethylamodiaquine AUC, were observed. The CYP2D6 and CYP2C9 activities of the subjects were measured by debrisoquine and losartan phenotyping tests, respectively. There were significant mean increases in debrisoquine metabolic ratio (MR) between baseline and the second cocktail [MR(2 h)-MR(baseline) 1.426 (95% confidence interval 1.159, 1.755), P=0.002; ANOVA, Fisher LSD test] and in mean losartan MR between baseline and the second cocktail [MR(2 h)-MR(baseline) 1.724 (95% confidence interval 1.076, 2.762), P=0.026; ANOVA, Fisher LSD test]. The effects on CYP2D6 and CYP2C9 activities subsided within a week after intake of amodiaquine as tested by the phenotyping cocktail. The changes in omeprazole MRs and caffeine MRs were not statistically significant between any of the study phases. CONCLUSION: A single dose of amodiaquine decreased CYP2D6 and CYP2C9 activities significantly compared to baseline values. Amodiaquine has the potential to cause drug-drug interactions and should be further investigated in malarial patients treated with drug combinations containing amodiaquine.

Chloroquine modulation of specific metabolizing enzymes activities: investigation with selective five drug cocktail.

AIMS: The aim of this study was to investigate whether chloroquine can inhibit drug metabolism in humans, if such inhibition is general or selective for certain enzymes and evaluate the potential for and clinical significance of any drug-drug interactions when chloroquine is co-administered with other drugs. METHODS: The study was conducted in fourteen normal non-smoking healthy male volunteers using a cocktail of five drugs consisting of caffeine, mephenytoin, debrisoquine, chlorzoxazone and dapsone to assess activities of cytochromes P450 (CYP) 1A2, 2C19, 2D6, 2E1 and 3A4 respectively. Dapsone was also used to assess N-acetyltransferase activity. The activities were assessed at baseline, after one and seven daily doses (250 mg daily) of chloroquine and 7 and 14 days after stopping chloroquine dosing. RESULTS: Chloroquine caused a progressive and significant decrease in CYP2D6 activity as measured by debrisoquine metabolism from first to seventh dose and the activity returned to baseline gradually over 14 days after stopping administration. There was no effect on the metabolism of any of the other probe drugs. CONCLUSIONS: Chloroquine has been shown to be capable of inhibiting the activity of CYP2D6 in vivo in humans. This effect is selective as activities of other enzymes investigated were not affected. The effect was modest but suggests a potential for drug-drug interactions when co-administered with other drugs that are substrates for this enzyme. The clinical significance of such an interaction will depend on the therapeutic index of any drug involved.

Halofantrine and chloroquine inhibit CYP2D6 activity in healthy Zambians.

AIMS: To determine the effect of therapeutic loading doses of halofantrine and chloroquine on CYP2D6 activity in healthy black Zambians. METHODS: Twenty healthy black male Zambians were phenotyped for CYP2D6 activity by measuring the debrisoquine/4-hydroxydebrisoquine ratio in a 0-8 h urine sample after a 10 mg oral dose of debrisoquine hemi-sulphate. The subjects (all 'extensive metabolizer' phenotype with respect to CYP2D6) were randomized into two groups of 10, and 24 h later one group received 1500 mg halofantrine hydrochloride and the other group 1500 mg chloroquine phosphate both orally in divided doses. All subjects were given further 10 mg doses of debrisoquine at 2 h, 1 week and 2 weeks after the last dose of the antimalarial drug, and phenotyped as described above. RESULTS: The median debrisoquine/4-hydroxydebrisoquine 0-8 h urinary ratio was increased by halofantrine (1.39 to 6.05; P<0.01; 95% confidence intervals 4.00-11.7) and chloroquine (1.96 to 3.91; P<0.01; 95% confidence intervals 1.34-2.66) when debrisoquine was given 2 h after treatment. The decrease in CYP2D6 activity remained statistically significant for 1 week after both drugs. Halofantrine was a significantly more potent inhibitor of CYP2D6 than chloroquine (P=0.037). Phenocopying occurred in two subjects taking halofantrine and one taking chloroquine (i.e. the debrisoquine/4-hydroxydebrisoquine ratios became consistent with the poor metabolizer phenotype). CONCLUSIONS: Given in therapeutic loading doses, both halofantrine and chloroquine caused significant inhibition of CYP2D6 activity in healthy black Zambians. With respect to halofantrine, this finding reinforces the recommendation that its combination with other drugs known to prolong the QT interval should be avoided, especially those that are metabolized significantly by CYP2D6.

[Comparison of serum concentrations of caffeine, 4-methylaminoantipyrine, sulfamethazine and debrisoquin following oral administration of these substances as a cocktail in type II diabetics before and after insulin therapy]. / Vergleich der Serumkonzentration von Coffein, 4-Monomethylaminoantipyrin, Sulfamethazin and Debrisoquin nach oraler Verabreichung dieser Substanzen als Cocktail bei Typ-II-Diabetikern vor und nach Umstelung auf Insulin.

A cocktail of 4 substances (caffeine/CYP1A/CYP1A2, metamizol/CYP2B, debrisoquin/CYP2D6 and sulfamethazine/N-acetyltransferase) was administered to 15 maturity-onset diabetics before and 6 months after insulin therapy (IT) to examine changes in hepatic biotransformation capacity in humans under pathological conditions. Blood and urine samples were taken 6 h after oral administration of the drugs. There were no differences in acetylation- and hydroxylationsphenotyping before or during IT. However, a significant increase in concentration of free sulfamethazine during IT can be interpreted as induction of N-acetyltransferase by poor metabolic control. Comparison of caffeine-concentration showed no significant differences. Obviously in humans CYP1A2 is not influenced by type-II-diabetes mellitus. Concentration of 4-methyl-antityprine (4-MAA), a metabolite of metamizol, was significantly increased during IT. This results shows a possible induction of CYP2B by poor metabolic control.

Differential inhibition of neuronal and extraneuronal monoamine oxidase.

This study examined whether the neuronal and extraneuronal sites of action of two monoamine oxidase (MAO) inhibitors, l-deprenyl and debrisoquin, could be distinguished by their effects on plasma concentrations of catecholamine metabolites. Plasma concentrations of the intraneuronal deaminated metabolite of norepinephrine, dihydroxyphenylglycol (DHPG), were decreased by 77% after debrisoquin and by 64% after l-deprenyl administration. Plasma concentrations of the extraneuronal O-methylated metabolite of norepinephrine, normetanephrine, were increased substantially more during treatment with l-deprenyl than with debrisoquin (255% compared to a 27% increase). The comparable decreases in plasma concentrations of DHPG indicate a similar inhibition of intraneuronal MAO by both drugs. Much larger increases in normetanephrine after l-deprenyl than after debrisoquin are consistent with a site of action of the latter drug directed at the neuronal rather than the extraneuronal compartment. Thus, differential changes in deaminated and O-methylated amine metabolites allows identification of neuronal and extraneuronal sites of action of MAO inhibitors.

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 levomepromazine and metabolites on debrisoquine hydroxylation in the rat.

The influence of the major metabolites of the phenothiazine derivative, levomepromazine (methotrimeprazine), on hydroxylation of debrisoquine was examined in male Sprague-Dawley rats. The metabolic ratio of debrisoquine/4-hydroxy debrisoquine was first determined in rats after oral administration of 10 mg/kg of debrisoquine. Then the same dose of debrisoquine was co-administered with various doses of levomepromazine or one of its metabolites. Levomepromazine and its sulphoxidated, N-demethylated and O-demethylated metabolites caused highly significant and dose-dependent increases in the debrisoquine metabolic ratio. 3-Hydroxy levomepromazine had no significant effect on the metabolism of debrisoquine. This indicates that the non-hydroxylated metabolites of levomepromazine have relatively high affinities for the cytochrome P450 enzyme which converts debrisoquine to 4-hydroxy debrisoquine in the rat. Such metabolites may therefore be responsible for a considerable part of the inhibitory effect of debrisoquine hydroxylation previously reported in patients treated with phenothiazine neuroleptics.

S-mephenytoin, sparteine and debrisoquine oxidation: genetic polymorphisms in a Turkish population.

A mephenytoin test was carried out in 106 unrelated healthy Turkish volunteers. Racemic mephenytoin was coadministered with either debrisoquine or sparteine. The S/R mephenytoin ratio ranged from < 0.1 to 0.73 in 105 subjects, accordingly phenotyped as extensive metabolisers. One subject had an S/R mephenytoin ratio of 1.02, showing that he was a poor metaboliser of mephenytoin (0.94%, confidence interval 0.25% and 13.65%). In 48 subjects, the metabolic ratios of debrisoquine and sparteine were correlated significantly (rs = 0.61, P < 0.001).

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.

[Assessment of biotransformation capacity following oral administration of various model substances as cocktail]. / Einschätzung der Biotransformationskapazität nach oraler Gabe unterschiedlicher Modellsubstanzen als "Cocktail".

A cocktail of four model substances orally administered to humans is used for simultaneous characterization of phenobarbital and 3-methylcholanthrene inducible forms of cytochrome-P450 and two genetic polymorphisms, the debrisoquine hydroxylation and N-acetylation. The investigations offer the possibility to assess four main processes of hepatic drug metabolism as well as the judgement of alterations in drug elimination. Both acetylation and hydroxylation phenotypes are not influenced after administration of the cocktail compared to the administration of the substances alone. A statistically significant 30.4% increase of mean body residence time could be found only for monomethylaminoantipyrine. The other pharmacokinetic parameters of monomethylaminoantipyrine and caffeine were unchanged. A one-point-determination for the 9 hour serum concentrations of monomethylaminoantipyrine, caffeine and sulfamethazine/acetylsulfamethazine as well as the 0-9 hours urine concentrations of debrisoquin/4-hydroxydebrisoquin will be conceivable by using "normal ranges".

A protocol for the safe administration of debrisoquine in biochemical epidemiologic research protocols for hospitalized patients.

The genetically determined ability to metabolize the antihypertensive drug debrisoquine has been proposed as a genetic risk factor for primary carcinomas of the lung. To test this hypothesis, the metabolism of the drug was evaluated in a case control study. The subjects were characterized by their ability to metabolize debrisoquine after receiving a test dose of the drug followed by the collection of an 8-hour urine sample. They were classified by laboratory analysis into one of the following three groups: extensive, intermediate, and poor metabolizers. Poor metabolizers comprise 10% of the population and are unable to hydroxylate the drug. This group was expected to be at highest risk for deleterious effects from this medication. A protocol was created that included patient education and blood pressure monitoring to administer this medication safely to a group of patients with cancer who were already compromised. Although poor metabolizers showed a small decrease in systolic and diastolic blood pressure, no significant hypotensive episodes or clinical sequelae were observed in any of the groups. These data suggest that debrisoquine can be administered safely in a controlled clinical setting and will be useful for the characterization of lung cancer patients in biochemical epidemiology studies.

The effect of urine pH on debrisoquine phenotyping: application of an HPLC-method.

The effect of urine pH on debrisoquine metabolic ratio (MR) was studied in 6 healthy volunteers. They were phenotyped on two separate occasions, firstly when urine was made alkaline with orally given sodium bicarbonate, and secondly when urine was acidified with oral ammonium chloride. The concentrations of debrisoquine and 4-hydroxydebrisoquine were analyzed by an HPLC (high performance liquid chromatographic) method, which was compared with a standard GC (gas chromatographic) method. The calculated MRs proved to be similar during alkalinization and during acidification, although there was a tendency to lower excretion of debrisoquine and its 4-hydroxymetabolite into acidic urine. The HPLC analysis correlated well with the GC analysis of debrisoquine and 4-hydroxy-debrisoquine concentrations in urine. The debrisoquine MRs obtained with HPLC and GC also correlated favorably (r = 0.90, p less than 0.001).

Multiple pathways of propranolol's metabolism are inhibited by debrisoquin.

We investigated the effect of debrisoquin on propranolol metabolism in six normal subjects who were extensive metabolizers of debrisoquin. Each subject was studied on two occasions. On the first occasion, each subject received oral propranolol (80 mg) alone; on the second occasion, 7 days later, each subject received a dose of propranolol (80 mg) 30 minutes after the administration of oral debrisoquin (40 mg). Oral propranolol clearance was reduced 33% +/- 16% (p less than 0.05) by the administration of debrisoquin. As predicted, the 4-hydroxypropranolol partial metabolic clearance was significantly (p less than 0.05) inhibited by debrisoquin. However, the side-chain oxidation pathway, as measured by naphthoxylactic acid, was also significantly (p less than 0.05) inhibited by debrisoquin. Debrisoquin administration did not change the renal clearance of any of the metabolites. These data support the usefulness of the in vivo inhibition model in the prediction of cosegregation of routes of metabolism. However, for propranolol, pathways of its metabolism that are not thought to cosegregate with debrisoquin was also inhibited.

Plasma debrisoquin levels in the assessment of reduction of plasma homovanillic acid. The debrisoquin method.

Plasma concentrations of unconjugated homovanillic acid (pHVA) reflect both central nervous system (CNS) and peripheral dopamine metabolism. Debrisoquin sulfate (DBQ) blocks peripheral, but not CNS, production of HVA from dopamine. Administration of DBQ has been used to decrease the proportion of peripherally produced HVA in pHVA measurements, making such measurements more reflective of CNS turnover of dopamine. We studied the relationships between DBQ dose, plasma DBQ (pDBQ) levels, and changes in pHVA in a group of 21 subjects (9 normal controls and 12 with Tourette's syndrome). DBQ dose was moderately correlated with pDBQ levels (r = 0.63, p = 0.002). Subjects (n = 8) with mean pDBQ levels above 60 ng/ml had a 48% to 66% decrease in mean pHVA levels; this may reflect nearly complete inhibition of peripheral HVA production. Subjects (n = 13) with mean pDBQ levels below 55 ng/ml had decreases in pHVA levels from 10% to 58%. No debrisoquin was detected in cerebrospinal fluid samples. These data suggest that pDBQ levels above 60 ng/ml are sufficient to assure substantial inhibition of peripheral HVA production and that monitoring pDBQ levels may be useful when employing this method for studying CNS metabolism.

S-mephenytoin hydroxylation phenotypes in a Swedish population determined after coadministration with debrisoquin.

Mephenytoin (100 mg) and debrisoquin (10 mg) were administered orally, both separately and together, to 41 healthy subjects. The ratios between the S and R enantiomers of mephenytoin and between debrisoquin and 4-OH-debrisoquin in urine were determined by use of GC. These ratios were used as measures of drug hydroxylation. There was no change in the phenotypic trait values of the two drugs when they were coadministered. Mephenytoin and debrisoquin then were coadministered to 253 healthy Swedish subjects, before bedtime, and urine samples were collected at periods of 0 to 8, 8 to 24, and 24 to 32 hours after drug administration. In the first sample, seven of the 253 subjects (2.8%, 95% confidence interval 0.8% to 4.8%) had an S/R ratio of greater than 0.8; this indicated that they were poor hydroxylators of S-mephenytoin. In the two consecutive samples, the S/R ratios of mephenytoin did not change in these seven persons, whereas it decreased to less than 0.2 in the third sample in the extensive hydroxylators. As was reported before, there was no relationship between the mephenytoin S/R ratio and the debrisoquin metabolic ratio (rs = 0.01). Coadministration of debrisoquin and mephenytoin before bedtime and urine collection during two consecutive nights allow for an accurate determination of both phenotypes in the population.