Effect of honey on CYP3A4, CYP2D6 and CYP2C19 enzyme activity in healthy human volunteers.

Honey is a common food supplement but not many studies have studied honey and drug interaction. This study investigates the influence of 7 days of honey administration on the activity of CYP3A4, CYP2D6 and CYP2C19 drug-metabolizing enzymes in healthy volunteers by using appropriate biomarker and probe drugs. A within-group pharmacokinetic study was done in 12 healthy volunteers. Urine samples (0-8 hr) were collected after administration of 30 mg of oral dextromethorphan (probe drug for CYP2D6) for analysis of dextromethorphan and dextrorphan. A plasma sample (4 hr) was collected after administration of 200 mg of oral proguanil (probe drug for CYP2C19) for the analysis of proguanil and cycloguanil. Urine samples (0-24 hr) were collected for the analysis of 6beta-hydroxycortisol (biomarker for CYP3A4). The volunteers were administered honey for 7 days. Subsequently blood and urine samples were collected after drug dosing as before. These samples were analysed for drug and metabolite concentrations in urine and plasma using high performance liquid chromatography method. Seven days of honey administration resulted in statistically significant increase in 24-hr urinary excretion of 6beta-hydroxycortisol. However, the metabolic ratios of dextromethorphan and proguanil were not significantly altered after 7 days of honey administration. Honey obtained from Western Ghats of southern India may induce CYP3A4 enzyme activity but not CYP2D6 and CYP2C19 enzyme activities.

Consumption of charcoal-broiled meat as an experimental tool for discerning CYP1A2-mediated drug metabolism in vivo.

Cytochrome P450 1A2 (CYP1A2) is a major drug-metabolising enzyme. Polycyclic aromatic hydrocarbons, present in high concentrations in tobacco smoke and charcoal-broiled meat, are known to induce CYP1A2. The purpose of the present study was to validate enzyme induction by consumption of charcoal-broiled meat as an experimental tool for discerning CYP1A2-mediated drug metabolism in vivo. Twenty-four healthy, non-smoking men, all extensive metabolisers of sparteine (CYP2D6), participated in the study. All participants were genotyped for a putative CYP1A2-inducibility genotype. In the study diet period charcoal-broiled meat was served for lunch and dinner for five consecutive days. All participants were tested with probe reactions for CYP1A2 (caffeine) and CYP2C19 (proguanil) before and after consuming the study diet. Further, in three subgroups, they were tested with either the CYP1A2-substrate tacrine or probe reactions for CYP3A4 (quinidine) or CYP2C9 (tolbutamide). Neither probe reactions for CYP1A2, CYP2C9, CYP2C19 or CYP3A4 were affected by consumption of charcoal-broiled meat as practised in this study. No modifying role of the CYP1A2-inducibility genotype was evident. A number of experimental limitations are discussed, among them the lack of standardisation of exposure, the timing of phenotyping, and the choice of probe reactions. In conclusion, consumption of charcoal-broiled meat as practised in the present study appears not to be a useful experimental tool for discerning CYP1A2-mediated metabolism in vivo.

Concordance between proguanil phenotype and CYP2C19 genotype in Chinese.

OBJECTIVE: To investigate whether urinary proguanil (chlorguanide) metabolite ratios incorporating its minor metabolite, 4-chlorophenylbiguanide, define individuals as extensive metabolisers (EMs) or poor metabolisers (PMs) of CYP2C19 more reliably than the standard phenotyping ratio [proguanil/cycloguanil (PG/CG)]. METHODS: Thirty-eight ethnic Chinese subjects ingested 100 mg proguanil, collected urine for 8 h and were genotyped for CYP2C19*1, *2 and *3 alleles. Proguanil metabolite ratios (PG/CG; proguanil/4-chlorophenylbiguanide (PG/CPB); proguanil/(cycloguanil+4-chlorophenylbiguanide) [PG/(CG+CPB)] were determined from the urinary recoveries of proguanil, cycloguanil and 4-chlorophenylbiguanide. Proguanil phenotypes were determined from the ratios using frequency distribution histograms, probit and normal test variable plots. RESULTS: Data from 35 subjects were suitable for analysis. Of subjects, 5 were CYP2C19*2/*2, 1 was *2/*3, 21 were *1/*2 and 8 were *1/*1. A rank order of proguanil metabolic ratios was observed, with *1/*1 subjects having the lowest, *1/*2 intermediate and *2/*2, *2/*3 having the highest ratios (P<0.0001). All subjects with PM genotypes were classified as PMs of proguanil by probit analysis of PG/CPB and PG/(CG+CPB) ratios, but not PG/CG. CONCLUSION: A gene-dose effect of CYP2C19 genotype on the conversion of proguanil to cycloguanil and 4-chlorophenylbiguanide has been demonstrated in ethnic Chinese subjects. Complete concordance between PM CYP2C19 genotype and PM phenotype was only achieved with probit analysis of proguanil metabolite ratios that incorporated 4-chlorophenylbiguanide.

Pregnancy and use of oral contraceptives reduces the biotransformation of proguanil to cycloguanil.

OBJECTIVE: To determine the effects of late pregnancy and also oestrogen supplementation on the CYP2C19-mediated biotransformation of proguanil (PG) to its active antifol triazine metabolite cycloguanil (CG). METHODS: Case control study conducted on the NW border of Thailand; a single dose of PG (4 mg/kg) was administered to Karen women in late pregnancy and a single blood and urine sample taken 6 h later. Women were studied in late pregnancy (>36 weeks) and restudied 2 months after delivery. A separate cohort of Karen women newly attending a birth-control clinic were studied before and 3 weeks into their first course of oral contraceptives (OCP: levonorgestrel 0.15 mg and ethinyloestradiol 0.03 mg). Forty-five pregnant women and forty-two healthy OCP users were studied. RESULTS: The results were similar in both groups; pregnancy and OCP use were both associated with reduced formation of cycloguanil (CG). Impaired PG biotransformation was seen in women with the "extensive metaboliser" phenotype (urine PG/CG ratio <10). CG levels, adjusted for dose, were a median (range) 73% (-59 to 420%) higher following the pregnancy than during the pregnancy in women characterised as extensive metabolisers ( P<0.001). CG levels in women characterised as extensive metabolisers were 34% (-54 to 323%) higher before than while taking the OCP ( P<0.01). CONCLUSION: Late pregnancy and OCP use impair biotransformation of the active antimalarial metabolite CG from the parent PG. This may be mediated by oestrogen inhibition of CYP2C19 activity. The dose of PG should be increased by 50% in these groups.

Analysis of proguanil and its metabolites by application of the sweeping technique in micellar electrokinetic chromatography.

The method of applying large sample volumes in micellar electrokinetic chromatography termed sweeping is applied to determine the conservative limits of detection of some basic drugs in plasma and urine. The biguanides proguanil, 4-chlorophenylbiguanide and cycloguanil are used as models of basic drugs and the limits of detection obtained compared with those previously reported for capillary zone electrophoresis using field-amplified sample injection (FASI) and also by LC using off-line preconcentration. It is found that the sweeping method can be applied to extracts of such biological matrices. The limits of detection obtained by sweeping are improved over FASI for plasma but not for urine and the limits of detection are higher than those reported for LC, for these compounds.

Improved validated assay for the determination of proguanil and its metabolites in plasma, whole blood, and urine using solid-phase extraction and high-performance liquid chromatography.

An improved and validated method is presented for the determination of proguanil, cycloguanil, and 4-chlorophenylbiguanide in plasma, whole blood, and urine using solid-phase extraction (SPE) technique and reversed-phase high-performance liquid chromatography (HPLC). The HPLC method uses isocratic elution with acetonitrile:phosphate buffer 0.1 mol/l, pH 2.6 (21.5:78.5 vol/vol) at a flow rate of 1.0 ml/min for the separation. The recovery of proguanil and metabolites ranged from 82% to 104%. The limit of determination was 20 nmol/l for proguanil and its metabolites in plasma and approximately 50 nmol/l for proguanil and metabolites in whole blood. Different stationary phases for HPLC and SPE were tested and the best chromatographic separation from endogenous constituents and other antimalarial drugs was achieved with cyanopropyl stationary phases.

Hepatic cytochrome P450 CYP2C activity in psoriasis: studies using proguanil as a probe compound.

Retinol and proguanil are metabolised by the same family of hepatic cytochrome P450, i.e. CYP2C. We used proguanil as a probe to study CYP2C activity, and by implication retinol metabolism, in psoriasis. In vitro studies showed that retinol competitively inhibited the hepatic metabolism of proguanil to cycloguanil. Proguanil metabolism was assessed in 82 patients with chronic plaque psoriasis. Following proguanil orally (200 mg), urine was analysed for proguanil and cycloguanil. A proguanil to cycloguanil ratio < 1 signified extensive metabolism and a ratio > 10 poor metabolism. A wider range of ratios was observed in psoriasis than previously reported for normal subjects. The proguanil to cycloguanil ratio was assessed in 10 cases each of know severe and mild psoriasis. Low CYP2C activity was associated with severe psoriasis, poor metaboliser status occurring in 50% of the severe group, but in none of the mild cases, p < 0.01. These findings may indicate differences in retinoid metabolism in psoriasis.

Fluvoxamine inhibits the CYP2C19-catalyzed bioactivation of chloroguanide.

OBJECTIVE: To investigate the interaction between fluvoxamine and chloroguanide (INN, proguanil) to confirm that fluvoxamine inhibits CYP2C19. METHODS: The study was carried out with a randomized, in vivo, crossover design. Six volunteers were extensive metabolizers of the S-mephenytoin oxidation polymorphism, and six volunteers were poor metabolizers. In period A of the study, each subject took 200 mg chloroguanide orally. In period B, each subject took 100 mg/day fluvoxamine for 8 days and on day 6 ingested 200 mg chloroguanide. In both periods, blood and urine were sampled at regular intervals. Chloroguanide and its two metabolites cycloguanil and 4-chlorphenylbiguanide in plasma and in urine were assayed by means of HPLC. RESULTS: During fluvoxamine use, the median of the total clearance of chloroguanide decreased in a statistically significant way from 1282 ml/min to 782 ml/min among the extensive metabolizers, whereas there was no change among the poor metabolizers. The partial clearance of chloroguanide by means of cydoguanil and 4-chlorphenylbiguanide formation among the extensive metabolizers decreased from 222 ml/min and 97 ml/min before to 33 ml/min and 11 ml/min during fluvoxamine intake, respectively. Among poor metabolizers the corresponding values were 35 ml/min and 7.6 ml/min before and 38 ml/min and 6.9 ml/min during fluvoxamine intake. For each metabolite clearance the change was statistically significant among the extensive metabolizers but not among the poor metabolizers. Both cycloguanil and 4-chlorphenylbiguanide formation clearances were statistically significantly higher among the extensive metabolizers than the poor metabolizers in period A but not in period B (phenocopy). CONCLUSION: Fluvoxamine is an effective inhibitor of CYP2C19.

Modified high-performance liquid chromatographic method to measure both dextromethorphan and proguanil for oxidative phenotyping.

The activities of the polymorphic enzymes cytochromes P450 2D6 and 2C19 can be assessed by administering the probe drugs, dextromethorphan and proguanil, respectively. An existing high-performance liquid chromatographic technique, which measures dextromethorphan and its metabolites, has been modified to also measure proguanil and its polymorphic metabolite, cycloguanil in urine. Proguanil and cycloguanil are assayed in separate aliquots of urine to that used for dextromethorphan/dextrorphan as pretreatment with beta-glucuronidase is required for the analysis of dextrorphan. To assay all four compounds a common extraction procedure is used and a single reversed-phase column and isocratic mobile phase with UV and fluorescence detectors connected in series are required. This technique is specific and sensitive for each analyte (limits of detection, dextrorphan/dextromethorphan/proguanil: 0.1 microgram/ml, cycloguanil: 0.2 microgram/ml). All assays are linear over the concentration ranges investigated (dextromethorphan/dextrorphan: 0.5-10 micrograms/ml, proguanil/cycloguanil: 1-20 micrograms/ml). The method described therefore uses laboratory resources very efficiently for all the assays required for hydroxylation phenotyping using proguanil and dextromethorphan.

Association between CYP2C19 genotype and proguanil oxidative polymorphism.

AIMS: To examine the relationship between proguanil metabolism and the number of mutations in CYP2C19 by comparing the CYP2C19 genotype and proguanil phenotype of 10 subjects. METHODS: Partial clearance and urinary metabolic ratio data were obtained from a previous study of 10 subjects [5]. Analysis of CYP2C19 genotypes was performed using PCR amplification followed by restriction endonuclease digestion of genomic DNA from a blood sample. RESULTS: The intrinsic partial clearance of PG to CG ranged from 0.41-10.11 h-1, and was related to the number of functional CYP2C19 alleles present. Genotypic PMs had metabolic ratios > 13, while genotypic heterozygote EMs had metabolic ratios < 9. CONCLUSIONS: Proguanil may be a suitable phenotyping probe for the CYP2C19 genetic polymorphism, however the exact antimode of the urinary metabolic ratio chosen to separate poor and extensive metabolisers needs further investigation.

Effects of omeprazole and cimetidine on the urinary metabolic ratio of proguanil in healthy volunteers.

OBJECTIVE: To examine the effects of omeprazole and cimetidine on the urinary recovery and metabolic ratio of proguanil in healthy subjects. METHODS: A metabolic interaction study was conducted in 12 young, healthy extensive metabolisers of proguanil, a CYP2C19 substrate, following a single 100 mg oral dose by analysis of urine collected for 8 hours. RESULTS: Concomitant administration of omeprazole (20 mg), a CYP2C19 substrate, had no significant effect on the urinary recovery of proguanil or cycloguanil, or the ratio of cycloguanil to proguanil [mean 0.76 (95% CI: 0.53 to 0.98) proguanil alone; mean 0.65 (95% CI: 0.40 to 0.89) proguanil plus omeprazole]. In contrast, cimetidine (400 mg), a general CYP inhibitor and renal organic cation secretion inhibitor, decreased the urinary recovery of cycloguanil and reduced the metabolic ratio from a mean of 0.76 to 0.54 (P < 0.01). In 3 poor metabolisers of proguanil, cimetidine had no effect on the proguanil metabolic ratio. CONCLUSION: The concomitant administration of omeprazole or cimetidine will not result in phenocopying extensive metabolisers of proguanil, although cimetidine inhibits the formation of cycloguanil in extensive metabolisers.

Evidence for the polymorphic oxidation of debrisoquine and proguanil in a Khmer (Cambodian) population.

The frequency distributions of the urinary metabolic ratios of debrisoquine and proguanil were measured in a population of unrelated Khmers. Out of 98 Khmer subjects studied, two were identified as poor metabolisers of debrisoquine when a metabolic ratio of 12.6 was used as the cut off point. This represents a prevalence of debrisoquine poor metabolisers of 2.1% (95% confidence interval 0.25-7.3%) which is similar to other Asian populations. Based on the distribution of the ratio of proguanil to cycloguanil excreted in urine, and using an antimode value of 10, the prevalence of poor metabolisers of proguanil in a Khmer population was estimated to be 18.4% (95% confidence interval 10.9-28.1%). The frequency of poor metabolisers of proguanil in Khmers was higher than that described for Caucasian populations, but similar to most reported results in Asian populations.

Metabolic disposition of proguanil in extensive and poor metabolisers of S-mephenytoin 4'-hydroxylation recruited from an Indonesian population.

1. The metabolism of proguanil (PG) was studied by measuring PG, cycloguanil (CG) and 4-chlorophenylbiguanide (CPB) in plasma and urine samples after an oral 200 mg dose of PG hydrochloride administered to 14 extensive (EMs) and 10 poor hydroxylators (PMs) of S-mephenytoin of Indonesian origin. 2. The mean ( +/- s.d.) values of the elimination half-life (t 1/2) and AUC of PG were significantly (P < 0.01) greater in the PM than in the EM group (20.6 +/- 3.1 vs 14.6 +/- 3.5 (95% confidence intervals of difference 3.1 to 8.9) h; and 5.43 +/- 1.89 vs 3.68 +/- 0.83 (0.58 to 2.91) micrograms ml-1 h). 3. Plasma concentrations of CG, an active metabolite, could not be detected in all PMs, and those of CPB were sufficiently high to determine a time-course in only four PMs. Mean AUC(0,24 h) values of CPB were significantly (P < 0.05) lower in the PM (n = 4) than in the EM group (n = 14) (0.47 +/- 0.13 vs 0.88 +/- 0.50 (-0.14 to 0.96) micrograms ml-1 h). 4. Log10 percentage urinary recovery of 4'-hydroxymephenytoin correlated significantly (P < 0.05) with the t 1/2 (rs = -0.661) and AUC (rs = -0.652) of PG. 5. PG, CG and CPB were detectable in urine at 12 h in all subjects. Log10 percentage urinary recovery of 4'-hydroxymephenytoin correlated significantly (P < 0.01) with urinary PG/CG (rs = -0.876), PG/CPB (rs = -0.833) and PG/(CG + CPB) (rs = -0.831) metabolic ratios.(ABSTRACT TRUNCATED AT 250 WORDS)

Simultaneous determination of chloroquine, proguanil and their metabolites in human biological fluids by high-performance liquid chromatography.

A reversed-phase ion-pair high-performance liquid chromatographic method with ultraviolet detection is described for the simultaneous measurement of chloroquine, proguanil and their major metabolites in human plasma, erythrocytes and urine. After a liquid-solid extraction on a Bond Elut C8 cartridge, the compounds are separated on a C8 Lichrospher 60 RP select B column by isocratic elution; the mobile phase is water-acetonitrile-methanol (78:28:4, v/v/v) with 0.5 M ammonium formate and 0.075 M perchloric acid. The eluent is monitored with an ultraviolet detector at 254 nm. The lower limits of quantification in plasma are near 6.0 ng ml-1 for chloroquine and near 9.0 ng ml-1 for proguanil. No chromatographic interference can be detected from endogenous compounds or from other antimalarial drugs. The method is accurate and precision is good with inter- and intra-assay relative standard deviations lower than 6.8% for plasma samples. N-(2-6 dichlorobenzylidene amino)guanidine is used as an internal standard. The chromatographic procedure takes 35 min and can be used for therapeutic drug monitoring and clinical studies.

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.

Plasma, erythrocyte and urine concentrations of chlorproguanil and two metabolites in man after different doses.

Failures in the prophylactic effect of the antimalarial biguanide chlorproguanil (Lapudrine) may be caused by insufficient levels of its active metabolite chlorcycloguanil. Concentrations of chlorproguanil, chlorcycloguanil and a second metabolite, dichlorophenylbiguanide, in plasma, erythrocytes and urine, were followed in 13 volunteers, using a HPLC assay. In an initial study the basic kinetics were investigated after an oral dose of 2 mg kg-1. In the main study, the concentration-time curves were followed for 1 week after an oral dose of 20 or 80 mg chlorproguanil, respectively, after either a single dose or one weekly dose for 5 weeks. Higher concentrations of all three compounds were found in erythrocytes than in plasma. The active substance, chlorcycloguanil, was below the probably effective concentration in erythrocytes 24 h after 20 mg chlorproguanil and 72 h after 80 mg. The urinary recovery was about 45% of the dose and t1/2 31-44 h, both higher than previously reported. The apparent clearance was 0.52-0.82 l h-1 kg-1, which is lower than previously found. It is suggested that improved dose regimens, e.g. a higher dose given once a week, should be clinically tested on basis of these kinetic results.

The pharmacokinetics and activation of proguanil in man: consequences of variability in drug metabolism.

1. Based on the ratio of drug to active metabolite excreted in urine approximately 3% of a healthy Caucasian population showed a reduced ability to convert proguanil to cycloguanil. 2. Pharmacokinetic analysis showed that this observation resulted from a reduced oral clearance of proguanil in these individuals (245, 534 and 552 ml min-1) compared with the rest of the population (858 +/- 482 ml min-1). 3. Peak plasma concentrations of active metabolite were significantly lower in these subjects (54.2, 26.8 and 51.7 ng ml-1) compared with the rest of the population (141 +/- 45.2 ng ml-1). 4. The observed variability may result from the polymorphic metabolism of proguanil in man.

Variability in the metabolism of proguanil to the active metabolite cycloguanil in healthy Kenyan adults.

Extensive metabolizers (EM) and poor metabolizers (PM) of the malaria chemoprophylactic drug proguanil have been identified by measuring the proguanil/cycloguanil ratio in urine following a single dose of the pro-drug. The pharmacokinetic characteristics of proguanil were similar in 8 EM and 8 PM subjects, but there were significant differences between the 2 groups with respect to cycloguanil pharmacokinetics. In none of the PM subjects could cycloguanil be detected in whole blood samples at any time after proguanil dosage. Plasma cycloguanil was measureable in only 2 of 8 PM subjects, despite an analytical sensitivity in the high-performance liquid chromatographic assay of 1 ng/ml cycloguanil. A comparatively high proportion of Black Kenyan adults appear to metabolize proguanil poorly, possibly because they lack the specific mixed function oxidase which will accept proguanil as substrate.