Christina Alm

Disposition of perphenazine is related to polymorphic debrisoquin hydroxylation in luman beings

The pharmacokinetics of a single oral dose of 6 mg perphenazine was studied in a group of six slow and six rapid hydroxylators of debrisoquin. Peak serum concentrations of perphenazine were significantly higher in slow hydroxylators than they were in rapid hydroxylators (2.4 ± 0.6 versus 0.7 ± 0.3 nmol/L, p < 0.001). The AUC(0–12) was also higher in slow hydroxylators than it was in rapid hydroxylators (18.5 ± 6.2 versus 4.5 ± 2.5 nmol · L−1 · hr, p < 0.001). The data suggest that the disposition of the antipsychotic drug perphenazine covaries with polymorphic debrisoquin hydroxylation.

Haloperidol disposition is dependent on debrisoquine hydroxylation phenotype.

To investigate the importance of genetic factors for the regulation of haloperidol metabolism, we studied the disposition of a single oral dose of this drug in a panel of six extensive (EM) and six poor (PM) metabolizers of debrisoquine. PM eliminated haloperidol significantly slower than EM, the plasma half-life being longer (mean 29.4 +/- S.D. 4.2 and 16.3 +/- 6.4 h; p less than 0.01) and the clearance lower (1.16 +/- 0.36 and 2.49 +/- 1.31 L/h/kg; p less than 0.05). A 4-mg dose of haloperidol was given to the first three PM, but all three developed side effects, and a 2-mg dose had to be given to the next three PM subjects. All EM received 4 mg haloperidol. The disposition of haloperidol is thus associated with the genetically determined capacity to hydroxylate debrisoquine. PM of debrisoquine (7% of Caucasian populations) might, therefore, on common doses of haloperidol, achieve high plasma concentrations and thereby have an increased risk of side effects. At the other extreme, very rapid metabolizers may need increased doses of haloperidol.

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.

Disposition of fluvoxamine in humans is determined by the polymorphic CYP2D6 and also by the CYP1A2 activity

Fluvoxamine is a selective serotonin reuptake inhibitor used widely in the treatment of depression and other psychiatric diseases, but little is known about the specific isozymes involved in its metabolism. This study investigated the relationship between fluvoxamine disposition and the polymorphic CYP2D6 and the polycyclic aromatic hydrocarbon (as contained in cigarette smoke) inducible CYP1A2.

Evaluation of caffeine as an in vivo probe for CYP1A2 using measurements in plasma, saliva and urine.

Twenty-five healthy volunteers were given 100 mg caffeine orally and several estimates of cytochrome P450 1A2 (CYP1A2) activity were evaluated. The validation was performed by correlation of different parameters in plasma, saliva, and urine to two measures of caffeine clearance, CL(oral) and CL(137X-->17X) that served as standards of reference. Two subjects were excluded because of noncompliance with a caffeine-free diet. In the remaining 23 subjects, both plasma and saliva total clearances of caffeine were highly correlated with each other (r(s) = 0.97, p < 0.0001). The ratio 17X/137X restricted to one sampling point taken 4 hours after dose, showed a high correlation (r(s)) with CL(oral) and CL(137X-->17X) in plasma (0.84/0.83) and saliva (0.82/0.77) (p < 0.0001 for all the correlation values) where 17X is 1,7-dimethylxanthine (paraxanthine) and 137X is 1,3,7-trimethylxanthine (caffeine). Additionally, the ratio (AFMU + 1U + 1X + 17U + 17X)/137X in a 0-24 hours urine sampling showed the highest correlation with CL(137X-->17X) (r(s) = 0.85, p < 0.001) where AFMU is 5-acetylamino-6-formylamino-3-methyluracil, 1U is 1-methyluracil, 1X is 1-methylxanthine, and 17U is 1,7-dimethyluric acid. The major estimates of CYP1A2 activity were significantly less in nonsmoking females, and this probably was related to the use of oral contraceptives in this subpopulation. In summary, among caffeine-based approaches for CYP1A2, the authors recommend either plasma or saliva 17X/137X ratio and the urinary (AFMU + 1U + 1X + 17U + 17X)/137X ratio during a sampling interval of at least 8 hours, starting at time zero since caffeine intake. These indices are simple, reliable, and relatively inexpensive estimates of CYP1A2 activity to be used in the study of human populations.

Bantu Tanzanians have a decreased capacity to metabolize omeprazole and mephenytoin in relation to their CYP2C19 genotype

To investigate the CYP2C19 polymorphism in Tanzanians because this enzyme shows large interindividual differences in activity and metabolizes several drugs of importance in Africa, especially the antimalarial agent chloroguanide (INN, proguanil).

Decreased capacity for debrisoquine metabolism among black Tanzanians: analyses of the CYP2D6 genotype and phenotype.

The cytochrome P450 2D6 (CYP2D6) genotypes and phenotypes of 106 unrelated, healthy black Tanzanians of Bantu origin were investigated. The results revealed a population with a generally decreased capacity to metabolize the CYP2D6 substrate debrisoquine with 59% of the Tanzanian extensive metabolisers having debrisoquine metabolic ratios (MRs) > 1 versus 20% in Caucasians. This decrease in metabolic capacity was not fully explained by the partially or fully detrimental CYP2D6 gene mutations analysed for in this study. As many as 7% poor metabolizers of debrisoquine were identified but none was homozygous for defective CYP2D6 alleles. The majority among the group of poor metabolizers had relatively low metabolic ratios. The mutational profile indicated a closer association of the Tanzanian CYP2D locus to that of Zimbabweans rather than to that of Ethiopians. The defective alleles CYP2D6*3, *4, *5 and *6 were found at low frequencies (0%, 1%, 6%, 0%, respectively), whereas the CYP2D6*17 allele causing an enzyme with altered specificity was common (allele frequency = 17%). It is concluded that the CYP2D6 genotype in the Tanzanian Bantu population is different from that of other African populations examined to date and that further studies are required to explain the generally lower capacity to metabolize CYP2D6 substrates.

Systemic absorption and block after epidural injection of ropivacaine in healthy volunteers.

Background: For local anesthetics, the process of removal from the site of administration influences the duration of anesthesia and the risk for systemic toxicity to develop. The systemic absorption of epidural ropivacaine and the time profile of sensory and motor block were studied in healthy volunteers. Methods: Nine persons simultaneously received 150 mg ropivacaine hydrochloride (7.5 mg/ml) epidurally and 40 mg deuterium‐labeled (sup 2 H sub 3)ropivacaine hydrochloride (0.25 mg/ml) intravenously. Peripheral arterial and venous plasma samples were collected, and assessments of sensory and motor block were made. Results: The arterial plasma concentrations increased faster than the venous concentrations, with 50% higher maximum concentrations after both intravenous and epidural administration. The absorption was biphasic. A correlation was seen between the duration of sensory block and the slower absorption half‐life; that is, the longer the half‐life, the longer the duration. The extent of spread varied among the volunteers, with the median upper block level not exceeding T12. The motor block (Bromage score 1) was of slower onset (median, 0.4 h) and of shorter duration (median, 4.1 h) than the sensory block (onset, 0.2 h; duration, 6.5 h at L2 medians). Conclusions: As much as 50% differences were seen in the arteriovenous plasma concentrations of ropivacaine during the first hour, which has implications for the interpretation of systemic toxic plasma concentrations. The absorption into the general circulation was biphasic, with a correlation between the sensory block and the slower absorption half‐life. A faster onset and a longer duration of sensory compared with motor block was seen.

Metabolism of ropivacaine in humans is mediated by CYP1A2 and to a minor extent by CYP3A4: An interaction study with fluvoxamine and ketoconazole as in vivo inhibitors

Potential drug‐drug interactions can be identified in vitro by exploring the importance of specific cytochrome P450 (CYP) isozymes for drug metabolism. The metabolism of the local anesthetic ropivacaine to 3‐hydroxyropivacaine and (S)‐2′,6′‐pipecoloxylidide was shown in vitro to be dependent on CYP1A2 and 3A4, respectively. In this in vivo model study we quantitated the role of these 2 isozymes for the metabolism of ropivacaine.

Stereoselective disposition of mianserin is related to debrisoquin hydroxylation polymorphism.

The pharmacokinetics of mianserin and its main metabolite desmethylmianserin were studied in poor and extensive metabolizers of debrisoquin and of S‐mephenytoin after a single oral dose of racemic mianserin. The debrisoquin metabolic ratio (MR) correlated significantly with area under the serum concentration–time curves (AUC) for (±)‐mianserin and (±)‐desmethylmianserin. Enantioselective high‐performance liquid Chromatographie analysis of mianserin showed that debrisoquin MR was related to AUC(0–12) for S(+)‐mianserin (rs = 0.87; p = 0.001; n = 15) but not for R(–)‐mianserin. The ratio between the AUC(0–12) for S( +)‐mianserin and that for R (–)‐mianserin was higher in poor metabolizers than in extensive metabolizers. Two extremely rapid extensive metabolizer subjects had the lowest mianserin S/R ratios. No differences in the pharmacokinetics of mianserin or desmethylmianserin were found between extensive metabolizers and poor metabolizers of S‐mephenytoin. The study shows that the elimination of both mianserin and its main metabolite desmethylmianserin is dependent on CYP2D6 activity. Furthermore, the CYP2D6‐dependent elimination of mianserin shows marked enantioselectivity for the more active S(+)‐enantiomer of mianserin.