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.

Evaluation of the levels of free and total amitriptyline and metabolites in the plasma and brain of the rat after long-term administration of doses used in receptor studies.

This study was conducted in order to investigate the level of amitriptyline (AT) and its metabolites. Three separate experiments were carried out. In two of these experiments, rats were treated over 7 days with IP doses of AT (10 mg/kg in experiment A and 2 X 20 mg/kg in experiment C). The rats were sacrificed either 2 (experiment C) or 12 h (experiments A and C) after the last dose. In experiment B, rats were sacrificed 2 or 12 h after a single dose of 20 mg/kg AT. The results of these experiments showed the following: in experiment A only AT was measurable in the brain and in the plasma, in contrast to experiments B and C, where NT and the hydroxylated metabolites AT-OH and NT-OH reached significant levels in the plasma and in the brain. The concentrations of AT-OH, NT-OH, and NT (12-h values) that were found in the brain are probably not pharmacologically relevant. The 12-h plasma values of all compounds tested were, even with the highest dose, lower than those expected to be clinically effective in man. Our results suggest that AT, at higher doses, may induce its own metabolism. The free plasma levels of this drug and its metabolites are higher in man than in the rat. The possible implications of these results in the use of antidepressants in the treatment of depression are discussed.

Cytochrome P-450 activities in human and rat brain microsomes.

The role of cytochrome P450 in the metabolism of dextromethorphan, amitriptyline, midazolam, S-mephenytoin, citalopram, fluoxetine and sertraline was investigated in rat and human brain microsomes. Depending on the parameters, the limit of quantification using gas chromatography-mass spectrometry methods was between 1.6 and 20 pmol per incubation, which generally contained 1500 microg protein. Amitriptyline was shown to be demethylated to nortriptyline by both rat and human microsomes. Inhibition studies using ketoconazole, furafylline, sulfaphenazole, omeprazole and quinidine suggested that CYP3A4 is the isoform responsible for this reaction whereas CYP1A2, CYP2C9, CYP2C19 and CYP2D6 do not seem to be involved. This result was confirmed by using a monoclonal antibody against CYP3A4. Dextromethorphan was metabolized to dextrorphan in rat brain microsomes and was inhibited by quinidine and by a polyclonal antibody against CYP2D6. Only the addition of exogenous reductase allowed the measurement of this activity in human brain microsomes. Metabolites of the other substrates could not be detected, possibly due to an insufficiently sensitive method. It is concluded that cytochrome P450 activity in the brain is very low, but that psychotropic drugs could undergo a local cerebral metabolism which could have pharmacological and/or toxicological consequences.

GC and GC-MS procedures for simultaneous phenotyping with dextromethorphan and mephenytoin.

A genetic deficiency in the metabolism of dextromethorphan and mephenytoin may be revealed by the excretion pattern of dextromethorphan and its metabolite dextrorphan, and mephenytoin, 4-OH-mephenytoin, respectively, after a single dose of the test drugs. Existing methods were modified for determining the compounds in 0.1-0.5 ml urine samples. No prior derivatization of the compounds was necessary before their gaschromatographic or mass-spectrometric analysis by using crosslinked 5% phenylmethyl silicone fused silica columns. Seven healthy volunteers were phenotyped at weekly intervals with either 25 mg dextromethorphan or 100 mg mephenytoin, or both drugs. One subject was a poor metabolizer of mephenytoin, while all subjects were extensive metabolizers of dextromethorphan. Neither a pharmacokinetic nor an analytical interference was observed when the results of the single test were compared with those of the combined test. The results of the mephenytoin test were also tentatively given in form of metabolic ratios. The GC-MS assay was designed for clinical studies so that patients treated with other drugs could be phenotyped.

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.

Amitriptyline pharmacokinetics and clinical response: I. Free and total plasma amitriptyline and nortriptyline.

A group of 30 patients suffering from endogenous depression was treated with 150 mg amitriptyline (AT) for 21 days. Depression ratings and determinations of total and free plasma AT and nortriptyline (NT) were performed weekly. No correlation between clinical improvement and any of the biochemical parameters was found. Thus, this study does not support the existence of a therapeutic window for AT. A highly significant correlation was calculated between free and total AT and free and total NT, and also between the free fractions of AT and NT; moreover, age correlated significantly and positively with total plasma AT, but not with NT, and negatively with the free fractions of both AT and NT. The absence of correlation between clinical improvement and pharmacokinetic parameters is discussed for its possible significance. The finding that responders are also found in patients with "low" levels of antidepressants (corroborating the pharmacokinetic and pharmacodynamic data obtained in animals submitted to a long-term treatment with antidepressants) suggests that the concept of the need for steady-state levels with low fluctuations should be re-examined. In the light of these results the clinical effectiveness of treatment with higher drug doses, administered at larger intervals, in order to produce high amplitude fluctuations of the antidepressant should be studied.

[The use of low-dose amitriptyline in psychogeriatrics. A clinical, pharmacokinetic and pharmacogenetic study]. / Utilisation de l'amitriptyline à faible dose en psychogériatrie. Une étude clinique, pharmacocinétique et pharmacogénétique.

Two groups of six depressive psychogeriatric patients (age 69-93) have been treated for three weeks with either 25 mg or 50 mg of amitriptyline (AT) per day. Before the beginning of the treatment and after 8, 15 and 22 days of medication, the patients (7 outpatients and 5 hospitalized patients) underwent various psychopathological tests (Hamilton, Crichton) and biochemical investigations, i.e. clinical chemistry and hematology, analyses of AT and nortriptyline (NT), in the plasma. In some subjects the hydroxylated metabolites and the binding of these substances to plasma proteins were also measured. Except one patient, all responded favourably to the treatment. No difference between the two doses has been observed as regards their clinical efficacy and incidence of side effects. The plasma levels of AT and NT were below those generally recommended in the literature. The monitoring served to identify some cases of noncompliance and, in one patient, a deficiency of hydroxylation of AT, confirmed by the debrisoquine test. These results suggest that the "therapeutic window" needs redefinition and that low-dose medication with antidepressants is indicated in a psychogeriatric population.

Interindividual differences in the binding of antidepressives to plasma proteins: the role of the variants of alpha 1-acid glycoprotein.

Alpha 1-acid glycoprotein (AAG) is one of the plasma proteins that bind basic drugs, like amitriptyline (AT) and its metabolite nortriptyline (NT). Two types of genetic polymorphism have been described for AAG: polymorphic forms which, on electrophoresis of the native protein, give four patterns with 5, 6, 7 or 8 bands, and the variants which on by electrophoresis of the desialysed protein, give three patterns with 2 bands, FF, FS and SS. In 31 depressive patients, treated daily with 150 mg AT for 3 weeks, free and total plasma AT and NT were determined, as well as the AAG polymorphic forms and variants. There was only a weak negative correlation between the free fractions of AT and NT and total plasma AAG, but free AT and NT were strongly correlated with the S form (but not the F form) of AAG variants. The differences in binding might be the expression of a further genetic factor determining the steady-state plasma levels of tricyclic drugs.

Pharmacokinetic drug interaction potential of risperidone with cytochrome p450 isozymes as assessed by the dextromethorphan, the caffeine, and the mephenytoin test.

Two published case reports showed that addition of risperidone (1 and 2 mg/d) to a clozapine treatment resulted in a strong increase of clozapine plasma levels. As clozapine is metabolized by cytochrome P450 isozymes, a study was initiated to assess the in vivo interaction potential of risperidone on various cytochrome P450 isozymes. Eight patients were phenotyped with dextromethorphan (CYP2D6), mephenytoin (CYP2C19), and caffeine (CYP1A2) before and after the introduction of risperidone. Before risperidone, all eight patients were phenotyped as being extensive metabolizers of CYP2D6 and CYP2C19. Risperidone at dosages between 2 and 6 mg/d does not appear to significantly inhibit CYP1A2 and CYP2C19 in vivo (median plasma paraxanthine/caffeine ratios before and after risperidone: 0.65, 0.69; p = 0.89; median urinary (S)/(R) mephenytoin ratios before and after risperidone:0.11, 0.12; p = 0.75). Although dextromethorphan metabolic ratio is significantly increased by risperidone (median urinary dextromethorphan/dextrorphan ratios before and after risperidone: 0.010, 0.018; p = 0.042), risperidone can be considered a weak in vivo CYP2D6 inhibitor, as this increase is modest and none of the eight patients was changed from an extensive to a poor metabolizer. The reported increase of clozapine concentrations by risperidone can therefore not be explained by an inhibition of CYP1A2, CYP2D6, CYP2C19 or by any combination of the three.

Steady state plasma levels of the enantiomers of trimipramine and of its metabolites in CYP2D6-, CYP2C19- and CYP3A4/5-phenotyped patients.

Steady state plasma concentrations of the (L)- and (D)-enantiomers of trimipramine (TRI), desmethyltrimipramine (DTRI), 2-hydroxytrimipramine (TRIOH) and 2-hydroxydesmethyl-trimipramine (DTRIOH) were measured in 27 patients receiving between 300 and 400 mg/day racemic TRI. The patients were phenotyped with dextromethorphan and mephenytoin, and the 8-hour urinary ratios of dextromethorphan/dextrorphan, dextromethorphan/3-methoxymorphinan, and (S)-mephenytoin/(R)mephenytoin were used as markers of cytochrome P-450IID6 (CYP2D6), CYP3A4/5 and CYP2C19 activities, respectively. One patient was a CYP2D6 and one was a CYP2C19 poor metabolizer. A stereoselectivity in the metabolism of TRI has been found, with a preferential N-demethylation of (D)-TRI and a preferential hydroxylation of (L)-TRI. CYP2D6 appears to be involved in the 2-hydroxylation of (L)-TRI, (L)DTRI and (D)-DTRI, but not of (D)-TRI, as significant correlations were measured between the dextromethorphan/dextrorphan ratios and the (L)-TRI/(L)-TRIOH (r = 0.45, p = 0.019), the (L)-DTRI/(L)-DTRIOH (r = 0.47, p = 0.014), and the (D)-DTRI/(D)-DTRIOH (r = 0.51, p = 0.006), but not with the (D)-TRI/(D)-TRIOH ratios (r = 0.29, NS). CYP2C19, but not CYP2D6, appears to be involved in the demethylation pathway, with a stereoselectivity toward the (D)-enantiomer of TRI, as a significant positive correlation was calculated between the mephenytoin (S)/(R) ratios and the concentrations to dose-to-weight ratios of (D)-TRI (r = 0.69, p = 0.00006). CYP3A4/5 appears to be involved in the metabolism of (L)-TRI to a presently not determined metabolite. The CYP2D6 poor metabolizer had the highest (L)-DTRI and (D)-DTRI concentrations to dose-to-weight ratios, and the CYP2C19 poor metabolizer had the highest (L)-TRI and (D)-TRI concentrations to dose-to-weight ratios of the group.

A double-blind, placebo-controlled study of citalopram with and without lithium in the treatment of therapy-resistant depressive patients: a clinical, pharmacokinetic, and pharmacogenetic investigation.

Sixty-nine depressive patients (DSM III criteria: 296.2, 296.3, 296.5, 300.4) were treated with 40 to 60 mg citalopram (CIT) daily for 4 weeks. Among them, 45 responded to treatment (improvement > 50% on the 21-item Hamilton Rating Scale for Depression [HAM-D]) and continued their treatment for another week before being released from the study. The 24 nonresponders were randomized and comedicated under double-blind conditions with lithium carbonate (Li) (2 x 400 mg/day) (CIT-Li group) or with placebo (CIT-Pl group) from days 29 to 35. For days 36 to 42, the patients of both subgroups were treated openly with Li (800 mg/day) in addition to the ongoing CIT treatment. On day 35, 6 of 10 patients responded to the CIT-Li combination, whereas 2 of 14 patients only responded to the CIT-Pl combination. This group difference reached significance (p < 0.05) on day 35 with lower HAM-D total scores in the CIT-Li group. No evidence was seen of a pharmacokinetic interaction between CIT and Li, and this combination was well tolerated. Patients were phenotyped with dextromethorphan and mephenytoin at baseline and at day 28. As evaluated at baseline, three patients (responders) were poor metabolizers of dextromethorphan and six patients (three responders and three nonresponders) of mephenytoin. On day 28, the ratio CIT/N-desmethylCIT (DCIT) in plasma was significantly higher in poor than in extensive metabolizers of mephenytoin (p = 0.0001), and there was a significant positive correlation between the metabolic ratio of dextromethorphan and the ratio DCIT/N-didesmethylCIT in plasma (p < 0.001). These findings illustrate the role of CYP2D6 and CYP2C19 in the metabolism of CIT. It can be concluded that Li addition to CIT is effective in patients not responding to CIT alone without any evidence of an accentuation or provocation of adverse events.

Dextromethorphan and mephenytoin phenotyping of patients treated with thioridazine or amitriptyline.

The metabolism of most tricyclic antidepressants and some phenothiazine neuroleptics is under the genetic control of hepatic cytochrome P-450IID6, which also regulates the metabolism of dextromethorphan. This study investigated the effect of treatment with amitriptyline or thioridazine on testing for genetically regulated efficiency of the metabolism of dextromethorphan and mephenytoin. One group of 33 patients was treated with 150 mg amitriptyline a day (the AMI group); 25 other patients received a daily dose of thioridazine, either 200 mg (200-THD group; n = 7) or 400 mg (400-THD group; n = 18). Before and after 10 days of this treatment, all patients were tested with 25 mg dextromethorphan and 100 mg mephenytoin to determine their pharmacogenetic status with respect to their hepatic drug oxidizing systems (cytochrome P-450IID6 and P-450 MP). Two patients were poor metabolizers (PMs) of dextromethorphan and three of mephenytoin. Treatment with either psychotropic drug was without significant effect on the metabolism of mephenytoin, but both amitriptyline and thioridazine increased significantly the metabolic ratio of dextromethorphan/dextrorphan. Thioridazine had the effect of changing the pharmacogenetic status of 15 efficient metabolizers of dextromethorphan to poor metabolizers; amitriptyline did not have such an effect. There was no significant correlation between day-11 plasma levels of thioridazine, mesoridazine, or sulforidazine and the metabolism of dextromethorphan, but there was a correlation between the metabolism of dextromethorphan and plasma levels of amitriptyline and nortriptyline. Amitriptyline (p less than 0.05), but not thioridazine, decreases the ratio of conjugated/total dextrorphan in urine.(ABSTRACT TRUNCATED AT 250 WORDS)