Effects of desvenlafaxine on the pharmacokinetics of desipramine in healthy adults.

The results of two single-center, two-period, open-label trials that evaluated the effects of multiple doses of desvenlafaxine on the pharmacokinetics of desipramine, a cytochrome P450 (CYP) 2D6 enzyme substrate, are presented. Healthy individuals aged 18-45 years were administered a single oral dose of 50 mg desipramine with and without 100 mg daily (n=34) or 400 mg daily (n=23) desvenlafaxine for 5 days. After coadministration of 100 mg desvenlafaxine, desipramine exposure, measured by peak plasma concentration (C(max)) and total area under the plasma concentration-versus-time curve (AUC), showed minimal increases of 25 and 17%, respectively; coadministration of 400 mg desvenlafaxine resulted in a 52% increase in desipramine C(max) and a 90% increase in AUC. For the 100 mg dose, the geometric least squares mean ratios and 90% confidence intervals (CIs) for desipramine AUC (117%; 90% CI 110-125%), 2-hydroxydesipramine AUC (114%; 90% CI 110-119%), and C(max) (110%; 90% CI 104-116%) were all within the 80-125% interval, showing the bioequivalence for AUC between desipramine administered alone and in combination with 100 mg desvenlafaxine. These results indicate that desvenlafaxine is a relatively weak inhibitor of CYP2D6 and that desvenlafaxine 100 mg, twice the recommended therapeutic dose of 50 mg, is unlikely to cause drug-drug interactions with CYP2D6 substrates.

Sequential metabolism of secondary alkyl amines to metabolic-intermediate complexes: opposing roles for the secondary hydroxylamine and primary amine metabolites of desipramine, (s)-fluoxetine, and N-desmethyldiltiazem.

Three secondary amines desipramine (DES), (S)-fluoxetine [(S)-FLX], and N-desmethyldiltiazem (MA) undergo N-hydroxylation to the corresponding secondary hydroxylamines [N-hydroxydesipramine, (S)-N-hydroxyfluoxetine, and N-hydroxy-N-desmethyldiltiazem] by cytochromes P450 2C11, 2C19, and 3A4, respectively. The expected primary amine products, N-desmethyldesipramine, (S)-norfluoxetine, and N,N-didesmethyldiltiazem, are also observed. The formation of metabolic-intermediate (MI) complexes from these substrates and metabolites was examined. In each example, the initial rates of MI complex accumulation followed the order secondary hydroxylamine > secondary amine >> primary amine, suggesting that the primary amine metabolites do not contribute to formation of MI complexes from these secondary amines. Furthermore, the primary amine metabolites, which accumulate in incubations of the secondary amines, inhibit MI complex formation. Mass balance studies provided estimates of the product ratios of N-dealkylation to N-hydroxylation. The ratios were 2.9 (DES-CYP2C11), 3.6 [(S)-FLX-CYP2C19], and 0.8 (MA-CYP3A4), indicating that secondary hydroxylamines are significant metabolites of the P450-mediated metabolism of secondary alkyl amines. Parallel studies with N-methyl-d(3)-desipramine and CYP2C11 demonstrated significant isotopically sensitive switching from N-demethylation to N-hydroxylation. These findings demonstrate that the major pathway to MI complex formation from these secondary amines arises from N-hydroxylation rather than N-dealkylation and that the primary amines are significant competitive inhibitors of MI complex formation.

The effects of desvenlafaxine and paroxetine on the pharmacokinetics of the cytochrome P450 2D6 substrate desipramine in healthy adults.

The potential for cytochrome P450 (CYP) 2D6 substrates to interact with desvenlafaxine (administered as desvenlafaxine succinate) and paroxetine was evaluated. In an open-label, crossover study, 20 healthy volunteers (aged 21-50) were randomized to 2 series of 9 days each of desvenlafaxine (100 mg/d) or paroxetine (20 mg/d), separated by a 5-day washout. The CYP2D6 substrate desipramine (50 mg) was administered alone on day 1 and coadministered on day 6 of dosing with either desvenlafaxine or paroxetine. CYP2D6 genotype was determined at baseline. Based on least squares geometric mean ratios between reference (desipramine alone) and test treatments, desvenlafaxine produced minor increases in desipramine area under the plasma concentration versus time curve (AUC; 36%) and peak plasma concentration (C(max); 30%) (vs paroxetine: 419%, 90%, respectively; both P < .001). Desvenlafaxine produced little change in 2-hydroxydesipramine AUC (16% increase) and C(max) (0%) versus paroxetine (18% and 82% decreases, respectively; P = .008, P < .001, respectively), indicating that desvenlafaxine, especially at the recommended therapeutic dose of 50 mg/d for major depressive disorder in the United States, has little potential to interact with CYP2D6 substrates.

An assessment of drug-drug interactions: the effect of desvenlafaxine and duloxetine on the pharmacokinetics of the CYP2D6 probe desipramine in healthy subjects.

A number of antidepressants inhibit the activity of the cytochrome P450 2D6 enzyme system, which can lead to drug-drug interactions. Based on its metabolic profile, desvenlafaxine, administered as desvenlafaxine succinate, a new serotonin-norepinephrine reuptake inhibitor, is not expected to have an impact on activity of CYP2D6. This single-center, randomized, open-label, four-period, crossover study was undertaken to evaluate the effect of multiple doses of desvenlafaxine (100 mg/day, twice the recommended therapeutic dose for major depressive disorder in the United States) and duloxetine (30 mg b.i.d.) on the pharmacokinetics (PK) of a single dose of desipramine (50 mg). A single dose of desipramine was given first to assess its PK. Desvenlafaxine or duloxetine was then administered, in a crossover design, so that steady-state levels were achieved; a single dose of desipramine was then coadministered. The geometric least-square mean ratios (coadministration versus desipramine alone) for area under the plasma concentration versus time curve (AUC) and peak plasma concentrations (C(max)) of desipramine and 2-hydroxydesipramine were compared using analysis of variance. Relative to desipramine alone, increases in AUC and C(max) of desipramine associated with duloxetine administration (122 and 63%, respectively) were significantly greater than those associated with desvenlafaxine (22 and 19%, respectively; P < 0.001). Duloxetine coadministered with desipramine was also associated with a decrease in 2-hydroxydesipramine C(max) that was significant compared with the small increase seen with desvenlafaxine and desipramine (-24 versus 9%; P < 0.001); the difference between changes in 2-hydroxydesipramine AUC did not reach statistical significance (P = 0.054). Overall, desvenlafaxine had a minimal impact on the PK of desipramine compared with duloxetine, suggesting a lower risk for CYP2D6-mediated drug interactions.

Effect of the novel anxiolytic drug deramciclane on cytochrome P(450) 2D6 activity as measured by desipramine pharmacokinetics.

BACKGROUND: In vitro findings have indicated that the novel anxiolytic drug, deramciclane, is an inhibitor of the cytochrome P(450) (CYP) 2D6 enzyme and co-administration of deramciclane and the CYP2D6 probe drug desipramine is possible in clinical practice. OBJECTIVE: To evaluate the effects of deramciclane on CYP2D6 activity as measured by desipramine pharmacokinetics and pharmacodynamics using paroxetine as a positive control for CYP2D6 inhibition. METHODS: Fifteen healthy subjects received either 60 mg deramciclane, 20 mg paroxetine or matched placebo for 8 days in randomized order in this double-blind, cross-over study. On day 8 of each study phase, the subjects received a 100-mg single dose of desipramine. Desipramine and its CYP2D6-dependent metabolite, 2-OH-desipramine, concentrations were measured for 240 h. Measurement of secretion of saliva, Visual Analogue Scale assessment of dryness of mouth and tiredness were carried out on day 7 and day 8 to assess the pharmacodynamic consequences of deramciclane or paroxetine co-administration with desipramine. RESULTS: Repeated administration of deramciclane doubled the AUC of desipramine ( P<0.001), while paroxetine caused a 4.8-fold increase in the AUC of desipramine ( P<0.001). Significant correlations were observed with paroxetine (r(s)=0.84, P<0.001) and deramciclane (r(s)=0.51, P=0.0498) concentrations and the magnitude of increase of desipramine AUC. Both deramciclane and paroxetine decreased the formation of 2-OH-desipramine in the first-pass phase. The AUC ratio of 2-OH-desipramine/desipramine was decreased by 39% ( P<0.001) by deramciclane and by 74% ( P<0.001) by paroxetine. There were no changes in the secretion of saliva during co-administration of desipramine with deramciclane compared with placebo. CONCLUSION: Although deramciclane seems to be a weaker inhibitor of CYP2D6 than paroxetine, dose adjustment of drugs metabolized by CYP2D6 may be needed when used concomitantly with deramciclane.

Effects of methylphenidate, desipramine, and L-dopa on attention and inhibition in children with Attention Deficit Hyperactivity Disorder.

The objective of this study was to investigate the effects of methylphenidate (MPH) on attention and inhibition in children with Attention Deficit Hyperactivity Disorder (ADHD) and to establish what the relative contributions of the noradrenergic and dopaminergic systems to this effect were. In addition to MPH, two other drugs were administered in order to affect both transmitter systems more selectively, L-dopa (dopamine (DA) agonist) and desipramine (DMI) (noradrenaline (NA) re-uptake inhibitor). Sixteen children with ADHD performed a stop-task, a laboratory task that measures the ability to inhibit an ongoing action, in a double-blind randomized within-subjects design. Each child received an acute clinical dose of MPH, DMI, L-dopa, and placebo; measures of performance and plasma were determined. The results indicated that inhibition performance was improved under DMI but not under MPH or L-dopa. The response-time to the stop-signal was marginally shortened after intake of DMI. MPH decreased omission and choice-errors and caused faster reaction times to the trials without the stop-tone. No effects of L-dopa whatsoever were noted. Prolactin levels were increased and 5-HIAA levels were lowered under DMI relative to placebo. It is suggested that the effects of MPH on attention are due to a combination of noradrenergic and dopaminergic mechanisms. The improved inhibition under DMI could be serotonergically mediated.

A 3D QSAR pharmacophore model and quantum chemical structure--activity analysis of chloroquine(CQ)-resistance reversal.

Using CATALYST, a three-dimensional QSAR pharmacophore model for chloroquine(CQ)-resistance reversal was developed from a training set of 17 compounds. These included imipramine (1), desipramine (2), and 15 of their analogues (3-17), some of which fully reversed CQ-resistance, while others were without effect. The generated pharmacophore model indicates that two aromatic hydrophobic interaction sites on the tricyclic ring and a hydrogen bond acceptor (lipid) site at the side chain, preferably on a nitrogen atom, are necessary for potent activity. Stereoelectronic properties calculated by using AM1 semiempirical calculations were consistent with the model, particularly the electrostatic potential profiles characterized by a localized negative potential region by the side chain nitrogen atom and a large region covering the aromatic ring. The calculated data further revealed that aminoalkyl substitution at the N5-position of the heterocycle and a secondary or tertiary aliphatic aminoalkyl nitrogen atom with a two or three carbon bridge to the heteroaromatic nitrogen (N5) are required for potent "resistance reversal activity". Lowest energy conformers for 1-17 were determined and optimized to afford stereoelectronic properties such as molecular orbital energies, electrostatic potentials, atomic charges, proton affinities, octanol-water partition coefficients (log P), and structural parameters. For 1-17, fairly good correlation exists between resistance reversal activity and intrinsic basicity of the nitrogen atom at the tricyclic ring system, frontier orbital energies, and lipophilicity. Significantly, nine out of 11 of a group of structurally diverse CQ-resistance reversal agents mapped very well on the 3D QSAR pharmacophore model.

Effect of tolcapone on the haemodynamic effects and tolerability of desipramine.

BACKGROUND AND PURPOSE: To determine the changes in haemodynamics, tolerability and pharmacokinetics that may occur when a combination of tolcapone and levodopa/carbidopa are given with desipramine. METHODS: In a crossover study, 22 healthy subjects received desipramine during two 13-day treatment periods (25 mg t.i.d. for 3 days and 50 mg t.i.d. for 10 days), with a washout period of 10-15 days. Subjects received levodopa/carbidopa (100 mg/25 mg t.i.d. for 5 days, days 9-13) and concomitant, double-blind, randomized treatment with either tolcapone (200 mg t.i.d.) or placebo. RESULTS: No significant pharmacodynamic and pharmacokinetic interactions occurred between tolcapone and desipramine. Adverse events were predictable based on the known effects of the individual drugs. CONCLUSIONS: Tolcapone can be combined with levodopa/carbidopa and desipramine in patients with Parkinson's disease.

Metabolism of desipramine in Japanese psychiatric patients: the impact of CYP2D6 genotype on the hydroxylation of desipramine.

We investigated the impact of the genotype of CYP2D6 on the hydroxylation of desipramine in eighteen patients who were administered desipramine hydrochloride per os. Significantly higher plasma concentration of desipramine/daily dose of desipramine/body weight was observed in the subjects with two mutated alleles than in the subjects with either no mutated alleles or one mutated allele (two mutated alleles versus no mutated alleles=530.4+/-215.2 versus 118.1+/-63.9 ng/ml/mg/kg, t=5.68, P<0.001; two mutated alleles versus one mutated allele=530.4+/-215.2 versus 176.2+/-62.3 ng/ml/mg/kg, P<0.001; One-way analysis of variance followed by Bonferroni's multiple comparison test, respectively). Significantly higher ratio of desipramine/2-hydroxy-desipramine was observed in the subjects with two mutated alleles compared to subjects with no mutated alleles or the subjects with one mutated allele (two mutated alleles versus one mutated allele= 4.39+/-0.36 versus 2.00+/-0.64, t=5.12, P<0.001; two mutated alleles versus no mutated alleles=4.39+/-0.36 versus 2.02+/-0.59, t=4.42, P<0.01). The genotyping of CYP2D6 only grossly predicts the steady state concentration of desipramine, mainly predicts the risk of getting very high plasma levels. Within each genotype there is marked interindividual variability.

Simultaneous determination of imipramine, desipramine and their 2- and 10-hydroxylated metabolites in human plasma and urine by high-performance liquid chromatography.

A simultaneous assay for imipramine, desipramine and their 2- and 10-hydroxy-metabolites using high-performance liquid chromatography (HPLC) is described. The drugs and internal standard, pericyazine, were extracted from plasma or urine at pH 9.6 with diethyl ether and back-extracted into 0.1 M orthophosphoric acid. The recovery of the compounds ranged from 78.6% for imipramine to 94.3% for 2-hydroxydesipramine. The extracts were analysed by reversed-phase HPLC with electrochemical detection using a mobile phase of 30% acetonitrile in 0.1 M K2HPO4 at pH 6.0 delivered at 2 ml/min. All compounds were resolved in a run time of 15 min with lower limits of quantification of 1.5 ng/ml for hydroxy-metabolites and 3 ng/ml for imipramine and desipramine. The intra- and inter-day coefficients of variation at 50 ng/ml were 5.2% and 6.8%, respectively (n=8).

Synthesis of 11C-labeled desipramine and its metabolite 2-hydroxydesipramine: potential radiotracers for PET studies of the norepinephrine transporter.

The antidepressant desipramine (DMI) and its principal metabolite 2-hydroxydesipramine (HDMI) have been radiolabeled with 11C for PET studies. The normethyl precursors of DMI and HDMI were synthesized from iminodibenzyl in 35% and 11% overall yield, respectively. Direct methylation of the normethyl precursor with [11C]CH3I, followed by HPLC purification, provided [11C]DMI and [11C]HDMI in 18-30% and 15-23% decay-corrected radiochemical yields, respectively, in a 45 min synthesis time from end of bombardment. The specific activities of the two radiotracers were >1459 Ci/mmol at the end of synthesis. [11C]DMI and [11C]HDMI have potential utility as PET radiotracers for the norepinephrine transporter.

2-Hydroxydesipramine and desipramine plasma levels: how are they related to antidepressant response?

Thirty-six outpatients aged 20 to 51 with RDC primary major depressive disorder (MDD) completed a 5-week trial of desipramine following a week of single-blind placebo. Five had a past history of hypomanic disorder. For all but one patient, daily dosage at bedtime was constant for the final 4 weeks, with a mean (S.D.) of 168.1 (46.5) mg. Plasma samples drawn at the three final weekly visits were assayed by high-performance liquid chromatography for 2-hydroxydesipramine (2-OH-DMI) and desipramine. Mean (S.D.) plasma levels were 59.8 (30.0) ng/ml for 2-OH-DMI and 142.9 (138.6) ng/ml for desipramine. Thirteen patients (36%) had a final 17-item Hamilton depression rating < and = 6 and were classified as responders. According to receiver operating characteristics analysis, patients with plasma 2-OH-DMI levels > and = 58 and < 92 ng/ml had a greater likelihood of responding than those with lower or higher levels (p = 0.005, Fisher's exact test), while patients with plasma desipramine levels > and = 64 ng/ml were more likely to respond than those with lower levels (p = 0.032, Fisher's exact test). Results using an alternate response criterion were similar. These findings suggest that in desipramine-treated outpatients with primary MDD the relationship between therapeutic response and plasma levels is curvilinear for 2-OH-DMI and linear for desipramine.

Phenobarbital induces the 2-hydroxylation of desipramine.

The kinetics of a single oral dose of desipramine (DMI; 100 mg) were studied in eight epileptic patients chronically treated with phenobarbital (PB) and in eight drug-free healthy controls. All subjects were extensive metabolizers with respect to the genetically determined CYP2D6-related metabolic polymorphism. Compared with controls, epileptic patients exhibited lower peak plasma DMI concentrations (74 +/- 24 vs. 107 +/- 32 nmol/L; means +/- SD, p < 0.05), smaller DMI area-under-the-curve values (1,943 +/- 461 vs. 3,234 +/- 1,145 nmol L-1 h; p < 0.01), and shorter DMI elimination half-lives (15.1 +/- 2.1 vs. 20.6 +/- 3.4 h; p < 0.01). The proportion of the dose excreted as 2-hydroxydesipramine (2-OH-DMI) was significantly higher in the patients (54 +/- 8 vs. 40 +/- 9%; p < 0.05). In one single poor metabolizer volunteer, a 3-week treatment with PB was associated with no major changes in DMI kinetics, but the urinary excretion of 2-OH-DMI tended to increase. These results suggest that PB is an inducer of the 2-hydroxylation of DMI, a reaction primarily catalyzed by CYP2D6, but do not provide further information on the specific P450 isoenzyme(s) being induced.

Inhibition of microsomal cytochromes P450 in rat liver by the tricyclic antidepressant drug desipramine and its primary oxidized metabolites.

N-Monoalkyl substituted tricyclic antidepressants like desipramine (DES) undergo cytochrome P450 (P450)-mediated biotransformation in liver to produce inhibitory metabolite-intermediate (MI) complexes with the enzyme. However, additional oxidation pathways that generate isolable metabolites have also been identified, so that the relationship between MI complexation and total oxidative metabolism is unclear. The present study investigated the capacity of DES and three putative metabolites (2-hydroxy- and 10-hydroxy-DES and N,N-didesmethylimipramine; DIDES) to elicit MI complexation and inhibit P450-dependent activities in rat liver. MI complexation of P450 was produced by DES, but not with the three metabolites, in NADPH-supplemented microsomes. Consistent with this finding, inhibition of testosterone hydroxylation pathways was enhanced markedly by prior incubation of DES with NADPH and microsomes. Direct addition of DIDES to incubations resulted in significant inhibition of P450 activities (IC50s of 35 and 29 microM against estradiol 6 beta- and 16 alpha-hydroxylation mediated by P450s 3A2 and 2C11, respectively). Neither 2-hydroxy- nor 10-hydroxy-DES directly inhibited testosterone hydroxylation (IC50s > 100 microM). However, after a preincubation step between these metabolites and NADPH-fortified microsomes, enhanced inhibition of reactions mediated by P450 3A2 and P450 2C11/2A1 was produced by 2-hydroxy-DES and 10-hydroxy-DES, respectively. Metabolism of DES to DIDES and 2-hydroxy-DES was estimated as 7.77 +/- 0.48 nmol/mg protein/hr (10-hydroxy-DES was not detected). It is likely that secondary oxidized metabolites derived from 2-hydroxy-DES, as well as the primary metabolite DIDES, may contribute to the inhibition of P450 activity during DES biotransformation. These results indicate that the 2-hydroxy-, 10-hydroxy-, and N-desmethyl-metabolites of DES are not involved in MI complexation, but complexation is not the sole mechanism by which DES inhibits microsomal drug oxidation that may lead to pharmacokinetic drug interactions.

Autoradiographic assessment of blood flow heterogeneity in the hamster heart.

OBJECTIVE: Provide regional flow measurement in the hearts of small mammals using a new, higher-resolution technique based on the deposition of a molecular marker. METHODS: We determined the instantaneous extraction and retention of the "molecular microsphere" radiolabeled desmethylimipramine in retrogradely perfused hamster hearts. In a separate series of experiments, autoradiography was used to measure regional myocardial deposition densities in hamster hearts of about 0.5 g with spatial area resolution of 16 x 16 microns. RESULTS: Radiolabeled desmethylimipramine is almost 100% extracted during a single transcapillary passage and is retained in the tissue for many minutes. Autoradiographic images demonstrated a spatial flow heterogeneity with standard deviations of 31 +/- 4% of the mean flow (N = 5) in 16 x 16 x 20-micronm3 voxels. This is equivalent to the projections made using fractal relationships from cruder observations obtained with microspheres in the hearts of baboons, sheep, and rabbits. CONCLUSIONS: Autoradiography using a molecular deposition marker provides quantitative information on myocardial flow heterogeneities with resolution at the size of cardiac myocytes. Because the regions resolved are smaller than the volume of regions supplied by single arterioles, the results must slightly exaggerate the true heterogeneity of regional flows.

Differential effect of desipramine and 2-hydroxydesipramine on depolarization-induced calcium uptake in synaptosomes from rat limbic sites.

This study was conducted to investigate the inhibition of synaptosomal 45Ca uptake by desipramine and its major metabolite 2-hydroxydesipramine in the rat hippocampus and cingulate cortex, areas associated with emotional control. A concentration-dependent inhibition of net depolarization-induced 45Ca uptake was observed for desipramine (20-200 microM) in synaptosomes from both sites. However, 20 microM 2-hydroxydesipramine failed to inhibit calcium channel function in either of the two limbic sites; higher concentrations (60 or 200 microM) did produce a minor degree of inhibition in hippocampus synaptosomes. Others have shown that the clinically encountered plasma concentrations of 2-hydroxydesipramine are lower than those of desipramine, and the brain concentration of 2-hydroxydesipramine is therefore not expected to surpass or even reach 20 microM. In view of the previously observed clinical activity of 2-hydroxydesipramine, the present results indicate that calcium channel antagonism may not be the basis for the therapeutic effect of tricyclic antidepressants.

Imipramine metabolism in relation to the sparteine and mephenytoin oxidation polymorphisms--a population study.

1. Sparteine and mephenytoin phenotyping tests were carried out in 327 healthy Danish subjects. Two weeks later each subject took 25 mg imipramine followed by urine collection for 24 h. The urinary content of imipramine, desipramine, 2-hydroxy-imipramine and 2-hydroxy-desipramine was assayed by h.p.l.c. 2. The medians of the hydroxylation ratios (i.e. 2-hydroxy-metabolite over parent compound) were 6 to 14 times higher in 300 extensive metabolizers of sparteine (EMs) as compared with 27 poor metabolizers (PMs), but none of the ratios separated the two phenotypes completely. 3. There were 324 EM of mephenytoin (EMM) and three PM (PMM) in the sample. The demethylation ratios between desipramine, 2-hydroxy-desipramine and their corresponding tertiary amines showed statistically significant correlations with the mephenytoin S/R isomer ratio (Spearman's rs: -0.20 and -0.27, P < 0.05). 4. The demethylation ratios were higher in 80 smokers than in 245 non-smokers. This indicates that CYP1A2, which is induced by cigarette smoking, also catalyzes the N-demethylation of imipramine. 5. CYP2D6 genotyping was carried out by PCR in 325 of the subjects, and the D6-wt allele was amplified in 298 EMs, meaning that they were genotyped correctly. One PMs was D6-wt/D6-B, another PMs had the genotype D6-wt/ and hence both were misclassified as EMs. The remaining 25 PMs were D6-A/D6-B (n = 5), D6-B/ (n = 18) or D6-D/D6-D (no PCR amplification, n = 2).(ABSTRACT TRUNCATED AT 250 WORDS)

Inhibition of desipramine hydroxylation in vitro by serotonin-reuptake-inhibitor antidepressants, and by quinidine and ketoconazole: a model system to predict drug interactions in vivo.

Biotransformation of the tricyclic antidepressant desipramine (DMI) to its metabolite 2-hydroxy-desipramine (2-OH-DMI) was studied in vitro using microsomal preparations from human, monkey, mouse and rat liver. In all species 2-OH-DMI was the principal identified metabolite. Mean (+/- S.E.) reaction parameters in six human liver samples were: Vmax, 0.11 +/- .02 nmol/ml/min/mg protein; Km, 16.1 +/- 4.2 microM. Quinidine was a highly potent inhibitor of 2-OH-DMI formation (mean Ki = 0.053 microM), consistent with the presumed role of Cytochrome P450-2D6 in mediating this reaction. Ketoconazole was a much less potent inhibitor (mean Ki = 10.3 microM). Two serotonin-specific reuptake inhibitor (SSRI) antidepressants, and their respective metabolites, were evaluated as potential inhibitors of 2-OH-DMI formation. Fluoxetine (FLU) and norfluoxetine (NOR) were the most potent inhibitors (mean Ki values: 3.0 and 3.5 microM, respectively). Sertraline (SERT) and its metabolite desmethylsertraline (DES) also inhibited the reaction (mean Ki: 22.7 and 16.0 microM), but were significantly less potent than FLU or NOR. Values of Ki and Km measured in vitro were used to generate a theoretical prediction of the degree of clearance inhibition in vivo at any given concentration of substrate and inhibitor. The model was applied to a clinical study in which DMI clearance in humans was impaired by coadministration of FLU (yielding FLU and NOR in plasma) or by SERT (yielding SERT and DES in plasma). Use of plasma SSRI concentrations in the predictive model underestimated the actual impairment of DMI clearance.(ABSTRACT TRUNCATED AT 250 WORDS)

Pharmacogenetics of desipramine metabolism.

There is wide interindividual variation in steady-state plasma concentration of desipramine and other tricyclic antidepressants primarily due to differences in rates of hydroxylation. Several studies have shown that the rate of hydroxylation of desipramine is correlated with the rate of hydroxylation of the genetic probe drug, debrisoquine, which is controlled by monogenic inheritance. However, no population studies of the polymorphic metabolism of antidepressants have been reported. In this study, 59 patients with endogenous depression received a fixed dose of desipramine and the steady-state plasma concentration of desipramine and 2-hydroxydesipramine were determined by high-pressure chromatography. A new statistical approach based on optimizing the fit to a specific stochastic model was utilized to separate the mixture of the three genotypes: homozygous extensive (AA), heterozygous extensive (Aa) and poor (aa) metabolizers. The proportions of the genotypes are 0.43, 0.45 and 0.12, respectively. The gene frequency of the low-activity allele is 0.34 and that of the high-activity allele is 0.66. The means (SD) of the desipramine/2-hydroxydesipramine metabolic ratios of the three genotypes are 1.71 (0.44), 3.32 (1.68) and 23.32 (10.03). These data suggest that the heterozygous genotype has half the metabolic activity of the homozygous extensive metabolizer and that the poor metabolizer genotype has negligible metabolic activity.