The beta1 selective beta-blocker metoprolol is metabolized predominantly but not exclusively by CYP2D6. Due to the polymorphism of the CYP2D6 gene, CYP2D6 activity varies markedly between individuals. Consequently, after short-term administration metoprolol plasma concentrations were found to be several fold higher in poor metabolizers than in extensive metabolizers. However, it is currently not known, whether the impact of the CYP2D6 polymorphism persists during long-term therapy, since alternate mechanisms of elimination or metabolism could be effective in this setting. The study comprised 91 Caucasian patients on long-term treatment with metoprolol (median duration of treatment 12.6 months; median daily drug dose: 47.5 mg/day). Metoprolol and alpha-OH-metoprolol plasma concentrations were assessed by HPLC. Genotyping detected the null alleles (*0): *3, *4, *5, *6, *7, *8, *12, *14, *15, the alleles *9, *10 and *41 associated with reduced enzymatic activity as well as the fully functional alleles *1 and *2. Genotype and allele frequencies were in accordance with published frequencies for the German population. The plasma metabolic ratio of metoprolol/alpha-OH-metoprolol was markedly affected by the genotype (P < 0.0001). In accordance, median adjusted metoprolol plasma concentrations were 6.2- and 3.9-fold higher in patients with *0/*0 genotypes (n = 8) and intermediate genotypes (n = 10), respectively, as compared to those with two fully functional alleles (n = 31; P < 0.01). In summary, the pronounced effect of the CYP2D6 genotype persists during long-term therapy, affecting both metabolic ratio and metoprolol plasma concentration.
The metabolic fate of brofaromine (CGP 11 305 A), a new, reversible, selective MAO-A inhibitor, has been assessed in poor (PM) and extensive (EM) metabolizers of debrisoquine. Compared to EM, PM had significantly longer t1/2 (136%) and larger AUC(0-infinity) (110%) of the parent compound brofaromine and a lower Cmax (69%) and AUC (0-72 h) (40%) of its O-desmethyl metabolite. The mean metabolite/substrate ratio (based on urine excretion) was about 6-times greater in EM than in PM. Treatment with quinidine converted all EM into phenocopies of PM. All pharmacokinetic parameters of brofaromine and O-desmethyl-brofaromine in EM treated with quinidine were similar to those of untreated PM, including the metabolite/substrate ratio. Quinidine treatment of PM did not alter the pharmacokinetics of brofaromine or of its metabolite, nor the metabolite/substrate ratio. The results indicate a role for the debrisoquine type of oxidation polymorphism in the O-demethylation and pharmacokinetics of brofaromine.
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