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In vitro studies have shown that esomeprazole, the S-isomer of omeprazole, is a metabolism dependent inhibitor (MDI) of cytochrome P450 2C19, an essential drug-metabolizing enzyme. In this study, we characterized the effects of esomeprazole in vivo on CYP2C19, 3A4, and 1A2 using pantoprazole, midazolam, and caffeine, respectively, as probe drugs. In addition, we estimated the half-life of CYP2C19 by observing its recovering activity after inhibition. In a 5-phase study 10 healthy volunteers were administered 20 mg pantoprazole, 50 mg caffeine and 0.5 mg midazolam before and 1, 25, 49 and 73 hours after a 7 day pretreatment with 80mg esomeprazole twice daily. Esomeprazole increased the (R)-pantoprazole’s exposure up to 5-fold and the significant increase lasted at least 72 hours, which suggests strong MDI of CYP2C19. Esomeprazole had a minor effect on CYP3A4 and no effect on CYP1A2. The turnover half-life of CYP2C19 was estimated to be 46 hours. This estimation will be useful in the future for in vitro-in vivo extrapolations and physiologically based pharmacokinetic modeling of CYP2C19. Concomitant use of drugs metabolized by CYP2C19 should be considered cautiously because of the clinically relevant strong and prolonged inhibition of CYP2C19 by esomeprazole. Alterations in exposures to drugs metabolized by CYP2C19 are expected after discontinuation of esomeprazole treatment for at least 3-4 days.

Cytochrome P450 (CYP) enzyme inhibition is one of the most common reasons for adverse drug-drug interactions. An especially harmful form of inhibition is time-dependent inhibition (TDI) in which the inhibition potency increases over time and persists even after discontinuation of the drug. Both direct and time-dependent inhibition can be efficiently screened with the so-called cocktail method containing several CYP-selective probe substrates in a single reaction mixture. This method is practical especially in ADME studies of drug development, as it offers lower costs, consumption of fewer reagents and faster implementation in comparison to conventional methods. In addition, the cocktail method can be used to establish new diagnostic CYP inhibitors in vitro. The aim of this Master’s thesis was to participate in the development and optimization of a new cocktail assay method. The method was developed for screening of major drug-metabolizing CYP enzymes in vitro both in a direct and time-dependent manner using pooled human liver microsomes. Based on preliminary testing, included probe substrates were divided into two cocktails to avoid significant inter-substrate interactions: cocktail I containing tacrine/CYP1A2, bupropion/CYP2B6, amodiaquine/CYP2C8, tolbutamide/CYP2C9 and midazolam/CYP3A4, and cocktail II containing coumarin/CYP2A6, (S)-mephenytoin/CYP2C19, dextromethorphan/CYP2D6 and astemizole/CYP2J2. First, cocktail incubation conditions were optimized, followed by the determination of probe reaction kinetics, kinetic parameters (Km, Vmax) and inter-substrate interactions with single- or dual-substrate incubations. Finally, suitable probe substrate concentrations and the composition of cocktails was evaluated based on the obtained results. As a result of assay optimization, optimal incubation conditions for yet unoptimized cocktail II were established. In optimized incubation conditions, all probe reactions exhibited saturable Michaelis-Menten kinetics except for tacrine 1-hydroxylation (CYP1A2), which exhibited biphasic kinetics instead (Km1: 7.36, Km2: 517). The selected probe substrate concentrations were all below or near their respective Km values except for (S)-mephenytoin 4’-hydroxylation (40 µM vs. Km of 12.5 µM); however, its concentration could not be reduced in order to maintain sufficient metabolite formation for UHPLC-MS/MS-analysis. Dual-substrate incubation assays demonstrated a need for the reduction of bupropion concentration below 100 µM due to its inhibitory effects on CYP2C8 and CYP3A4. In addition, chlorzoxazone/CYP2E1 and testosterone/CYP3A4 were tested as complementary probe substrates for the cocktails; however, they proved to be unsuitable for both cocktails due to significant interactions (>40% inhibition). Prior to the deployment of the method, some adjustments of probe substrate concentrations are still required in addition to consideration of the suitability of less commonly used CYP3A4 and CYP2E1 probe reactions to improve cocktail coverage. Lastly, validation of the method with known time-dependent model inhibitors should also be conducted. Besides to improvement of the cocktails, new information was generated on inter-cocktail probe-probe interactions and enzyme kinetics of probe reactions, especially for the less-studied astemizole O-demethylation (CYP2J2) and tacrine 1-hydroxylation (CYP1A2). Generated information can be used, for example, in the development of new cocktails.