Application of the Relative Activity Factor Approach in Scaling from Heterologously Expressed Cytochromes P450 to Human Liver Microsomes: Studies on Amitriptyline as a Model Substrate

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Vol. 297, Issue 1, 326-337, April 2001

Application of the Relative Activity Factor Approach in Scaling from Heterologously Expressed Cytochromes P450 to Human Liver Microsomes: Studies on Amitriptyline as a Model Substrate

Karthik Venkatakrishnan, Lisa L. von Moltke and David J. Greenblatt

Department of Pharmacology and Experimental Therapeutics, Tufts University School of Medicine, and the Division of Clinical Pharmacology, New England Medical Center, Boston, Massachusetts

	Abstract

Top Abstract Introduction Experimental Procedures Results Discussion References

The relative activity factor (RAF) approach is being increasingly used in the quantitative phenotyping of multienzyme drugbiotransformations. Using lymphoblast-expressed cytochromes P450(CYPs) and the tricyclic antidepressant amitriptyline as a modelsubstrate, we have tested the hypothesis that the human livermicrosomal rates of a biotransformation mediated by multiple CYPisoforms can be mathematically reconstructed from the rates ofthe biotransformation catalyzed by individual recombinant CYPsusing the RAF approach, and that the RAF approach can be usedfor the in vitro-in vivo scaling of pharmacokinetic clearancefrom in vitro intrinsic clearance measurements in heterologousexpression systems. In addition, we have compared the resultsof two widely used methods of quantitative reaction phenotyping,namely, chemical inhibition studies and the prediction of relativecontributions of individual CYP isoforms using the RAF approach.For the pathways of N-demethylation (mediated by CYPs 1A2, 2B6,2C8, 2C9, 2C19, 2D6, and 3A4) and E-10 hydroxylation (mediatedby CYPs 2B6, 2D6, and 3A4), the model-predicted biotransformationrates in microsomes from a panel of 12 human livers determinedfrom enzyme kinetic parameters of the recombinant CYPs were similarto, and correlated with the observed rates. The model-predictedclearance via N-demethylation was 53% lower than the previouslyreported in vivo pharmacokinetic estimates. Model-predicted relativecontributions of individual CYP isoforms to the net biotransformationrate were similar to, and correlated with the fractional decrementin human liver microsomal reaction rates by chemical inhibitorsof the respective CYPs, provided the chemical inhibitors usedwere specific to their target CYPisoforms.

	Introduction

Top Abstract Introduction Experimental Procedures Results Discussion References

The prediction of relative contributions of individual CYP isoforms to the overall metabolic rate of a drug biotransformationin human liver microsomes is important because this informationallows the prediction of drug-drug interactions that may resultupon coadministration with CYP isoform-selective inhibitors orinducers. This process is called quantitative reaction phenotypingand is generally accomplished using a combination of inhibitionstudies, correlation studies, and studies using heterologouslyexpressed CYP isoforms (Clarke, 1998; Rodrigues, 1999). Due tothe recent advances in molecular cloning and expression technologyand the commercial availability of cDNA-expressed CYP isoforms,these heterologously expressed enzymes are being increasinglyused as in vitro models of human liver microsomes in quantitativephenotyping (Crespi, 1995; Crespi and Penman, 1997; Crespi andMiller, 1999). When multiple enzymes catalyze a drug biotransformation,the utility of correlation analyses is limited unless they areused in a multivariate analysis format that generally requiresa large sample set (Clarke, 1998) and may thus not be of valuefrom a practical standpoint. Thus, the complementary approachesof inhibition studies and studies using heterologously expressedCYP isoforms are generally used in combination, and the utilityof this combined approach of integrated quantitative reactionphenotyping has been demonstrated in numerousstudies.

In the present investigation, we have characterized the biotransformation of the tricyclic antidepressant amitriptyline usinglymphoblast-expressed CYP isoforms and applied the relative activityfactor (RAF) approach (Crespi, 1995; Crespi and Penman, 1997;Crespi and Miller, 1999; Störmer et al., 2000; Venkatakrishnanet al., 2000a) in mathematically reconstructing the biotransformationrates in microsomes from a panel of 12 human livers. In addition,we have estimated the relative contributions of individual CYPisoforms to the overall rate of amitriptyline metabolism via theparallel pathways of N-demethylation and E-10 hydroxylation usingchemical inhibition studies and by application of the RAF approach.The results using both approaches have been compared, and thepossible sources of discrepancies between the two methods arediscussed. These studies provide further validation of the RAFapproach in scaling metabolic rates from heterologous expressionsystems to human liver microsomes, and the subsequent applicationof this approach in quantitative reaction phenotyping of multienzymebiotransformationpathways.

	Experimental Procedures

Top Abstract Introduction Experimental Procedures Results Discussion References

Materials. Liver samples, obtained from the International Institute for the Advancement of Medicine (Exton, PA), or the Liver TissueProcurement and Distribution Service (University of Minnesota)were from 12 different transplant donors (L1-L12) with no knownliver disease. The tissue was partitioned and kept at $-$ 80°C untilthe time of microsome preparation as described previously (vonMoltke et al., 1993, 1994). Microsomal protein concentrationswere determined using the bicinchoninic acid method (Pierce, Rockford,IL). Two of the 12 livers (L11 and L12) were CYP2C19-deficient,and one liver was CYP2D6-deficient. The phenotypic propertiesof the 12 livers with respect to the activities of CYPs 1A2, 2B6,2C9, 2C19, 2D6, and 3A have been previously described (Venkatakrishnanet al., 1998b, 1999, 2000a).

Microsomes from cDNA-transfected human lymphoblastoid cells expressing CYP1A2, 2A6, 2B6, 2C8, 2C9-Arg₁₄₄, 2C19, 2D6, 2E1,or 3A4 (Crespi, 1995

) were purchased from Gentest Corporation(Woburn, MA), aliquoted, and stored at $-$ 80°C, and thawed on icebefore use. Microsomal protein concentrations and CYP contentwere provided by the manufacturer. SUPERMIX (a commercially availableformulation of insect cell-expressed CYPs 1A2, 2C8, 2C9, 2C19,2D6, and 3A4, mixed in proportions similar to their activitiesin human liver microsomes) was purchased from GentestCorporation.

Amitriptyline and nortriptyline were purchased from Sigma (St. Louis, MO). E-10 hydroxy amitriptyline was purchased from ResearchBiochemicals International (Natick, MA). CYP isoform-selectivechemical inhibitors were purchased from their manufacturers: $alpha$ -naphthoflavone,sulfaphenazole, quinidine, and TAO were from Sigma; and ketoconazolewas from Research Biochemicals International. Omeprazole was kindlyprovided by Astra Pharmaceuticals. S-Mephenytoin was purchasedfrom Ultrafine Chemicals (Manchester,UK).

Measurement and Prediction of Amitriptyline Biotransformation Rates. Incubations of amitriptyline with human liver microsomes and lymphoblast-expressed CYPs were performed using previously describedmethods (Schmider et al., 1995, 1996; Venkatakrishnan et al.,1998a). Reactions were performed for 20 min at 37°C in 50 mM KH₂PO₄(pH 7.4) containing 5 mM MgCl₂, 0.5 mg/ml $beta$ -NADP⁺, and an isocitrate/isocitric dehydrogenase NADPH regeneratingsystem, in a total volume of 250 µl. Microsomal protein concentrationsand reaction times were chosen to be in the linear range and tominimize substrate consumption. Incubations were terminated bythe addition of 100 µl of acetonitrile and desipramine was addedas the internal standard. The incubates were centrifuged and theconcentrations of nortriptyline and E-10 hydroxy amitriptylinein the supernatants were measured by high performance liquid chromatographywith UV detection at 214 nm. A 30-cm × 3.9-mm steel reverse phaseC₁₈ µBondapak column (Waters, Milford, MA) was used and the mobilephase was a 70:30 mixture of 50 mM KH₂PO₄ and acetonitrile, ata flow rate of 1.5 ml/min.

The kinetics of amitriptyline N-demethylation and E-10 hydroxylation by lymphoblast-expressed CYP isoforms was described usingappropriate enzyme kinetic models to define the substrate concentration-velocityfunctions for each enzyme. At the lymphoblast microsomal proteinconcentration used (250 µg/ml), the free fraction of amitriptylinein incubates was 0.82, and the microsomal binding was ligand concentration-independent(Venkatakrishnan et al., 2000b

). Unbound substrate concentrationswere used in the kinetic analysis to determine unbiased estimatesof the enzyme kinetic parameters that would not be affected bymicrosomal protein concentration (McLure et al., 2000

; Venkatakrishnanet al., 2000b

The human liver microsomal rates of amitriptyline N-demethylation and E-10 hydroxylation were measured at a microsomal proteinconcentration of 200 µg/ml, at two added concentrations of amitriptyline:2.5 and 25 µM, in the panel of 12 human livers using previouslydescribed methods. Microsomal binding then effectively reducedthese concentrations to an estimated 1.5 and 15 µM, respectively,based on the free fraction in incubates containing 200 µg/ml microsomalprotein (0.63), determined by equilibrium dialysis (Venkatakrishnanet al., 2000b

). These concentrations of amitriptyline were chosento approximate the estimated intrahepatic concentrations of thedrug in humans after a single dose, and at steady state, respectively,based on the clinical pharmacokinetics of amitriptyline (Schulzet al., 1985

) and the intrahepatic partitioning of the drug (vonMoltke et al., 1998

). Rates of amitriptyline biotransformationby SUPERMIX were alsomeasured.

Equation 1 was used to predict the rates of amitriptyline N-demethylation and E-10 hydroxylation by the 12 liver samples andSUPERMIX:

<UP>v</UP>=<LIM><OP>∑</OP><LL><UP>i</UP></LL></LIM> <UP>A<SUB>i</SUB>v<SUB>i</SUB></UP>(<UP>s</UP>)

(1)

In this equation, the functions v_i(s) refer to the individual concentration-velocity functions for each CYP isoform mediatingthe N-demethylation or E-10 hydroxylation reaction, determinedby enzyme kinetic studies on lymphoblast-expressed isoforms, withthe correction for microsomal binding incorporated in kineticanalyses (Table 1). The terms A_is are scaling factors used toconvert rates of a biotransformation mediated by heterologouslyexpressed CYPs to the rates in human liver microsomes. RAFs wereused as estimates of A_is in this equation. The RAFs incorporatethe hepatic abundance of each CYP isoform and the differencesin activity per unit enzyme between the lymphoblast-expressedand human liver microsomal CYPs (Crespi, 1995

; Crespi and Miller,1999

; Störmer et al., 2000

; Venkatakrishnan et al., 2000a

). RAFsfor each CYP isoform were determined as the ratio of the rateof biotransformation of an isoform-specific index substrate byhuman liver microsomes to the rate of the same index reactioncatalyzed by the cDNA-expressed form of that enzyme, both ratesbeing measured at saturating substrate concentrations (Crespi,1995

; Crespi and Miller, 1999

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TABLE 1
Unbiased kinetic parameters of amitriptyline biotransformation by lymphoblast-expressed human CYP isoforms
N-Demethylation by CYPs 1A2, 2B6, and 2C9, and E-10 hydroxylation by CYPs 2B6, and 3A4 were described by a Michaelis-Menten model (parameters V_max and K_m denoting the maximal rate at saturating substrate concentrations and the Michaelis constant, respectively). N-Demethylation by CYP3A4 was described by a Hill model (S₅₀ denoting the substrate concentration at which 50% of the maximal rate V_max is reached, and A denoting the Hill coefficient). CYPs 2C8, 2C19, and 2D6 were described by a Michaelis-Menten model with uncompetitive inhibition by substrate (parameter K_s denoting the inhibition constant for uncompetitive inhibition by substrate).

Lymphoblast RAF estimates for these CYPs were determined for each liver, and for SUPERMIX using ethoxyresorufin O-deethylation(1A2), bupropion hydroxylation (2B6), Taxol 6 $alpha$ -hydroxylation (2C8),flurbiprofen 4-hydroxylation (2C9), S-mephenytoin 4-hydroxylation(2C19), bufuralol 1'-hydroxylation (2D6), and triazolam 1-hydroxylation(3A4) as index reactions (Table 2). The methods for RAF estimationusing these index reactions have been described in detail earlier(Störmer et al., 2000

; Venkatakrishnan et al., 2000a

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TABLE 2
Lymphoblast RAF estimates for CYPs 1A2, 2B6, 2C8, 2C9, 2C19, 2D6, and 3A4 in human liver microsomes and SUPERMIX
n = 12 human livers for CYPs 1A2, 2B6, 2C8, 2C9, and 3A4; n = 10 human livers for CYP2C19 (poor metabolizer livers L11 and L12 excluded); n = 11 human livers for CYP2D6 (poor metabolizer liver L8 excluded). Bolded table entries are sample medians, with range of values in parentheses and interquartile range in brackets. RAF values are in picomoles per milligram of microsomal protein.

The model-predicted amitriptyline N-demethylation and E-10 hydroxylation rates (eq. 1) were compared with the measured ratesin the panel of 12 human livers and SUPERMIX using correlationanalyses (SigmaStat software; SPSS Inc., Chicago,IL).

In Vitro Profiling of Oxidative Amitriptyline Metabolism. The fraction of total oxidative metabolic rate that was attributable to N-demethylation was predicted as the ratio of predictedN-demethylation rate to the sum of the predicted N-demethylationand E-10 hydroxylation rates for each liver sample, under theassumption that N-demethylation and E-10 hydroxylation accountfor the total oxidative metabolism of amitriptyline. That is,the contributions of the minor pathways of Z-10 hydroxylation,2-hydroxylation, and N-oxidation were ignored. The predicted N-demethylationfractions were compared with the observed values using correlationanalyses (SigmaStat software; SPSS Inc.).

Prediction of Pharmacokinetic Clearance. The unbiased kinetic parameters of lymphoblast-expressed CYP isoforms were used to calculate estimates of in vitro intrinsicclearance for amitriptyline N-demethylation. Because CYP3A4-mediatedamitriptyline N-demethylation was characterized by Hill enzymekinetics, the intrinsic clearance was calculated based on theassumption of maximal autoactivation of the enzyme in vivo, usingthe method proposed by Houston and Kenworthy (2000). For all otherCYPs, the intrinsic clearance was calculated as the V_max/K_m ratio(Houston, 1994). The net in vitro human liver microsomal intrinsicclearance was calculated as a linear combination of the intrinsicclearance terms contributed by each CYP isoform, weighted by theirrespective lymphoblast RAF estimates. This was then scaled upto in vivo intrinsic clearance using previously published valuesof scaling factors: 50 mg of microsomal protein per gram of liver,and 20 g of liver per kilogram of body weight (Carlile et al.,1999). The resulting estimated intrinsic clearance of amitriptylinevia N-demethylation was used in conjunction with estimates ofhuman hepatic blood flow (20 ml/min/kg) and the free fractionof amitriptyline in human plasma (0.057; Schulz et al., 1985)to predict intravenous clearance via N-demethylation using thewell stirred and parallel-tube models (Obach et al., 1997; Thummelet al., 1997; Obach, 1999). Predicted N-demethylation clearanceestimates using these liver models were compared with the in vivoN-demethylation clearance of amitriptyline (calculated as 60%of the total intravenous clearance) of 4 ml/min/kg (Schulz etal., 1985).

Chemical Inhibition Studies. Chemical inhibition studies were performed at substrate (amitriptyline) concentrations of 1.5 and 15 µM, at inhibitor concentrationsspecified below. The choice of inhibitor concentrations was basedon the existing data in the literature (Newton et al., 1995; Bourriéet al., 1996; Ono et al., 1996; Ko et al., 1997; Koyama et al.,1997) and from personal experience in our laboratory. The objectivewas to maximize the extent of inhibition of the target CYP withminimal nonspecific inhibition of other CYP isoforms. With theexception of TAO, all other inhibitors were coincubated with substrate,microsomes, and the NADPH regenerating system. TAO being a mechanism-basedinhibitor was preincubated with human liver microsomes and theNADPH regenerating system at 37°C for 20 min before initiationof the reaction with substrate. The selectivities of omeprazole(10 µM) and S-mephenytoin (500 µM) as CYP2C19 inhibitors wereevaluated using individual lymphoblast-expressed CYP isoformswith amitriptyline as the substrate, at an amitriptyline concentrationof 10 µM. At the concentration used, both omeprazole and S-mephenytoininhibited CYPs 2C9 and 1A2 in addition to CYP2C19 (under Results).Although omeprazole inhibition studies were performed simply bycoincubation with human liver microsomes and amitriptyline, theexperimental design was modified as follows with S-mephenytoinas inhibitor. Control incubations were performed in the presenceof $alpha$ -naphthoflavone (1 µM) and sulfaphenazole (10 µM), whereasCYP2C19-inhibited reactions contained these inhibitors in additionS-mephenytoin (500 µM). The fractional decrement of reaction velocity(FDV) by S-mephenytoin determined using this method should inprinciple be a better reflector of CYP2C19 contribution to theoverall rate of amitriptyline N-demethylation due to the lackof confounding effects of CYP1A2 and CYP2C9inhibition.

For the E-10 hydroxylation pathway, TAO inhibition studies could not be performed at the lower amitriptyline concentrationof 1.5 µM. Preincubation of microsomes for 20 min (even withoutthe inhibitor) caused substantial inhibition of the reaction thatresulted in E-10 hydroxy amitriptyline peaks that were practicallyundetectable (signal-to-noise ratios less than 2), making inhibitionby TAO difficult toquantify.

Prediction of Relative Contributions and Integrated Reaction Phenotyping. The relative contributions (f_i) of each CYP isoform to the overall rate of amitriptyline N-demethylation and E-10 hydroxylationwere predicted using the kinetic parameters of lymphoblast-expressedenzymes and RAF estimates (eq. 2), as described earlier for ratepredictions:

<UP>fi</UP>=<FR><NU><UP>Aivi</UP>(<UP>s</UP>)</NU><DE><LIM><OP>∑</OP><LL><UP>i</UP></LL></LIM> <UP>Aivi</UP>(<UP>s</UP>)</DE></FR> (2)

The model-predicted relative contributions were compared with the fractional decrement in reaction velocity by isoform-selectivechemical inhibitors for each liver using correlation analyses(SigmaStat software; SPSS Inc.).

	Results

Top Abstract Introduction Experimental Procedures Results Discussion References

Kinetics of Amitriptyline Biotransformation by Lymphoblast-Expressed CYP Isoforms. Amitriptyline was N-demethylated by CYPs 1A2, 2B6, 2C8, 2C9, 2C19, 2D6, and 3A4, whereas CYPs 2A6 and 2E1 did not show anydetectable activity. E-10 hydroxylation was observed in microsomescontaining CYPs 2B6, 2D6, and 3A4, whereas the other isoformsdid not show any detectable activity. All the identified amitriptylineN-demethylases and E-10 hydroxylases were characterized by enzymekinetics (Figs. 1 and 2, respectively) and the parameters aregiven in Table 1. CYP1A2- and 2C9-mediated amitriptyline N-demethylationshowed inhibition by substrate at high concentrations of amitriptyline(Fig. 1). However, models describing substrate inhibition didnot yield physiologically acceptable parameter estimates. Thus,a Michaelis-Menten model was used with the data points at amitriptylineconcentrations greater than 167 µM excluded from the nonlinearregression analysis.

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Fig. 1. Kinetics of amitriptyline (AMI) N-demethylation by lymphoblast-expressed CYP isoforms. Closed circles are experimental data points, and lines are fitted functions. Data points for CYPs 1A2 and 2C9 with unbound amitriptyline concentrations greater than 167 µM were excluded in nonlinear regression analysis for estimation of kinetic parameters, and are indicated as open circles. See Table 1 for kinetic parameters.

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Fig. 2. Kinetics of amitriptyline (AMI) E-10 hydroxylation by lymphoblast-expressed CYP isoforms. Closed circles are experimental data points, and lines are fitted functions. See Table 1 for kinetic parameters.

Rate Measurements and Predictions, and in Vitro Profiling of Oxidative Amitriptyline Metabolism. Strong statistically significant correlations were observed between the predicted and observed rates of amitriptyline N-demethylationand E-10 hydroxylation, and the N-demethylation fraction in thepanel of 12 human livers. The predicted and observed N-demethylationrates were almost identical (Fig. 3, A and D), whereas the E-10hydroxylation rates were generally underpredicted with a lessthan 2-fold error (Fig. 3, B and E). This resulted in a smalloverprediction of the N-demethylation fraction (calculated asthe ratio of N-demethylation rate divided by the sum of N-demethylationand E-10 hydroxylation rates), especially at the lower amitriptylineconcentration of 1.5 µM (Fig. 3, C and F).

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Fig. 3. Comparison of predicted (x-axis) and observed (y-axis) human liver microsomal rates of amitriptyline N-demethylation (A and D) and E-10 hydroxylation (B and E), and the N-demethylation fraction (C and F) at substrate concentrations of 1.5 µM (A-C) and 15 µM (D-F). Closed circles represent individual human liver samples and the open circle represents SUPERMIX. The dotted line is the line of identity, and the area between the dashed lines is the area with a less than 2-fold prediction error. When statistically significant (p < 0.05), R² values indicating the strength of the correlation are provided, and the regression line is depicted as a solid line. The SUPERMIX data point was not included in correlation analyses.

Amitriptyline N-demethylation rates by SUPERMIX were higher than those observed in human liver microsomes, whereas the E-10hydroxylation rates and N-demethylation fractions were in therange of those observed for human livermicrosomes.

Prediction of Pharmacokinetic Clearance. The RAF model-predicted value of human liver microsomal intrinsic clearance for amitriptyline N-demethylation was 35.7 µl/min/mgmicrosomal protein. The resulting scaled up estimated intrinsicclearance of amitriptyline via N-demethylation was 35.7 ml/min/kgof body weight. Predicted N-demethylation clearance estimatesusing the well stirred and parallel-tube liver models were 1.8and 1.9 ml/min/kg,respectively.

Quantitative Reaction Phenotyping. At amitriptyline concentrations of 1.5 and 15 µM, the model-predicted relative contributions of each CYP isoform to overallN-demethylation and E-10 hydroxylation rate are provided in Table3. These predicted relative contributions can then be comparedwith and used in conjunction with the results of chemical inhibitionstudies (Table 4) for integrated quantitative reaction phenotyping.

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TABLE 3
Predicted relative contributions (f_i) of individual CYP isoforms to rates of amitriptyline N-demethylation and E-10 hydroxylation by human liver microsomes and SUPERMIX at substrate concentrations of 1.5 and 15 µM, using RAF estimates (Table 2) and kinetic parameters of amitriptyline biotransformation (Table 1) in eq. 2
Table entries are means ± S.D., with the range of values in parentheses. Data from CYP2C19 and 2D6 poor metabolizer livers were excluded in calculating means and range of values for N-demethylation; data from the CYP2D6 deficient liver was excluded for E-10 hydroxylation (n = 9 human livers for N-demethylation, n = 11 human livers for E-10 hydroxylation).

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TABLE 4
Results of chemical inhibition studies of amitriptyline biotransformation by human liver microsomes and SUPERMIX at substrate concentrations of 1.5 and 15 µM
FDV is presented. Table entries are means ± S.D., with the range of values in parentheses. Data from CYP2C19 and 2D6 poor metabolizer livers were excluded in calculating means and range of values for N-demethylation; data from the CYP2D6 deficient liver was excluded for E-10 hydroxylation (n = 9 human livers for N-demethylation, n = 11 human livers for E-10 hydroxylation).

At the concentrations chosen, both omeprazole (10 µM) and S-mephenytoin (500 µM) produced an approximately 75% inhibitionof lymphoblast-expressed CYP 2C19-mediated amitriptyline N-demethylation(IC₅₀ values of 2.8 and 66.3 µM for omeprazole and S-mephenytoin,respectively, at a substrate concentration of 10 µM) and alsosignificantly inhibited CYPs 1A2 (45-50% inhibition) and 2C9 (55-60%inhibition), whereas the rates of amitriptyline N-demethylationby CYPs 2B6, 2C8, 2D6, and 3A4 were largely unaltered (Fig. 4).This indicated that these CYP2C19 inhibitors were not completelyselective.

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Fig. 4. Inhibition of amitriptyline N-demethylation catalyzed by lymphoblast-expressed CYP isoforms, by omeprazole (A and B) and S-mephenytoin (C and D). A and C, effects of a fixed concentration of inhibitor (10 µM omeprazole and 500 µM S-mephenytoin, respectively) on amitriptyline N-demethylation by CYPs 1A2, 2B6, 2C8, 2C9, 2C19, 2D6, and 3A4 were examined. B and D, inhibition of lymphoblast-expressed CYP2C19 was studied, and IC₅₀ analyses were performed using varying concentrations of the inhibitor. In all experiments the amitriptyline concentration was 10 µM.

Ketoconazole, at the concentration chosen (2.5 µM) was not a CYP3A4-specific inhibitor, based on studies with lymphoblast-expressedCYP isoforms. At an amitriptyline concentration of 5 µM, ketoconazole(2.5 µM) completely inhibited CYP3A4-mediated amitriptyline N-demethylation.In addition, CYPs 1A2, 2C8, 2C9, and 2C19 were inhibited by 18,43, 33, and 30%, respectively. However, the rates of CYP2B6- and2D6-mediated amitriptyline N-demethylation were notaffected.

The results of chemical inhibition studies are summarized in Table 4. In Figs. 5-7, the results of chemical inhibition studieshave been compared with the model predicted relative contributionsof each CYP to amitriptyline N-demethylation and E-10 hydroxylationrate. In each plot, the association between the model-predictedrelative contribution of a CYP isoform (x-axis) and the FDV byan inhibitor of that isoform (y-axis) in the panel of 12 humanlivers is examined.

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Fig. 5. Comparison of model-predicted relative contributions (x-axis) of individual CYP isoforms to amitriptyline N-demethylation rate at a substrate concentration of 1.5 µM, and the FDV by an isoform-selective chemical inhibitor of that CYP (y-axis). See legend to Fig. 3 for meanings of symbols and lines, and text for details of chemical inhibition methods.

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Fig. 6. Comparison of model-predicted relative contributions (x-axis) of individual CYP isoforms to amitriptyline N-demethylation rate at a substrate concentration of 15 µM, and the FDV by an isoform-selective chemical inhibitor of that CYP (y-axis). See legend to Fig. 3 for meanings of symbols and lines, and text for details of chemical inhibition methods.

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Fig. 7. Comparison of model-predicted relative contributions (x-axis) of individual CYP isoforms to amitriptyline E-10 hydroxylation rate at substrate concentrations of 1.5 µM (A and B) and 15 µM (C-E), and the FDV by an isoform-selective chemical inhibitor of that CYP (y-axis). See legend to Fig. 3 for meanings of symbols and lines, and text for details of chemical inhibition methods.

Figure 8 compares the results of both approaches to reaction phenotyping. Mean values of predicted relative contributionsin the panel of livers are compared with the mean FDV values determinedusing selective chemical inhibitors (with CYP2D6- and 2C19-deficientlivers excluded in the analysis for N-demethylation, and the CYP2D6-deficientliver excluded for E-10 hydroxylation).

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Fig. 8. Comparison of the averaged results of the RAF-based method using heterologously expressed CYP enzymes (model-predicted relative contribution of individual CYP isoforms on the x-axis) and of chemical inhibition studies (FDV by chemical inhibitors of the respective CYP isoforms on the y-axis) as approaches to quantitative phenotyping of amitriptyline N-demethylation (A and B) and E-10 hydroxylation (C and D), at substrate concentrations of 1.5 µM (A and C) and 15 µM (B and D). CYP-inhibitor pairs shown are 1A2- $alpha$ -naphthoflavone (1), 2C9-sulfaphenazole (2), 2C19-omeprazole (3), 2C19-S-mephenytoin (4), 2D6-quinidine (5), 3A4-TAO (6), and 3A4-ketoconazole (7). Data points are averaged values of the nine livers containing functional CYPs 2C19 and 2D6, for N-demethylation; and of the 11 livers containing functional CYP2D6 for E-10 hydroxylation. See Tables 3 and 4 for standard deviations and range of values. The dotted line is the line of identity, and the area between the dashed lines is the area with a less than 2-fold prediction error.

	Discussion

Top Abstract Introduction Experimental Procedures Results Discussion References

We have established using amitriptyline as a model substrate that the human liver microsomal rates of multienzyme drug biotransformationscan be mathematically reconstructed using the enzyme kinetic parametersof heterologously expressed CYPs and scaling factors that incorporatethe relative hepatic abundance of individual CYP isoforms andthe differences in turnover number between the cDNA-expressedenzymes and their human liver microsomal counterparts. Amitriptylinewas chosen as the model substrate considering the multiplicityof CYP enzymes that mediate its oxidativebiotransformation.

The prediction of human liver microsomal rates using kinetic parameters of individual cDNA-expressed CYPs has been reportedfor omeprazole 5-hydroxylation (Yamazaki et al., 1997), 7-ethoxycoumarinO-deethylation (Shimada et al., 1999), chlorzoxazone 6-hydroxylation(Shimada et al., 1999), and for cyclophosphamide and ifosfamide4-hydroxylation (Roy et al., 1999) and N-dechloroethylation (Huanget al., 2000). Our approach is similar to the approaches of Royet al. (1999) and Huang et al. (2000) that used the relative substrate-activity-factor-basedmethod (Roy et al., 1999; Huang et al., 2000) that is identicalin principle to the RAF approach (Crespi, 1995; Crespi and Penman,1997; Crespi and Miller, 1999). On the other hand, Yamazaki etal. (1997) and Shimada et al. (1999) used immunoquantified levelsof individual CYPs to predict biotransformation rates in livermicrosomes (Yamazaki et al., 1997; Shimada et al., 1999). As demonstratedpreviously, immunoquantified CYP levels may not be valid scalingfactors to predict human liver microsomal rates from rates measuredin heterologous expression systems, due to differences in turnovernumber of the enzyme in the two situations (Venkatakrishnan etal., 2000a).

As illustrated here for amitriptyline, this scaling approach can be used for in vitro metabolite profiling. The N-demethylationfraction for amitriptyline predicted using this approach (0.80± 0.09 and 0.84 ± 0.06 at substrate concentrations of 1.5 and15 µM, respectively) was similar to that observed in human livermicrosomes (0.71 ± 0.11 and 0.82 ± 0.06 at substrate concentrationsof 1.5 and 15 µM, respectively). These values are greater thanthe average in vivo demethylation fraction of 0.6 after a singleamitriptyline dose in humans (Rollins et al., 1980; Mellströmet al., 1983, 1986), most likely explained by the failure to measurethe minor oxidative pathways of Z-10 hydroxylation, 2-hydroxylation,and N-oxidation, and the direct conjugative pathway of N-glucuronidationin our in vitrosystem.

A potential application of the RAF approach is the prediction of pharmacokinetic clearance from intrinsic clearance measurementsin heterologous expression systems (Ito et al., 1998). For amitriptyline,there was a 53% underprediction of in vivo N-demethylation clearance(predicted value of 1.9 ml/min/kg, compared with literature averagevalue of 4 ml/min/kg). Amitriptyline is lipophilic and undergoesextensive hepatic uptake in humans, with a liver/plasma ratioof 36.4, based on autopsy studies (von Moltke et al., 1998). Thus,although a basic tenet of the widely used liver models for predictionof pharmacokinetic clearance is that free drug concentrationsin plasma are in equilibrium with hepatocyte concentrations, thismay not be true for drugs that are actively taken up and/or concentratedin the liver (Thummel et al., 1997). The clearance of lipophilicdrugs such as amitriptyline, diphenhydramine, and diltiazem hasbeen underpredicted in previous in vitro-in vivo scaling studiesusing human liver microsomes (Obach, 1999). Thus, the existingliver models may not adequately describe the relationship betweenin vitro intrinsic clearance and hepatic drug clearance in vivo,and the assumption that unbound plasma drug concentrations arereflective of hepatic enzyme-available concentrations is not generallyvalid.

The relative contribution of a CYP isoform to the overall rate of a multienzyme drug biotransformation pathway is a functionof substrate concentration. CYP2C19 appears to be the major determinantof amitriptyline N-demethylation at therapeutically relevant drugconcentrations, with added contributions of CYPs 2C8, 2C9, 1A2,and 2D6, whereas the contributions of CYPs 2B6 and 3A4 are predictedto be negligible (Table 3). However, at high substrate concentrations,the importance of CYP3A4 increases owing to its high hepatic abundanceand sigmoidal kinetics. With E-10 hydroxylation, CYP2D6 is predictedto be the major catalyst at therapeutically relevant concentrations.However, CYPs 2B6 and 3A4 assume greater importance at highersubstrate concentrations (Table 3). Thus, the mechanism of amitriptylinedisposition after a therapeutic dose is likely to be differentfrom that after a toxicoverdose.

The predicted substrate concentration-dependent differences in relative contributions of CYPs 2C19 and 3A4 to amitriptylineN-demethylation are confirmed by the results of inhibition studies.Inhibition by the CYP2C19 inhibitors omeprazole and S-mephenytoinwas greater at a substrate concentration of 1.5 µM compared withthat observed at 15 µM, whereas the reverse was true for the CYP3A4inhibitors TAO and ketoconazole (Table 4). These findings emphasizethe importance of selecting low therapeutically relevant substrateconcentrations in inhibitionstudies.

In general, good correlations were observed between the extent of inhibition of amitriptyline N-demethylation or E-10 hydroxylationby an isoform-specific inhibitor and the RAF model-predicted relativecontribution of the target CYP isoform (Figs. 5-7). The scatterplots in Figs. 5 through 7 reveal some interesting propertiesof the inhibitors used in this study. Figures 5C and 6C examinethe association of the model-predicted relative contribution ofCYP2C19 with the extent of inhibition by 10 µM omeprazole. Althougha significant positive association was noted, suggesting the inhibitionof CYP2C19 by this inhibitor, a statistically significant positiveintercept of the regression line was also noted, suggesting thelack of complete specificity of omeprazole toward CYP2C19. Inthe CYP2C19-deficient livers L11 and L12, omeprazole produced25% inhibition of amitriptyline N-demethylation. This may be explainedby the inhibition of CYPs 1A2 and 2C9 by omeprazole (Fig. 4).

Even S-mephenytoin, a selective CYP2C19 substrate, inhibited lymphoblast-expressed CYP1A2 and 2C9-catalyzed amitriptylineN-demethylation (Fig. 4). Although we measured inhibition by S-mephenytoinwith CYPs 1A2 and 2C9 inhibited, this approach did not completelyeliminate nonspecific inhibition, as is reflected by the nonzeroy-intercept in Figs. 5D and 6D, and the approximately 20% inhibitionof amitriptyline N-demethylation by livers L11 and L12. Contraryto our current findings, no nonspecific effects of S-mephenytoinwere noted in human liver microsomes up to a concentration of750 µM with imipramine as the substrate (Koyama et al., 1997).These data suggest that the effects of chemical inhibitors maybe substrate-dependent.

The incomplete specificity of quinidine toward CYP2D6 at a concentration of 5 µM is demonstrated in Fig. 7, A and C. In liverL8 lacking CYP2D6, quinidine inhibited amitriptyline E-10 hydroxylationby 40 and 25% at substrate concentrations of 1.5 and 15 µM, respectively.In this liver, CYP3A4 should account for a major fraction of thehydroxylation rate. The substrate concentrations used are muchlower than the CYP3A4 K_m of 69 µM for amitriptyline E-10 hydroxylation.Thus, quinidine, an alternative substrate of CYP3A4 (Nielsen etal., 1999), is expected to inhibit the CYP3A4 component of amitriptylineE-10 hydroxylation. In fact, amitriptyline E-10 hydroxylationand N-demethylation catalyzed by lymphoblast-expressed CYP3A4were both inhibited by 30 to 40% by 5 µM quinidine at 10 µM amitriptyline.Thus, there is no absolute window of selectivity for a competitiveinhibitor, and the extent of nonspecific inhibition will dependon the inhibitor concentration in relation to the K_m of the nontargetCYP(s).

Ketoconazole is a selective CYP3A4 inhibitor at concentrations less than 5 µM based on its effects on index reactions at theirK_m values (Newton et al., 1995). At 1.5 µM amitriptyline, thespecificity of ketoconazole may be questionable, explaining theoverprediction of the CYP3A4 contribution to overall metabolicrate (Fig. 8), and the large y-intercept in Figs. 5G and 6G. Infact, at a low substrate concentration of 5 µM, ketoconazole (2.5µM) significantly inhibited amitriptyline N-demethylation by lymphoblast-expressedCYPs 2C8, 2C9, and 2C19. Although less evident, even with TAO,the extent of inhibition was greater than the model-predictedrelative contribution of CYP3A4 in some livers (Figs. 5F and 6F).The reason for this discrepancy is not clear and may be relatedto the sigmoidicity in CYP3A4kinetics.

With the exception of ketoconazole, Fig. 8 suggests that the methods of chemical inhibition and the RAF approach using cDNA-expressedCYPs yield comparable estimates of the relative contributionsof individual CYP isoforms to the rate of amitriptyline biotransformationvia N-demethylation and E-10 hydroxylation. Another widely usedmethod in reaction phenotyping is the use of selective antibodyinhibitors of specific CYP isoforms (Shou et al., 2000). Whendesigned carefully, inhibitory antibodies are often much moreselective than chemical inhibitors, although selective inhibitoryantibodies of CYP2C19 were not commercially available when thisstudy was performed. A combination of the complementary approachesof selective enzyme inhibition and the use of heterologously expressedCYPs should be a useful approach to reaction phenotyping and shouldprovide important information for the prediction of drug interactionswith inhibitors or inducers of specific CYP isoforms. The advantagesand pitfalls associated with both approaches need to be recognizedin interpreting experimental data and in the inference of a reactionphenotype.

	Footnotes

Accepted for publication January 3, 2001.

Received for publication September 14, 2000.

This work was supported by Grants MH-34223, DA-05258, DA-13209, MH-19924, MH-58435, GM-61834, and RR-00054 from the Departmentof Health and Human Services. L.L.v.M. was the recipient of aScientist Development Award (K21-MH-01237) from the National Instituteof MentalHealth.

Send reprint requests to: David J. Greenblatt, M.D., Department of Pharmacology and Experimental Therapeutics, Tufts University School of Medicine, 136 Harrison Ave., Boston, MA 02111. E-mail: Dj.Greenblatt{at}tufts.edu

	Abbreviations

CYP, cytochrome P450; RAF, relative activity factor; cDNA, complementary DNA; TAO, troleandomycin; FDV, fractional decrement of reaction velocity.

	References

Top Abstract Introduction Experimental Procedures Results Discussion References

Bourrié M, Meunier V, Berger Y and Fabre G (1996) Cytochrome P450 isoform inhibitors as a tool for the investigation of metabolic reactions catalyzed by human liver microsomes. J Pharmacol Exp Ther 277: 321-332[Abstract/Free Full Text].
Carlile DJ, Hakooz N, Bayliss MK and Houston JB (1999) Microsomal prediction of in vivo clearance of CYP2C9 substrates in humans. Br J Clin Pharmacol 47: 625-635[Medline].
Clarke SE (1998) In vitro assessment of human cytochrome P450. Xenobiotica 28: 1167-1202[Medline].
Crespi CL (1995) Xenobiotic-metabolizing human cells as tools for pharmacological and toxicological research. Adv Drug Res 26: 179-235.
Crespi CL and Miller VP (1999) The use of heterologously expressed drug metabolizing enzymes $---$ state of the art and prospects for the future. Pharmacol Ther 84: 121-131[Medline].
Crespi CL and Penman BW (1997) Use of cDNA-expressed human cytochrome P450 enzymes to study potential drug-drug interactions. Adv Pharmacol 43: 171-188.
Houston JB (1994) Utility of in vitro drug metabolism data in predicting in vivo metabolic clearance. Biochem Pharmacol 47: 1469-1479[Medline].
Houston JB and Kenworthy KE (2000) In vitro-in vivo scaling of CYP kinetic data not consistent with the classical Michaelis-Menten model. Drug Metab Dispos 28: 246-254[Abstract/Free Full Text].
Huang Z, Roy P and Waxman DJ (2000) Role of human liver microsomal CYP3A4 and CYP2B6 in catalyzing N-dechloroethylation of cyclophosphamide and ifosfamide. Biochem Pharmacol 59: 961-972[Medline].
Ito K, Iwatsubo T, Kanamitsu S, Nakajima Y and Sugiyama Y (1998) Quantitative prediction of in vivo drug clearance and drug interactions from in vitro data on metabolism, together with binding and transport. Annu Rev Pharmacol Toxicol 38: 461-499[Medline].
Ko J-W, Sukhova N, Thacker D, Chen P and Flockhart DA (1997) Evaluation of omeprazole and lansoprazole as inhibitors of cytochrome P450 isoforms. Drug Metab Dispos 25: 853-862[Abstract/Free Full Text].
Koyama E, Chiba K, Tani M and Ishizaki T (1997) Reappraisal of human CYP isoforms involved in imipramine N-demethylation and 2-hydroxylation: A study using microsomes obtained from putative extensive and poor metabolizers of S-mephenytoin and eleven recombinant human CYPs. J Pharmacol Exp Ther 281: 1199-1210[Abstract/Free Full Text].
McLure JA, Miners JO and Birkett DJ (2000) Nonspecific binding of drugs to human liver microsomes. Br J Clin Pharmacol 49: 453-461[Medline].
Mellström B, Bertilsson L, Lou Y-C, Säwe J and Sjökvist F (1983) Amitriptyline metabolism: Relationship to polymorphic debrisoquine hydroxylation. Clin Pharmacol Ther 34: 516-520[Medline].
Mellström B, Säwe J, Bertilsson L and Sjökvist F (1986) Amitriptyline metabolism: Association with debrisoquin hydroxylation in nonsmokers. Clin Pharmacol Ther 39: 369-371[Medline].
Newton DJ, Wang RW and Lu AYH (1995) Cytochrome P450 inhibitors: Evaluation of specificities in the in vitro metabolism of therapeutic agents by human liver microsomes. Drug Metab Dispos 23: 154-158[Abstract].
Nielsen TL, Rasmussen BB, Flinois J-P, Beaune P and Brøsen K (1999) In vitro metabolism of quinidine: The (3S)-3-hydroxylation of quinidine is a specific marker reaction for cytochrome P-4503A4 activity in human liver microsomes. J Pharmacol Exp Ther 289: 31-37[Abstract/Free Full Text].
Obach RS (1999) The prediction of human clearance of twenty-nine drugs from hepatic microsomal intrinsic clearance data: An examination of the in vitro half-life approach and nonspecific binding to microsomes. Drug Metab Dispos 27: 1350-1359[Abstract/Free Full Text].
Obach RS, Baxter JG, Liston TE, Silber BM, Jones BC, MacIntyre F, Rance DJ and Wastall P (1997) The prediction of human pharmacokinetic parameters from preclinical and in vitro metabolism data. J Pharmacol Exp Ther 283: 46-58[Abstract/Free Full Text].
Ono S, Hatanaka T, Hotta H, Satoh T, Gonzalez FJ and Tsutsui M (1996) Specificity of substrate and inhibitor probes for cytochrome P450s: Evaluation of in vitro metabolism using cDNA-expressed human P450s and human liver microsomes. Xenobiotica 26: 681-693[Medline].
Rodrigues AD (1999) Integrated cytochrome P450 reaction phenotyping: Attempting to bridge the gap between cDNA-expressed cytochromes P450 and native human liver microsomes. Biochem Pharmacol 57: 465-480[Medline].
Rollins DE, Alvan G, Bertilsson L, Gillette JR, Mellström B, Sjökvist F and Träskman L (1980) Interindividual differences in amitriptyline demethylation. Clin Pharmacol Ther 28: 121-128[Medline].
Roy P, Yu LJ, Crespi CL and Waxman DJ (1999) Development of a substrate-activity based approach to identify the major human liver P-450 catalysts of cyclophosphamide and ifosfamide activation based on cDNA-expressed activities and liver microsomal P-450 profiles. Drug Metab Dispos 27: 655-666[Abstract/Free Full Text].
Schmider J, Greenblatt DJ, Harmatz JS and Shader RI (1996) Enzyme kinetic modeling as a tool to analyse the behaviour of cytochrome P450 catalysed reactions: Application to amitriptyline N-demethylation. Br J Clin Pharmacol 41: 593-604[Medline].
Schmider J, Greenblatt DJ, von Moltke LL, Harmatz JS and Shader RI (1995) N-demethylation of amitriptyline in vitro: Role of cytochrome P-450 3A (CYP3A) isoforms, and effect of metabolic inhibitors. J Pharmacol Exp Ther 275: 592-597[Abstract/Free Full Text].
Schulz P, Dick P, Blaschke TF and Hollister L (1985) Discrepancies between pharmacokinetic studies of amitriptyline. Clin Pharmacokinet 10: 257-268[Medline].
Shimada T, Tsumura F and Yamazaki H (1999) Prediction of human liver microsomal oxidations of 7-ethoxycoumarin and chlorzoxazone with kinetic parameters of recombinant cytochrome P-450 enzymes. Drug Metab Dispos 27: 1274-1280[Abstract/Free Full Text].
Shou M, Lu T, Krausz KW, Sai Y, Yang T, Korzekwa KR, Gonzalez FJ and Gelboin HV (2000) Use of inhibitory monoclonal antibodies to assess the contribution of cytochromes P450 to human drug metabolism. Eur J Pharmacol 394: 199-209[Medline].
Störmer E, von Moltke LL and Greenblatt DJ (2000) Scaling drug biotransformation data cDNA-expressed CYP to human liver: A comparison of relative activity factors and human liver abundance in studies of mirtazapine metabolism. J Pharmacol Exp Ther 295: 793-801[Abstract/Free Full Text].
Thummel KE, Kunze KL and Shen DD (1997) Enzyme-catalyzed processes of first-pass hepatic and intestinal drug extraction. Adv Drug Deliv Rev 27: 99-127[Medline].
Venkatakrishnan K, Greenblatt DJ, von Moltke LL, Schmider J, Harmatz JS and Shader RI (1998a) Five distinct human cytochromes mediate amitriptyline N-demethylation in vitro: Dominance of CYP 2C19 and 3A4. J Clin Pharmacol 38: 112-121[Abstract].
Venkatakrishnan K, von Moltke LL, Court MH, Harmatz JS, Crespi CL and Greenblatt DJ (2000a) Comparison between CYP content and relative activity approaches to scaling from cDNA-expressed cytochromes P450 to human liver microsomes: Ratios of accessory proteins as sources of discrepancies between the approaches. Drug Metab Dispos 28: 1493-1504[Abstract/Free Full Text].
Venkatakrishnan K, von Moltke LL and Greenblatt DJ (1998b) Relative quantities of catalytically active CYP 2C9 and 2C19 in human liver microsomes: Application of the relative activity factor approach. J Pharm Sci 87: 845-853[Medline].
Venkatakrishnan K, von Moltke LL and Greenblatt DJ (1999) Nortriptyline E-10-hydroxylation in vitro is mediated by human CYP2D6 (high affinity) and CYP3A4 (low-affinity): Implications for interactions with enzyme-inducing drugs. J Clin Pharmacol 39: 567-577[Abstract].
Venkatakrishnan K, von Moltke LL, Obach RS and Greenblatt DJ (2000b) Microsomal binding of amitriptyline: Effect on estimation of enzyme kinetic parameters in vitro. J Pharmacol Exp Ther 293: 343-350[Abstract/Free Full Text].
von Moltke LL, Greenblatt DJ, Cotreau-Bibbo MM, Duan SX, Harmatz JS and Shader RI (1994) 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. J Pharmacol Exp Ther 268: 1278-1283[Abstract/Free Full Text].
von Moltke LL, Greenblatt DJ, Harmatz JS and Shader RI (1993) Alprazolam metabolism in vitro: Studies of human, monkey, mouse, and rat liver microsomes. Pharmacology 47: 268-276[Medline].
von Moltke LL, Greenblatt DJ, Schmider J, Wright CE, Harmatz JS and Shader RI (1998) In vitro approaches to predicting drug interactions in vivo. Biochem Pharmacol 55: 113-122[Medline].
Yamazaki H, Inoue K, Shaw PM, Checovich WJ, Guengerich FP and Shimada T (1997) Different contributions of cytochrome P450 2C19 and 3A4 in the oxidation of omeprazole by human liver microsomes: Effects of contents of these two forms in individual human samples. J Pharmacol Exp Ther 283: 434-442[Abstract/Free Full Text].

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