Effect of voriconazole on the pharmacokinetics and pharmacodynamics of intravenous and oral midazolam

OBJECTIVE: Our objective was to assess the effect of the antimycotic voriconazole on the pharmacokinetics and pharmacodynamics of oral and intravenous midazolam. METHODS: We used a randomized, crossover study design. Ten healthy male volunteers were given either no pretreatment (control phase) or voriconazole (voriconazole phase) orally, 400 mg twice daily on the first day and 200 mg twice daily on the second day. Midazolam was given, either 0.05 mg/kg intravenously or 7.5 mg orally, 1 hour after the last dose of voriconazole and during the control phase. Plasma concentrations of midazolam, alpha-hydroxymidazolam, and voriconazole were determined for 24 hours and pharmacodynamic variables measured for 12 hours. RESULTS: Voriconazole reduced the clearance of intravenous midazolam by 72% (P < .001) and increased its elimination half-life from 2.8 to 8.3 hours (P < .001). Voriconazole increased the peak concentration and the area under the plasma concentration-time curve of oral midazolam by 3.8- and 10.3-fold, respectively (P < .001). The bioavailability of oral midazolam was increased from 31% to 84% (P < .001). Voriconazole profoundly increased the psychomotor effects of oral midazolam (P < .001) but only weakly increased the effects of intravenous midazolam. CONCLUSION: When midazolam is given as small intravenous bolus doses, its effect is not increased to a clinically significant degree by voriconazole. The use of large midazolam doses increases the risk of clinically significant interactions also after its intravenous administration. The use of oral midazolam with voriconazole should be avoided, or substantially lower doses should be used.     

Differentiation of intestinal and hepatic cytochrome P450 3A activity with use of midazolam as an in vivo probe: effect of ketoconazole

BACKGROUND: The cytochrome P450 3A (CYP3A) isoforms are responsible for the metabolism of a majority of therapeutic compounds, and they are abundant in the intestine and liver. CYP3A activity is highly variable, causing difficulty in the therapeutic use of CYP3A substrates. A practical in vivo probe method that characterizes both intestinal and hepatic CYP3A activity would be useful. OBJECTIVES: To determine the intestinal and hepatic contribution to the bioavailability of midazolam with use of the CYP3A inhibitor ketoconazole. METHODS: The pharmacokinetics of midazolam was assessed in nine (six men and three women) healthy individuals after single doses of 2 mg intravenous and 6 mg oral midazolam (phase I). These pharmacokinetic values were compared with those obtained after single doses of 2 mg intravenous and 6 mg oral midazolam and three doses of 200 mg oral ketoconazole (phase II). RESULTS: After ketoconazole therapy, area under the concentration versus time curve of midazolam increased 5-fold after intravenous midazolam administration (P < or = .001) and 16-fold after oral midazolam administration (P < or = .001). Intrinsic clearance decreased by 84% (P = .003). Total bioavailability increased from 25% to 80% (P < .001). The intestinal component of midazolam bioavailability increased to a greater extent than the hepatic component (2.3-fold [P = .003] and 1.5-fold [P < or = .001], respectively). In the control phase, female subjects had greater midazolam clearance values than the male subjects. CONCLUSIONS: Ketoconazole caused marked inhibition of CYP3A activity that was greater in the intestine than the liver. Administration of single doses of oral and intravenous midazolam with and without oral ketoconazole exemplifies a practical method for differentiating intestinal and hepatic CYP3A activity.     

The cytochrome P450 3A4 inhibitor itraconazole markedly increases the plasma concentrations of dexamethasone and enhances its adrenal-suppressant effect

OBJECTIVE: To examine the possible interaction of itraconazole with orally and intravenously administered dexamethasone. METHODS: In a randomized, double-blind, placebo-controlled crossover study with four phases, eight healthy subjects took either 200 mg itraconazole (in two phases) or placebo (in two phases) orally once daily for 4 days. On day 4 each subject received an oral dose of 4.5 mg dexamethasone or an intravenous dose of 5.0 mg dexamethasone sodium phosphate during both itraconazole and placebo phases. Plasma dexamethasone and cortisol concentrations were determined by HPLC up to 71 hours, itraconazole and hydroxyitraconazole up to 23 hours. RESULTS: Itraconazole decreased the systemic clearance of intravenously administered dexamethasone by 68% (P < .001), increased the total area under the plasma dexamethasone concentration-time curve [AUC(0-infinity)] 3.3-fold (P < .001), and prolonged the elimination half-life of dexamethasone 3.2-fold (P < .001). The AUC(0-infinity) of oral dexamethasone was increased 3.7-fold (P < .001), the peak plasma concentration 1.7-fold (P < .001), and the elimination half-life 2.8-fold (P < .001) by itraconazole. The morning plasma cortisol concentrations measured 47 and 71 hours after administration of dexamethasone were substantially lower after exposure to itraconazole than to placebo (P < .001). Accordingly, the adrenal-suppressant effect of dexamethasone was greatly enhanced during the itraconazole phases. CONCLUSIONS: Itraconazole markedly increases the systemic exposure to and effects of dexamethasone. A careful follow-up is recommended when itraconazole or other potent inhibitors of the cytochrome P450 3A4 are added to the drug regimen of patients receiving dexamethasone.     

Cisapride: a potential model substrate to assess cytochrome P4503A4 activity in vivo

OBJECTIVES: Cisapride was compared with midazolam in vivo to determine its potential applicability as a cytochrome P450 (CYP) 3A4 "probe." As well, we evaluated whether cisapride was transported by P-glycoprotein. METHODS: Bidirectional transport assays were conducted in LLC-PK1 cells and the derivative cell line L-MDR1 to determine whether cisapride was a substrate for P-glycoprotein. A pharmacokinetic study was also conducted in 17 healthy adults (n = 8 women) who received intravenous midazolam (0.025 mg/kg), oral midazolam (0.15 mg/kg), and oral cisapride (0.07 mg/kg) in a randomized crossover design. Plasma concentrations were quantitated from repeated after-dosing blood samples by HPLC with ultraviolet detection for midazolam and HPLC with tandem mass spectrometry detection for cisapride and norcisapride. Pharmacokinetic parameters were determined by noncompartmental methods. Both linear and nonlinear regression analyses were used to examine the association between the apparent plasma clearance of midazolam and cisapride and the cisapride/norcisapride plasma concentration ratios. RESULTS: Although not a substrate for P-glycoprotein, cisapride inhibited P-glycoprotein with an apparent inhibition constant (K(i)) of 16.1 micromol/L. Linear correlations between cisapride clearance and both intravenous and oral midazolam clearance (P =.01, r(2) = 0.43 and P =.001, r(2) = 0.46, respectively) were found. Cisapride/norcisapride plasma concentration ratios at 8 hours (P =.001, r(2) = 0.90) and 12 hours (P =.001, r(2) = 0.96), as well as cisapride plasma concentrations at these time points, were shown to accurately predict the area under the plasma concentration versus time curve for cisapride. CONCLUSIONS: CYP3A4 activity reflected by the total body clearance after oral administration of cisapride should be independent of transport by P-glycoprotein. Concordance between the pharmacokinetics for cisapride and midazolam support the applicability of oral cisapride as a pharmacologic substrate to assess total CYP3A4 activity in vivo. Cisapride plasma concentration ratios at 8 or 12 hours after a single oral cisapride dose may prove useful as a single-point determination to reflect the area under the plasma concentration versus time curve and the plasma clearance of cisapride and, as well, total CYP3A4 activity in vivo.     

Pharmacokinetics and pharmacodynamics of saquinavir in pediatric patients with human immunodeficiency virus infection

OBJECTIVE: Our objective was to investigate the clinical pharmacologic characteristics of saquinavir given as a soft gelatin capsule, either alone or in combination with nelfinavir, to children and adolescents with human immunodeficiency virus infection. METHODS: The pharmacokinetics of 50 mg/kg saquinavir 3 times a day (tid) alone versus 33 mg/kg saquinavir tid plus 30 mg/kg nelfinavir tid was assessed after single-dose administration and after short- and long-term administration. The single-dose pharmacokinetics of fixed (1200 mg) versus unrestricted weight-adjusted dosing (50 mg/kg) was also investigated. RESULTS: Saquinavir as the sole protease inhibitor resulted in lower saquinavir exposure in children (steady-state geometric mean area under the concentration-time curve from time zero to 24 hours [AUC (0-24 h)], 5790 ng x h/ml; steady-state concentration 8 hours after drug administration [C(8h,SS)], 65 ng/ml) and adolescents [steady-state geometric mean AUC(0-24 h), 5914 ng x h/ml] than that reported in adults treated with 1200 mg tid [steady-state geometric mean AUC(0-24 h), 21,700 ng x h/ml; C(8h,SS), 223 ng/ml]. This finding appeared to be attributable to markedly higher apparent oral clearance, potentially as a result of increased systemic clearance and reduced oral bioavailability. Nelfinavir combined with saquinavir reduced apparent oral clearance, increasing saquinavir exposure in children [steady-state geometric mean AUC(0-24 h), 11,070 ng x h/ml; C(8h,SS), 380 ng/ml] to levels that approach those observed in adults. A significant correlation between average trough concentration and sustained viral load suppression was observed in children. The apparent threshold for maintaining viral load suppression was a mean trough saquinavir concentration above 200 ng/ml. CONCLUSIONS: The pharmacokinetics of saquinavir in children is different from that of adults, and administration of saquinavir alone will not give consistently efficacious plasma levels. The best way of improving saquinavir exposure in children is through combination therapy with other protease inhibitors that inhibit saquinavir metabolism.     

Effects of aprepitant on cytochrome P450 3A4 activity using midazolam as a probe

BACKGROUND: Aprepitant is a neurokinin(1) receptor antagonist that enhances prevention of chemotherapy-induced nausea and vomiting when added to conventional therapy with a corticosteroid and a 5-hydroxytryptamine(3) (5-HT(3)) antagonist. Because aprepitant may be used with a variety of chemotherapeutic agents and ancillary support drugs, which may be substrates of cytochrome P450 (CYP) 3A4, assessment of the potential of this drug to inhibit CYP3A4 activity in vivo is important. The effect of aprepitant on in vivo CYP3A4 activity in humans with oral midazolam used as a sensitive probe of CYP3A4 activity was evaluated in this study. METHODS: In this open-label, randomized, single-period study, 16 healthy male subjects were enrolled. Subjects received one of two oral aprepitant regimens for 5 days (8 subjects per regimen): (1) 125 mg aprepitant on day 1 and then 80 mg/d on days 2 to 5 or (2) 40 mg aprepitant on day 1 and then 25 mg/d on days 2 to 5. All subjects also received a single oral dose of midazolam, 2 mg, at prestudy (3 to 7 days before aprepitant treatment) and on days 1 and 5 (1 hour after aprepitant administration). RESULTS: Coadministration of midazolam and 125/80 mg aprepitant increased the midazolam area under the plasma concentration-time curve by 2.3-fold on day 1 (P <.01) and by 3.3-fold on day 5 (P <.01), as compared with midazolam alone (prestudy). The 125/80-mg regimen of aprepitant also increased the midazolam maximum observed concentration by 1.5-fold on day 1 (P <.05) and by 1.9-fold on day 5 (P <.01). The midazolam half-life values increased from 1.7 hours (prestudy) to 3.3 hours on both day 1 and day 5. Coadministration of 40/25 mg aprepitant and midazolam did not result in significant changes in the midazolam area under the plasma concentration-time curve, maximum observed concentration, and half-life at either day 1 or day 5. CONCLUSIONS: The 5-day 125/80-mg regimen of aprepitant produced moderate inhibition of CYP3A4 activity in humans, as measured with the use of midazolam as a probe drug.     

Drug-Drug Interaction Study of Ketoconazole and Ritonavir-Boosted Saquinavir

Saquinavir, a potent human immunodeficiency virus protease inhibitor, is extensively metabolized by CYP3A4. Saquinavir is coadministered with ritonavir, a strong CYP3A4 inhibitor, to boost its exposure. Ketoconazole is a potent CYP3A inhibitor. The objectives of this study were to investigate the effect of ketoconazole on the pharmacokinetics of saquinavir/ritonavir and vice versa using the approved dosage regimens of saquinavir/ritonavir at 1,000/100 mg twice daily and ketoconazole at 200 mg once daily. This was an open-label, randomized two-arm, one-sequence, two-period crossover study in healthy subjects. In study arm 1, 20 subjects received saquinavir/ritonavir treatment alone for 14 days, followed in combination with ketoconazole treatment for 14 days. In arm 2, 12 subjects received ketoconazole treatment for 6 days, followed in combination with saquinavir/ritonavir treatment for 14 days. The pharmacokinetics were assessed on the last day of each treatment (days 14 and 28 in arm 1 and days 6 and 20 in arm 2). The exposures C_max and the area under the concentration-time curve from 0 to 12 h (AUC_0-12) of saquinavir and ritonavir with or without ketoconazole were not substantially altered after 2 weeks of concomitant dosing with ketoconazole. The C_max and AUC_0-12 of ketoconazole, dosed at 200 mg once daily, were increased by 45% (90% confidence interval = 32 to 59%) and 168% (90% confidence interval = 146 to 193%), respectively, after 2 weeks of concomitant dosing with ritonavir-boosted saquinavir (1,000 mg of saquinavir/100 mg of ritonavir given twice daily). The greater exposure to ketoconazole when given in combination with saquinavir/ritonavir was not associated with unacceptable safety or tolerability. No dose adjustment for saquinavir/ritonavir (1,000/100 mg twice daily) is required when coadministered with 200 mg of ketoconazole once daily, and high doses of ketoconazole (>200 mg/day) are not recommended.     

The interaction between St John's wort and an oral contraceptive

OBJECTIVES: The popular herbal remedy St John's wort is an inducer of cytochrome P450 (CYP) 3A enzymes and may reduce the efficacy of oral contraceptives. Therefore we evaluated the effect of St John's wort on the disposition and efficacy of Ortho-Novum 1/35 (Ortho-McNeil Pharmaceutical, Inc, Raritan, NJ), a popular combination oral contraceptive pill containing ethinyl estradiol (INN, ethinylestradiol) and norethindrone (INN, norethisterone). METHODS: Twelve healthy premenopausal women who were using oral contraception (>3 months) received a combination oral contraceptive pill (Ortho-Novum 1/35) for 3 consecutive 28-day menstrual cycles. During the second and third cycles, the participants received 300 mg St John's wort 3 times a day. The serum concentrations of ethinyl estradiol (day 7), norethindrone (day 7), follicle-stimulating hormone (days 12-16), luteinizing hormone (days 12-16), progesterone (day 21), and intravenous and oral midazolam (days 22 and 23) were determined in serial blood samples. The incidence of breakthrough bleeding was quantified during the first and third cycles. RESULTS: Concomitant use of St John's wort was associated with a significant (P <.05) increase in the oral clearance of norethindrone (8.2 +/- 2.7 L/h to 9.5 +/- 3.4 L/h, P =.042) and a significant reduction in the half-life of ethinyl estradiol (23.4 +/- 19.5 hours to 12.2 +/- 7.1 hours, P =.023). The oral clearance of midazolam was significantly increased (109.2 +/- 47.9 L/h to 166.7 +/- 81.3 L/h, P =.007) during St John's wort administration, but the systemic clearance of midazolam was unchanged (37.7 +/- 11.3 L/h to 39.0 +/- 10.3 L/h, P =.567). Serum concentrations of follicle-stimulating hormone, luteinizing hormone, and progesterone were not significantly affected by St John's wort dosing (P >.05). Breakthrough bleeding occurred in 2 of 12 women in the control phase compared with 7 of 12 women in the St John's wort phase. The oral clearance of midazolam after St John's wort dosing was greater in women who had breakthrough bleeding (215.9 +/- 66.5 L/h) than in those who did not (97.5 +/- 37.2 L/h) (P =.005). CONCLUSION: St John's wort causes an induction of ethinyl estradiol-norethindrone metabolism consistent with increased CYP3A activity. Women taking oral contraceptive pills should be counseled to expect breakthrough bleeding and should consider adding a barrier method of contraception when consuming St Johns wort.     

Pharmacokinetics and pharmacodynamics of dichloroacetate in patients with cirrhosis.

OBJECTIVES: We tested the hypotheses that (1) plasma clearance of dichloroacetate is decreased in patients with end-stage cirrhosis, and (2) patients with cirrhosis are vulnerable to dichloroacetate-induced hypoglycemia caused by exaggerated inhibition of hepatic glucose production. METHODS: Seven subjects with cirrhosis and six healthy volunteers received a 5-hour primed constant infusion of 6,6-2H2-glucose. After a 2-hour basal period, subjects received intravenous dichloroacetate, 35 mg/kg, over 30 minutes. Dichloroacetate pharmacokinetics were compared by the mixed-effects population-based technique. Glucose production was calculated by means of isotope dilution. RESULTS: The optimal dichloroacetate pharmacokinetic model for both subjects with cirrhosis and control subjects had two compartments, with all parameters weight normalized. Peak plasma dichloroacetate concentration in subjects with cirrhosis did not differ from that in control subjects, but typical dichloroacetate clearance was only 36% of that in control subjects (P < .001). Dichloroacetate decreased plasma lactate concentration by approximately 50% (P < .001), glucose production by 7% to 9% (P < .05), and plasma glucose concentration by 9% to 14% (P < .05) in both subjects with cirrhosis and control subjects. Dichloroacetate-induced decreases in plasma lactate and glucose concentrations and in glucose production in subjects with cirrhosis did not differ from those in control subjects. CONCLUSIONS: Plasma dichloroacetate clearance is markedly decreased in patients with cirrhosis, likely because of compromised hepatic function. Subjects with cirrhosis exhibit neither exaggerated inhibition of glucose production nor increased risk of hypoglycemia as a result of acute dichloroacetate-induced hypolactatemia.     

Single-point sampling for assessment of constitutive, induced, and inhibited cytochrome P450 3A activity with alfentanil or midazolam

INTRODUCTION: The clearances of oral and intravenous alfentanil are in vivo probes for assessing first-pass and hepatic cytochrome P450 (CYP) 3A activity. Clearance determinations require time-consuming and expensive serial blood samples and quantitative analysis. This investigation tested the hypothesis that a single concentration measurement can accurately predict alfentanil clearance and compared limited sampling results for alfentanil and midazolam. METHODS: Data were analyzed from 2 previous studies in healthy volunteers (n = 10 in each). By use of a dose-finding protocol, subjects received oral alfentanil (23, 30, 43, or 75 microg/kg). By use of a CYP3A modulation protocol, subjects received oral or intravenous alfentanil and midazolam after pretreatment with rifampin (INN, rifampicin) (CYP3A induction), troleandomycin (CYP3A inhibition), grapefruit juice (intestinal CYP3A inhibition), or nothing (control). Alfentanil and midazolam area under the concentration-time curve (AUC) was calculated by noncompartmental analysis. Correlations between AUC and plasma concentration at each time point were evaluated by unweighted and weighted (1/y, 1/y(2)) linear regression, and the optimal weight and sampling time were determined. RESULTS: Correlations between AUC and plasma concentration were best with 1/y(2) weights. Optimal correlations were at 1.5 to 2 hours for each alfentanil dose and also in an all-dose composite analysis. With the CYP3A modulation protocol, correlations for the control, grapefruit juice, rifampin, and troleandomycin sessions were optimal at 2, 3, 1.5, and 12 hours, respectively, for oral alfentanil, at 2, 3, 0.5, and 9 hours, respectively, for intravenous alfentanil, at 5, 5, 1.5, and 13 hours, respectively, for oral midazolam, and at 3, 1.75, 1, and 13 hours, respectively, for intravenous midazolam. In a composite analysis of all treatments, correlations (oral and intravenous) were optimal at 4 to 5 hours for alfentanil and 5 to 6 hours for midazolam. AUC estimated by a single-point concentration was highly predictive of measured AUC (r(2) = 0.91 and 0.93 for oral and intravenous alfentanil, respectively, and r(2) = 0.90 and 0.87 for oral and intravenous midazolam, respectively). CYP3A induction or inhibition was detected equally well by single-point alfentanil concentrations and by formal AUC determinations. CONCLUSION: A single plasma concentration can predict alfentanil AUC and hence clearance, independent of dose, and thus appears to be an effective and efficient strategy for assessing CYP3A modulation over a broad spectrum of enzyme activity.     

The comparative effects of verapamil and a new dihydropyridine calcium channel blocker on digoxin pharmacokinetics

Conflicting conclusions have been reported about interaction of calcium channel blockers with digoxin. The effects of verapamil (240 mg/day) and a new dihydropyridine calcium channel blocker, isradipine (15 mg/day), on the pharmacokinetics of 1 mg intravenous digoxin were compared. All 24 volunteer subjects were healthy, male, nonobese, and aged 18 to 38 years. Groups of 12 subjects received each oral agent over 15 days, with collections of blood and urine for 72 hours after intravenous digoxin. Significant (P less than 0.05) reduction in nonrenal (7.01 +/- 1.97 to 4.00 +/- 1.86 L/hr) and total clearance (14.1 +/- 2.6 to 11.5 +/- 2.5 L/hr) were induced by verapamil, without change in renal clearance. A near-significant (P less than 0.1) increase in peripheral volume of distribution contributed to prolonged elimination half-life (23.1 +/- 4.4 to 34.3 +/- 9.7 hours). By contrast, isradipine caused only a 9% reduction in volume of distribution. Verapamil causes digoxin accumulation by reducing nonrenal elimination. No evidence of clinically relevant interaction of isradipine with digoxin was seen.     

The effect of rifampin on the pharmacokinetics of oral and intravenous ondansetron

BACKGROUND: Ondansetron is an antiemetic agent metabolized by cytochrome P450 (CYP) enzymes. Rifampin (INN, rifampicin) is a potent inducer of CYP3A4 and some other CYP enzymes. We examined the possible effect of rifampin on the pharmacokinetics of orally and intravenously administered ondansetron. METHODS: In a randomized crossover study with 4 phases and a washout of 4 weeks, 10 healthy volunteers took either 600 mg rifampin (in 2 phases) or placebo (in 2 phases) once a day for 5 days. On day 6, 8 mg ondansetron was administered either orally (after rifampin and placebo) or intravenously (after rifampin and placebo). Ondansetron concentrations in plasma were measured up to 12 hours. RESULTS: The mean total area under the plasma concentration-time curve [AUC(0-infinity)] of orally administered ondansetron after rifampin pretreatment was reduced by 65% compared with placebo (P < .001). Rifampin decreased the peak plasma concentration of oral ondansetron by about 50% (from 27.2+/-3.0 to 13.8+/-1.5 ng/mL [mean +/- SEM]; P < .001]) and the elimination half-life (t1/2) by 38% (P < .01). The bioavailability of oral ondansetron was reduced from 60% to 40% (P < .01) by rifampin. The clearance of intravenous ondansetron was increased 83% (from 440+/-38.4 to 805+/-44.6 mL/min [P < .001]) by rifampin. Rifampin reduced the t1/2 of intravenously administered ondansetron by 46% (P < .001) and the AUC(0-infinity) by 48% (P < .001). CONCLUSIONS: Rifampin considerably decreases the plasma concentrations of ondansetron after both oral and intravenous administration. The interaction is most likely the result of induction of the CYP3A4-mediated metabolism of ondansetron. Concomitant use of rifampin or other potent inducers of CYP3A4 with ondansetron may result in a reduced antiemetic effect, particularly after oral administration of ondansetron.     

The effect of age,sex, and rifampin administration on intestinal and hepatic cytochrome P450 3A activity

BACKGROUND: The relative susceptibility of intestinal and hepatic cytochrome P450 (CYP) 3A to induction by rifampin (INN, rifampicin), as a function of age and sex, was investigated with the CYP3A substrate midazolam. METHODS: Fourteen young women (mean age, 26 +/- 4 years), 14 young men (mean age, 27 +/- 4 years), 14 elderly women (mean age, 72 +/- 5 years), and 10 elderly men (mean age, 70 +/- 4 years) received simultaneous intravenous doses (0.05 mg/kg over a 30-minute period) and oral doses of midazolam (3-8 mg of a stable isotope, (15)N(3)-midazolam) before and after 7 days of rifampin dosing (600 mg once daily in the evening). Serum and urine samples were assayed for midazolam, (15)N(3)-midazolam, and metabolites by liquid chromatography-mass spectrometry. RESULTS: No significant difference (P > or =.05) in the baseline systemic and oral clearance of midazolam was observed between male and female or young and old volunteers. Rifampin significantly (P <.0001) increased the systemic and oral clearance of midazolam from 0.44 +/- 0.2 L. h/kg and 1.56 +/- 0.8 L x h/kg to 0.96 +/- 0.3 L x h/kg and 34.4 +/- 21.2 L x h/kg, respectively. Likewise, the oral clearance of midazolam was significantly (P <.0001) increased in women and men, from 1.64 +/- 0.87 L x kg/h and 1.46 +/- 0.7 L x kg/h to 28.4 +/- 13.2 L x kg/h and 41.6 +/- 26.5 L x kg/h, respectively. A significant (P =.0023) effect of sex was noted in the extent of induction of the oral clearance of midazolam, being greater in men than in women. In contrast, the extent of midazolam systemic clearance induction was greater in women than in men (P =.0107). Age did not influence the extent of intestinal and hepatic CYP3A induction as determined by the oral and systemic clearance of midazolam. Rifampin dosing significantly (P <.0001) reduced the oral availability by 88%, from 0.32 +/- 0.13 to 0.04 +/- 0.02. Correspondingly, hepatic and intestinal availabilities were significantly (P <.0001) reduced after rifampin administration. After rifampin, the correlation coefficient for the relationship between oral availability and intestinal availability was significantly (P <.0001) reduced from 0.96 to 0.67, which reflects the increasing contribution of hepatic extraction to the determination of midazolam oral availability. A significant nonlinear inverse relationship was observed between the percent change in systemic clearance of midazolam and the initial baseline midazolam systemic clearance (r = -0.68, N = 52, P <.0001). Likewise, a significant inverse relationship was observed between the percent change in oral clearance and the baseline oral clearance (r = -0.39, N = 52, P =.0041). A significant inverse relationship between the ratio of hepatic intrinsic clearance in the presence of rifampin to that in the absence of rifampin and the corresponding ratio of intestinal intrinsic clearance was observed (Spearman correlation coefficient [r] = -0.68, P <.0001) and indicates that in a given individual the extent of induction was high at either the hepatic or the intestinal site but not both. CONCLUSION: Sex-related differences exist in the extent of intestinal and hepatic CYP3A induction by rifampin. The extent of induction at hepatic and intestinal sites was inversely dependent and reflected the independent regulation of CYP3A expression at these sites. The large interindividual variation in the extent of induction is explained in part by the variation in baseline expression of CYP3A. Sex-related differences in response to CYP3A inducers will be substrate-dependent and reflect the relative contribution of hepatic and intestinal sites of metabolism.     

Effect of oral antacid administration on the pharmacokinetics of intravenous doxycycline.

The effect of oral antacid administration on the pharmacokinetics of intravenous doxycycline was studied. In a randomized crossover design, six healthy male volunteers received an infusion of 200 mg of doxycycline hyclate on two occasions separated by 7 days. On one occasion, subjects were given 30 ml of aluminum hydroxide orally four times a day for 4 days, beginning 2 days prior to doxycycline dosing. Blood and urine samples were collected up to 48 and 96 h after the infusion, respectively, and were analyzed by a microbial assay. Values for volume of distribution at steady state, nonrenal clearance, urine recovery, and urine pH were not statistically different among treatment groups. With concomitant antacid therapy, the half-life of intravenous doxycycline was shortened from 16.2 +/- 2.6 to 11.2 +/- 1.2 h (P = 0.003), and total body clearance increased from 37.4 +/- 6.5 to 54.1 +/- 12.3 ml/min (P = 0.008). Area under the concentration-time curve for serum was decreased by 18 to 44%, with a 22 to 41% increase in renal clearance. Although the increase in nonrenal clearance ranged from 11 to 128%, the high variability led to a nonsignificant difference (P = 0.07). Concomitant oral antacid therapy may significantly enhance the clearance of intravenous doxycycline.     

Effect of simultaneous versus staggered dosing on pharmacokinetic interactions of protease inhibitors

OBJECTIVE: The aim of this study was to determine whether pharmacokinetic interactions between the protease inhibitors saquinavir soft gel, nelfinavir, and ritonavir are affected by the timing of administration. STUDY DESIGN: We used an open-label, 6-period, incomplete Latin square crossover study in 18 human immunodeficiency virus-negative subjects. Each received single oral doses of 2 of the 3 protease inhibitors during each of 6 periods. Single doses were given either simultaneously or separated by 4 hours. The order of the periods was balanced, and periods were separated by 2 days. We measured protease inhibitor concentrations over a 24-hour period by HPLC and estimated pharmacokinetic parameters by noncompartmental methods. RESULTS: Median saquinavir area under the curve (AUC) increased by 62-fold when ritonavir was coadministered, by 50-fold when ritonavir was given 4 hours earlier, and by 16-fold when saquinavir preceded ritonavir by 4 hours. Saquinavir AUC increased by 7-fold when nelfinavir was coadministered. Nelfinavir AUC increased by 2.5-fold with coadministration of ritonavir and by 1.8- and 2.1-fold when ritonavir was administered before nelfinavir and after nelfinavir, respectively. Ritonavir AUCs were unaffected by coadministration of the other drugs. The effect of ritonavir on the kinetics of saquinavir persisted for at least 48 hours after a single dose of ritonavir, suggesting the possibility of metabolic intermediates that form inhibitory complexes. CONCLUSION: Except for saquinavir followed by ritonavir, there is little difference in protease inhibitor exposure for simultaneous or staggered doses. The persistent effect of ritonavir suggests the possibility that lower doses and longer dosing intervals might be effective when ritonavir is used to boost concentrations of other protease inhibitors.     

Pharmacokinetics and safety of saquinavir/ritonavir and omeprazole in HIV-infected subjects

We investigated the pharmacokinetics and safety of saquinavir/ritonavir when administered with omeprazole simultaneously and 2 h apart to human immunodeficiency virus (HIV) subjects. Saquinavir/ritonavir 12-h pharmacokinetics was assessed with and without omeprazole 40 mg. Subjects were randomized to group A (saquinavir/ritonavir and omeprazole simultaneously/2 h apart) or group B (saquinavir/ritonavir and omeprazole 2 h apart/simultaneously). Saquinavir/ritonavir pharmacokinetics was assessed on days 1, 8, and 22. Within-subject changes were evaluated by geometric mean ratios and 90% confidence interval (CI). Twelve subjects completed the study. GM (90% CI) for saquinavir area under the curve (AUC)(0-12) (ng h/ml), trough concentration (C(trough)) (ng/ml), and maximum concentration (C(max)) (ng/ml) were 14,698 (13,242-20,636), 433 (368-758), 2,513 (2,243-3,329) without omeprazole; 22,646 (18,536-131,861), 750 (619-1,280), 3,890 (3,223-5,133) with omeprazole simultaneously; and 24,549 (20,884-38,894), 851 (720-1,782), 4,141 (3,554-5,992) with omeprazole 2 h earlier. Simultaneous administration of omeprazole significantly increased saquinavir AUC(0-12), C(trough), and C(max) by 54, 73, and 55%, whereas staggered administration by 67, 97, and 65%. No grade 3/4 toxicity or lab abnormalities were observed. In the presence of omeprazole, saquinavir plasma exposure is significantly increased in HIV-infected subjects whether administered simultaneously or 2 h apart.     

Pharmacology of ephedra alkaloids and caffeine after single-dose dietary supplement use

OBJECTIVE: Serious cardiovascular toxicity has been reported in people taking dietary supplements that contain ma huang (Ephedra) and guarana (caffeine). We assessed the pharmacokinetics and pharmacodynamics of a dietary supplement that contains these herbal stimulants. METHODS: Eight healthy adults received a single oral dose of a thermogenic dietary supplement labeled to contain 20 mg ephedrine alkaloids and 200 mg caffeine after an overnight fast. Serial plasma and urine samples were analyzed by use of liquid chromatography-tandem mass spectrometry for ephedrine alkaloid and caffeine concentrations, and heart rate and blood pressure were monitored for 14 hours. RESULTS: Plasma clearance and elimination half-lives for ephedrine, pseudoephedrine, and caffeine were comparable to published values reported for drug formulations. A prolonged half-life of ephedrine and pseudoephedrine was observed in 1 subject with the highest urine pH. Mean systolic blood pressure increased significantly to a maximum of 14 mm Hg above baseline at 90 minutes after ingestion (P <.001). There was a lag in the mean heart rate response that reached a maximum change of 15 beats/min above baseline at 6 hours after ingestion (P <.001). Diastolic blood pressure changes were insignificant. Two subjects who were taking oral contraceptives had longer caffeine half-lives (15.5 +/- 0.3 hours versus 5.6 +/- 1.7 hours) and lower values for oral clearance (0.34 +/- 0.01 mL/min. kg versus 0.99 +/- 0.41 mL/min. kg) than subjects who were not taking oral contraceptives. CONCLUSIONS: Botanical stimulants have disposition characteristics similar to their pharmaceutical counterparts, and they can produce significant cardiovascular responses after a single dose.     

CYP3A activity in European American and Japanese men using midazolam as an in vivo probe

OBJECTIVE: To investigate putative differences in CYP3A activity between European American and Japanese subjects using midazolam as an in vivo probe. METHODS: Midazolam was administered orally (2 mg) to 22 young healthy Japanese men and, on a separate occasion, to 19 of these by the intravenous route (1 mg). The disposition of the drug and its 1'-hydroxy metabolite were determined and compared with data collected in a similar fashion in 20 young healthy European American men. RESULTS: Plasma concentrations of midazolam, especially those attained soon after drug administration, were higher after intravenous injection in Japanese subjects than those in European American men. This observation was associated with smaller initial (2.5-fold) and steady-state (1.8-fold) volumes of distribution for the drug; normalization for body weight only modestly reduced these differences. The systemic clearance value of midazolam was 25% lower (P < .03) in Japanese subjects, but this difference was not apparent after accounting for the smaller body weights of that group. No statistical differences were noted in the elimination half-life (t 1/2) of midazolam between European American and Japanese subjects. Much greater interindividual variability was observed after oral administration compared with intravenous administration, but significant differences were not found between the 2 groups with respect to the maximum midazolam plasma level or its oral clearance. Absolute oral bioavailability and its associated gastrointestinal and hepatic extraction ratios also showed no statistically significant interracial differences. CONCLUSIONS: On average, hepatic CYP3A, as measured by the metabolism of midazolam, is lower in young healthy Japanese men compared with similar European Americans. However, there is considerable interindividual variability, and body size appears to be an important determinant. After oral administration, even greater variability in the plasma level-time profile of midazolam is present, and no statistically significant or clinically important interracial/ethnic difference is present. Possibly because of smaller body mass and differences in body composition, midazolam has a smaller distribution volume(s) in Japanese men than in European American men that might be an important factor when drugs are administered intravenously.     

Enzyme induction in the elderly: effect of rifampin on the pharmacokinetics and pharmacodynamics of propafenone

OBJECTIVE: A clinical study on enzyme induction in elderly subjects was performed by investigation of the effect of rifampin (INN, rifampicin) on propafenone disposition. Propafenone was chosen as a model drug because of its complex metabolism that permits the simultaneous in vivo assessment of induction of phase 1 and phase 2 pathways. METHODS: Six extensive metabolizers of CYP2D6 (age, 70.5 +/- 3.5 years) ingested 600 mg rifampin once daily for 9 consecutive days. One day before the first rifampin dose and on the day of the last rifampin dose, each elderly individual received a single intravenous infusion of 70 mg unlabeled propafenone and received a single oral dose of 300 mg deuterated propafenone 2 hours later. Pharmacokinetics and pharmacodynamics of propafenone were compared before and during induction. RESULTS: Maximum QRS prolongation after oral propafenone was decreased significantly by rifampin (18% +/- 5% versus 6% +/- 3%; P < .01). There were no substantial differences in pharmacokinetics and pharmacodynamics of intravenous propafenone during induction. However, bioavailability of propafenone dropped from 30% +/- 24% to 4% +/- 3% (P < .05). After oral propafenone was administered, clearances through N-dealkylation (6 +/- 3 mL/min versus 26 +/- 16 mL/min; P < .05) and glucuronidation (178 +/- 75 mL/min versus 739 +/- 533 mL/min; P < .05), but not 5-hydroxylation, were increased by rifampin, indicating substantial enzyme induction. CONCLUSIONS: Both phase 1 and phase 2 pathways of propafenone metabolism were induced by rifampin in elderly subjects, resulting in a clinically relevant drug interaction.