Failure of Oral Activated Charcoal to Accelerate the Elimination of Amiodarone and Chloroquine

1 The effect of activated charcoal on the elimination of amiodarone and chloroquine was studied in the rat.

2 The study consisted of two separate experiments. Amiodarone and chloroquine were injected subcutaneously at doses of 200 mg kg-1 and 100 mg kg-1, respectively. Six rats in both experiments were put on a charcoal-containing diet 48 h after drug administration, while the control groups remained on a normal diet.

3 Treatment with repeated oral activated charcoal had no effect on the true elimination of amiodarone and chloroquine.

4 These results suggest that, after the distribution of amiodarone and chloroquine into peripheral compartments, their rate of elimination cannot be significantly accelerated with multiple oral doses of activated charcoal.

Mitochondrial DNA polymerase gamma variants in idiopathic sporadic Parkinson disease

OBJECTIVE

Dysfunction of mitochondrial DNA polymerase gamma (POLG) has been recently recognized as an important cause of inherited neurodegenerative diseases. We have reported dominant and recessive inheritance of parkinsonism, mitochondrial myopathy, and premature amenorrhea in five ethnically distinct families with POLG1 mutations. This prompted us to carry out a detailed analysis of the coding region and intron-exon boundaries of POLG1 in Finnish patients with idiopathic sporadic Parkinson disease (PD) and in nonparkinsonian controls.

METHODS

The coding region of POLG1 was analyzed in 140 Finnish patients with PD and their 127 spouses as age- and ethnically matched controls. Further, we analyzed the intragenic CAG-repeat region of POLG1 in 126 additional patients with nonparkinsonian neurologic disorders and in 516 Finnish population controls.

RESULTS

We found clustering of rare variants of the POLG1 CAG-repeat, encoding a polyglutamine tract, in Finnish patients with idiopathic PD as compared to their spouses (p = 0.003; OR 3.01, 95% CI 1.35 to 6.71), population controls (p = 0.001; OR 2.45, 95% CI 1.45 to 4.14), and patients with nonparkinsonian neurologic disorders (p = 0.05, OR 1.98, 95% CI 0.97 to 4.05). We found several amino acid substitutions, none of them associating with PD. These included a previously parkinsonism-associated POLG variant Y831C, found in one patient with PD, but also in five controls, suggesting that it is a neutral amino acid polymorphism.

CONCLUSIONS

Our results suggest that POLG polyglutamine tract variants should be considered as a predisposing genetic factor in idiopathic sporadic Parkinson disease.

Gemfibrozil is a potent inhibitor of human cytochrome P450 2C9

The in vitro inhibitory effects of gemfibrozil on cytochrome P450 (CYP) 1A2 (phenacetin O-deethylation), CYP2A6 (coumarin 7-hydroxylation), CYP2C9 (tolbutamide hydroxylation), CYP2C19 (S-mephenytoin 4'-hydroxylation), CYP2D6 (dextromethorphan O-deethylation), CYP2E1 (chlorzoxazone 6-hydroxylation), and CYP3A4 (midazolam 1'-hydroxylation) activities were examined using pooled human liver microsomes. The in vivo drug interactions of gemfibrozil were predicted in vitro using the [I]/([I] + K(i)) values. Gemfibrozil strongly and competitively inhibited CYP2C9 activity, with a K(i) (IC(50)) value of 5.8 (9.6) microM. In addition, gemfibrozil exhibited somewhat smaller inhibitory effects on CYP2C19 and CYP1A2 activities, with K(i) (IC(50)) values of 24 (47) microM and 82 (136) microM, respectively. With concentrations up to 250 microM, gemfibrozil showed no appreciable effect on CYP2A6, CYP2D6, CYP2E1, and CYP3A4 activities. Based on [I]/([I] + K(i)) values calculated using peak total (or unbound) plasma concentration of gemfibrozil, 96% (56%), 86% (24%), and 64% (8%) inhibition of the clearance of CYP2C9, CYP2C19, and CYP1A2 substrates could be expected, respectively. In conclusion, gemfibrozil inhibits the activity of CYP2C9 at clinically relevant concentrations, and this is the likely mechanism by which gemfibrozil interacts with CYP2C9 substrate drugs, such as warfarin and glyburide. Gemfibrozil may also impair clearance of CYP2C19 and CYP1A2 substrates, but inhibition of other CYP isoforms is unlikely.

In vitro evaluation of valproic acid as an inhibitor of human cytochrome P450 isoforms: preferential inhibition of cytochrome P450 2C9 (CYP2C9)

AIMS

To evaluate the potency and specificity of valproic acid as an inhibitor of the activity of different human CYP isoforms in liver microsomes.

METHODS

Using pooled human liver microsomes, the effects of valproic acid on seven CYP isoform specific marker reactions were measured: phenacetin O-deethylase (CYP1A2), coumarin 7-hydroxylase (CYP2A6), tolbutamide hydroxylase (CYP2C9), S-mephenytoin 4'-hydroxylase (CYP2C19), dextromethorphan O-demethylase (CYP2D6), chlorzoxazone 6-hydroxylase (CYP2E1) and midazolam 1'-hydroxylase (CYP3A4).

RESULTS

Valproic acid competitively inhibited CYP2C9 activity with a Ki value of 600 microM. In addition, valproic acid slightly inhibited CYP2C19 activity (Ki = 8553 microM, mixed inhibition) and CYP3A4 activity (Ki = 7975 microM, competitive inhibition). The inhibition of CYP2A6 activity by valproic acid was time-, concentration- and NADPH-dependent (KI = 9150 microM, Kinact=0.048 min(-1)), consistent with mechanism-based inhibition of CYP2A6. However, minimal inhibition of CYP1A2, CYP2D6 and CYP2E1 activities was observed.

CONCLUSIONS

Valproic acid inhibits the activity of CYP2C9 at clinically relevant concentrations in human liver microsomes. Inhibition of CYP2C9 can explain some of the effects of valproic acid on the pharmacokinetics of other drugs, such as phenytoin. Co-administration of high doses of valproic acid with drugs that are primarily metabolized by CYP2C9 may result in significant drug interactions.

Effect of gemfibrozil on the pharmacokinetics and pharmacodynamics of glimepiride

OBJECTIVE

Our objective was to study the effects of gemfibrozil on the pharmacokinetics and pharmacodynamics of glimepiride, a new sulfonylurea antidiabetic drug and a substrate of cytochrome P4502C9 (CYP2C9).

METHODS

In a randomized, 2-phase crossover study, 10 healthy volunteers were treated for 2 days with 600 mg oral gemfibrozil or placebo twice daily. On day 3, they received a single dose of 600 mg gemfibrozil or placebo and 1 hour later a single dose of 0.5 mg glimepiride orally. Plasma glimepiride, serum insulin, and blood glucose concentrations were measured up to 12 hours.

RESULTS

Gemfibrozil increased the mean total area under the plasma concentration-time curve of glimepiride by 23% (range, 6%-56%; P <.005). The mean elimination half-life of glimepiride was prolonged from 2.1 to 2.3 hours (P <.05) by gemfibrozil. No statistically significant differences were found in the serum insulin or blood glucose variables between the two phases.

CONCLUSIONS

Gemfibrozil modestly increases the plasma concentrations of glimepiride. This may be caused by inhibition of CYP2C9.

Stereoselective pharmacokinetics of cisapride in healthy volunteers and the effect of repeated administration of grapefruit juice

AIMS

To determine whether the pharmacokinetics of cisapride and its interaction with grapefruit juice are stereoselective.

METHODS

The study was a randomized, two-phase cross over design with a washout period of 2 weeks. Ten healthy volunteers were pretreated with either water or 200 ml double strength grapefruit juice three times a day for 2 days. On the 3rd each subject ingested a single 10 mg dose of rac-cisapride tablet. Double strength grapefruit juice (200 ml) or water was administered during cisapride dosing and 0.5 and 1.5 h thereafter. Blood samples were collected before and for 32 h after cisapride administration. Plasma concentrations of cisapride enantiomers were measured by a chiral h.p.l.c. method. A standard 12-lead ECG was recorded before cisapride administration (baseline) and 2, 5, 8, and 12 h later.

RESULTS

This study showed that cisapride pharmacokinetics are stereoselective. In control (water treated) subjects, the mean Cmax (30 +/- 13.6 ng ml-1; P = 0.0008) and AUC(0, infinity) (201 +/- 161 ng ml-1 h; P = 0.029) of (-)-cisapride were significantly higher than the Cmax (10.5 +/- 3.4 ng ml-1) and AUC(0, infinity) (70 +/- 51.5 ng ml-1 h) of (+)-cisapride. There was no marked difference in elimination half-life between (-)-cisapride (4.7 +/- 2.7 h) and (+)-cisapride (4.8 +/- 3 h). Compared with the water treated group, grapefruit juice significantly increased the mean Cmax of (-)-cisapride from 30 +/- 13.6-55.5 +/- 18 ng ml-1 (95% CI on mean difference, -33, -17; P = 0.00005) and of (+)-cisapride from 10.5 +/- 3.4 to 18.4 +/- 6.2 ng ml-1 (95% CI on mean difference, -11.8, -3.9, P = 0.00015). The mean AUC(0, infinity) of (-)-cisapride was increased from 201 +/- 161 to 521.6 +/- 303 ng ml-1 h (95% CI on mean difference, -439, -202; P = 0.0002) and that of (+)-cisapride from 70 +/- 51.5 to 170 +/- 91 ng ml-1 h (95% CI on mean difference, -143, -53; P = 0.0005). The tmax was also significantly increased for both enantiomers (from 1.35 to 2.8 h for (-)-cisapride and from 1.75 to 2.9 h for (+)-cisapride in the control and grapefruit juice group, respectively; P < 0.05). The t(1/2) of (-)-cisapride was significantly increased by grapefruit juice, while this change did not reach significant level for (+)-cisapride. The proportion of pharmacokinetic changes brought about by grapefruit juice was similar for both enantiomers, suggesting non-stereoselective interaction. We found no significant difference in mean QTc intervals between the water and grapefruit juice treated groups.

CONCLUSIONS

The pharmacokinetics of cisapride is stereoselective. Grapefruit juice elevates plasma concentrations of both (-)- and (+)-cisapride, probably through inhibition of CYP3A in the intestine. At present, there are no data on whether the enantiomers exhibit stereoselective pharmacodynamic actions. If they do, determination of plasma concentrations of the individual enantiomers as opposed to those of racemic cisapride may better predict the degree of drug interaction, cardiac safety and prokinetic efficacy of cisapride.

Activated charcoal alone and followed by whole-bowel irrigation in preventing the absorption of sustained-release drugs

OBJECTIVE

Our objective was to study the effect of activated charcoal on the absorption of sustained-release drugs ingested 1 hour earlier and to examine whether whole-bowel irrigation affects the efficacy of charcoal.

METHODS

In this randomized, 3-phase crossover study, 9 healthy subjects received, at the same time, 200 mg carbamazepine, 200 mg theophylline, and 120 mg verapamil. All drugs were given as sustained-release tablets. One hour after taking the tablets, the subjects were assigned to one of the following treatments: 25 g activated charcoal as a suspension, 25 g activated charcoal as a suspension followed by whole-bowel irrigation with polyethylene glycol (PEG) electrolyte lavage solution, or 200 mL water (control). The absorption of the drugs was characterized by using the area under the plasma drug concentration-time curve from time zero to 24 hours [AUC(0-24)], peak plasma concentration (C(max)), C(max) minus the plasma concentration at 1 hour (C(Delta)), and time to peak (t(max)).

RESULTS

Activated charcoal alone given 1 hour after drug intake significantly (P <.001) reduced the absorption [AUC(0-24)] of all 3 drugs (by 62%-75%). Also the C(max) and C(Delta) values of these drugs were significantly reduced by charcoal alone. Whole-bowel irrigation did not increase significantly the effect of charcoal on any absorption parameters of the 3 drugs studied. On the contrary, whole-bowel irrigation significantly (P <.01) decreased the efficacy of charcoal with respect to carbamazepine.

CONCLUSIONS

Activated charcoal alone given 1 hour after intake of sustained-release drugs was effective in preventing the absorption of all 3 drugs studied. Whole-bowel irrigation may even decrease the efficacy of charcoal if the drug is well adsorbable onto charcoal. However, our study was performed with therapeutic drug doses only. In overdoses their possible effects on gastrointestinal motility may modify the efficacy of decontamination methods.

Effect of methylprednisolone on CYP3A4-mediated drug metabolism in vivo

OBJECTIVE

To study the effects of methylprednisolone on the pharmacokinetics and pharmacodynamics of triazolam.

METHODS

In this three-phase cross-over study, ten healthy subjects received 0.25 mg oral triazolam on three occasions: on day 1 (no pretreatment, control), on day 8 (1 h after a single dose of 32 mg oral methylprednisolone) and on day 18 (after further treatment with 8 mg oral methylprednisolone daily for 9 days). The plasma concentrations of triazolam were determined up to 10 h, and its effects were measured using four psychomotor tests up to 6 h.

RESULTS

The single dose of methylprednisolone showed no significant effects on the pharmacokinetics of triazolam. However, the Digit Symbol Substitution Test result was better (P < 0.05) during the single-dose methylprednisolone phase than during the control phase, the other three tests showing no differences between the phases. The multiple-dose treatment with methylprednisolone reduced the mean peak plasma concentration (Cmax) of triazolam by 30% (P < 0.05) but had no significant effects on the time to Cmax (tmax), elimination half-life (t 1/2), area under the plasma concentration-time curve from 0 h to 10 h (AUC(0-10 h)) and AUC(0-infinity) and did not alter the effects of triazolam.

CONCLUSION

A single, relatively high dose of methylprednisolone (32 mg) did not affect cytochrome P450 (CYP)3A4 activity, and treatment with 8 mg methylprednisolone daily for 9 days did not result in clinically significant induction of CYP3A4.

The cytochrome P4503A4 inhibitor clarithromycin increases the plasma concentrations and effects of repaglinide

OBJECTIVE

Our objective was to study the effects of the macrolide antibiotic clarithromycin on the pharmacokinetics and pharmacodynamics of repaglinide, a novel short-acting antidiabetic drug.

METHODS

In a randomized, double-blind, 2-phase crossover study, 9 healthy volunteers were treated for 4 days with 250 mg oral clarithromycin or placebo twice daily. On day 5 they received a single dose of 250 mg clarithromycin or placebo, and 1 hour later a single dose of 0.25 mg repaglinide was given orally. Plasma repaglinide, serum insulin, and blood glucose concentrations were measured up to 7 hours.

RESULTS

Clarithromycin increased the mean total area under the concentration-time curve of repaglinide by 40% (P <.0001) and the peak plasma concentration by 67% (P <.005) compared with placebo. The mean elimination half-life of repaglinide was prolonged from 1.4 to 1.7 hours (P <.05) by clarithromycin. Clarithromycin increased the mean incremental area under the concentration-time curve from 0 to 3 hours of serum insulin by 51% (P <.05) and the maximum increase in the serum insulin concentration by 61% (P <.01) compared with placebo. No statistically significant differences were found in the blood glucose concentrations between the placebo and clarithromycin phases.

CONCLUSIONS

Even low doses of the cytochrome P4503A4 (CYP3A4) inhibitor clarithromycin increase the plasma concentrations and effects of repaglinide. Concomitant use of clarithromycin or other potent inhibitors of CYP3A4 with repaglinide may enhance its blood glucose-lowering effect and increase the risk of hypoglycemia.

Effects of rifampin on the pharmacokinetics and pharmacodynamics of glyburide and glipizide

OBJECTIVE

To study the effects of rifampin (INN, rifampicin) on the pharmacokinetics and pharmacodynamics of glyburide (INN, glibenclamide) and glipizide, 2 sulfonylurea antidiabetic drugs.

METHODS

Two separate, randomized, 2-phase, crossover studies with an identical design were conducted. In each study, 10 healthy volunteers received 600 mg rifampin or placebo once daily for 5 days. On day 6, a single dose of 1.75 mg glyburide (study I) or 2.5 mg glipizide (study II) was administered orally. Plasma glyburide and glipizide and blood glucose concentrations were measured for 12 hours.

RESULTS

In study I, rifampin decreased the area under the plasma concentration--time curve [AUC(0-infinity)] of glyburide by 39% (P <.001) and the peak plasma concentration by 22% (P =.01). The elimination half-life of glyburide was shortened from 2.0 to 1.7 hours (P <.05) by rifampin. The blood glucose decremental AUC(0-7) (net area below baseline) and the maximum decrease in the blood glucose concentration were decreased by 44% (P =.05) and 36% (P <.001), respectively, by rifampin. In study II, rifampin decreased the AUC(0-infinity) of glipizide by 22% (P <.05) and shortened its half-life from 3.0 to 1.9 hours (P =.01). No statistically significant differences in the blood glucose concentrations were found between the phases; however, 4 subjects had moderate hypoglycemia during the placebo phase but only 1 subject had moderate hypoglycemia during the rifampin phase.

CONCLUSIONS

Rifampin moderately decreased the plasma concentrations and effects of glyburide but had only a slight effect on glipizide. The mechanism underlying the interaction between rifampin and glyburide is probably induction of either CYP2C9 or P-glycoprotein or both. Induction of CYP2C9 would explain the increased systemic elimination of glipizide. It is probable that the blood glucose--lowering effect of glyburide is reduced during concomitant treatment with rifampin. In some patients, the effects of glipizide may also be reduced by rifampin.

Plasma concentrations of active lovastatin acid are markedly increased by gemfibrozil but not by bezafibrate

BACKGROUND

Concomitant use of fibrates with statins has been associated with an increased risk of myopathy, but the underlying mechanism of this adverse reaction remains unclear. Our aim was to study the effects of bezafibrate and gemfibrozil on the pharmacokinetics of lovastatin.

METHODS

This was a randomized, double-blind, 3-phase crossover study. Eleven healthy volunteers took 400 mg/day bezafibrate, 1200 mg/day gemfibrozil, or placebo for 3 days. On day 3, each subject ingested a single 40 mg dose of lovastatin. Plasma concentrations of lovastatin, lovastatin acid, gemfibrozil, and bezafibrate were measured up to 24 hours.

RESULTS

Gemfibrozil markedly increased the plasma concentrations of lovastatin acid, without affecting those of the parent lovastatin compared with placebo. During the gemfibrozil phase, the mean area under the plasma concentration-time curve from 0 to 24 hours [AUC(0-24)] of lovastatin acid was 280% (range, 131% to 1184%; P < .001) and the peak plasma concentration (Cmax) was 280% (range, 123% to 1042%; P < .05) of the corresponding value during the placebo phase. Bezafibrate had no statistically significant effect on the AUC(0-24) or Cmax of lovastatin or lovastatin acid compared with placebo.

CONCLUSIONS

Gemfibrozil markedly increases plasma concentrations of lovastatin acid, but bezafibrate does not. The increased risk of myopathy observed during concomitant treatment with statins and fibrates may be partially of a pharmacokinetic origin. The risk of developing myopathy during concomitant therapy with lovastatin and a fibrate may be smaller with bezafibrate than with gemfibrozil.

Effects of fluconazole and fluvoxamine on the pharmacokinetics and pharmacodynamics of glimepiride

OBJECTIVE

Our objective was to study the effects of fluconazole and fluvoxamine on the pharmacokinetics and pharmacodynamics of glimepiride, a new sulfonylurea antidiabetic drug.

METHODS

In this randomized, double-blind, three-phase crossover study, 12 healthy volunteers took 200 mg of fluconazole once daily (400 mg on day 1), 100 mg of fluvoxamine once daily, or placebo once daily for 4 days. On day 4, a single oral dose of 0.5 mg of glimepiride was administered. Plasma glimepiride and blood glucose concentrations were measured up to 12 hours.

RESULTS

In the fluconazole phase, the mean total area under the plasma concentration-time curve of glimepiride was 238% (P <.0001) and the peak plasma concentration was 151% (P <.0001) of the respective control value. The mean elimination half-life of glimepiride was prolonged from 2.0 to 3.3 hours (P <.0001) by fluconazole. In the fluvoxamine phase, the mean area under the plasma concentration-time curve of glimepiride was not significantly different from that in the placebo phase. However, the mean peak plasma concentration of glimepiride was 143% (P <.05) of the control and the elimination half-life was prolonged from 2.0 to 2.3 hours (P <.01) by fluvoxamine. Fluconazole and fluvoxamine did not cause statistically significant changes in the effects of glimepiride on blood glucose concentrations.

CONCLUSIONS

Fluconazole considerably increased the area under the plasma concentration-time curve of glimepiride and prolonged its elimination half-life. This was probably caused by inhibition of the cytochrome P-450 2C9-mediated biotransformation of glimepiride by fluconazole. Concomitant use of fluconazole with glimepiride may increase the risk of hypoglycemia as much as would a 2- to 3-fold increase in the dose of glimepiride. Fluvoxamine moderately increased the plasma concentrations and slightly prolonged the elimination half-life of glimepiride.

Selegiline pharmacokinetics are unaffected by the CYP3A4 inhibitor itraconazole

OBJECTIVE

To characterise the effects of itraconazole, a potent inhibitor of CYP3A4, on the pharmacokinetics of selegiline in healthy volunteers.

METHODS

In this randomised, placebo-controlled crossover study with two phases, 12 healthy volunteers took either 200 mg itraconazole or matched placebo once daily for 4 days. On day 4, a single 10-mg oral dose of selegiline hydrochloride was administered. Serum concentrations of selegiline and its primary metabolites desmethylselegiline and l-methamphetamine were determined up to 32 h. A caffeine test was performed on day 3 of both phases, by measuring the plasma paraxanthine/caffeine concentration ratio 6 h after caffeine intake, to examine the role of CYP1A2 in selegiline pharmacokinetics. In addition, the effects of itraconazole on the metabolism of selegiline in vitro were characterised by using human liver microsomes.

RESULTS

Itraconazole had no significant effects on the pharmacokinetic variables of selegiline, desmethylselegiline or l-methamphetamine, with the exception that the AUC of desmethylselegiline was increased by about 10% (P < 0.05). There was a significant correlation between the AUC(desmethylselegiline)/AUC(selegiline) ratio and the paraxanthine/caffeine ratio (r = 0.41; P < 0.05), suggesting involvement of CYP1A2 in the formation of desmethylselegiline. In experiments with human liver microsomes, itraconazole had no inhibitory effect on the formation of either desmethylselegiline or l-methamphetamine from selegiline.

CONCLUSIONS

The pharmacokinetics of selegiline in healthy volunteers were unaffected by the potent CYP3A4 inhibitor itraconazole. In addition, itraconazole showed no inhibitory effect on the biotransformation of selegiline to desmethylselegiline and l-methamphetamine by human liver microsomes. These findings suggest that selegiline is not susceptible to interaction with CYP3A4 inhibitors.

Identification of drugs ingested in acute poisoning: correlation of patient history with drug analyses

The aim of this study was to assess the reliability of patient history in the identification of the drugs taken by patients who have an acute drug overdose. To this end, a prospective study involving 51 cases of acute, deliberate drug poisoning was carried out (patients with ethanol as the only apparent cause of intoxication were excluded). Information based on interviews with the patients and their companions or on circumstantial evidence (e.g., drug containers found) was compared with the results from drug analyses of various body fluids. The information obtained on admission was completely in accordance with the laboratory findings in only 27% of the cases. Minor discrepancies between the history and the results from drug analyses concerning the identity of the drugs taken were found in 55% of the cases. In 18% of the cases, the discrepancies were considered clinically important. Serious symptoms occurred in approximately 20% of the patients, but none of them were the result of incorrect information obtained on admission. All the patients survived. These results support the prevailing view that rapid identification of the drugs taken in overdose by means of comprehensive drug screens would have little effect on the treatment of most cases of acute poisoning. However, such assays would enable optimal treatment of many cases of acute poisoning by reducing the need for supervision and costly treatments and facilitating the identification of cases that would require prompt drug-specific treatment.

Rifampin greatly reduces plasma simvastatin and simvastatin acid concentrations

BACKGROUND

Rifampin (rifampicin) is a potent inducer of several cytochrome P450 (CYP) enzymes, including CYP3A4. The cholesterol-lowering drug simvastatin has an extensive first-pass metabolism, and it is partially metabolized by CYP3A4. This study was conducted to investigate the effect of rifampin on the pharmacokinetics of simvastatin.

METHODS

In a randomized cross-over study with two phases and a washout of 4 weeks, 10 healthy volunteers received a 5-day pretreatment with rifampin (600 mg daily) or placebo. On day 6, a single 40-mg dose of simvastatin was administered orally. Plasma concentrations of simvastatin and its active metabolite simvastatin acid were measured up to 12 hours with a sensitive liquid chromatography-ion spray tandem mass spectrometry method.

RESULTS

Rifampin decreased the total area under the plasma concentration-time curve of simvastatin and simvastatin acid by 87% (P < .001) and 93% (P < .001), respectively. Also the peak concentrations of both simvastatin and simvastatin acid were reduced greatly (by 90%) by rifampin (P < .001). On the other hand, rifampin had no significant effect on the elimination half-life of simvastatin or simvastatin acid.

CONCLUSIONS

Rifampin greatly decreases the plasma concentrations of simvastatin and simvastatin acid. Because the elimination half-life of simvastatin was not affected by rifampin, induction of the CYP3A4-mediated first-pass metabolism of simvastatin in the intestine and the liver probably explains this interaction. Concomitant use of potent inducers of CYP3A4 can lead to a considerably reduced cholesterol-lowering efficacy of simvastatin.

Effect of rifampicin on the pharmacokinetics and pharmacodynamics of glimepiride

AIMS

To study the effects of rifampicin on the pharmacokinetics and pharmaco-dynamics of glimepiride, a new sulphonylurea antidiabetic drug.

METHODS

In this randomised, two-phase cross-over study, 10 healthy volunteers were treated for 5 days with 600 mg rifampicin or placebo once daily. On day 6, a single oral dose of 1 mg glimepiride was administered. Plasma glimepiride and blood glucose concentrations were measured up to 12 h.

RESULTS

Rifampicin decreased the mean area under the plasma concentration-time curve of glimepiride by 34% (P < 0.001) and the mean elimination half-life by 25% (P < 0.05). No significant differences in the blood glucose response to glimepiride were observed between the placebo and rifampicin phases. However, symptomatic hypoglycaemia occurred only during the placebo phase.

CONCLUSIONS

The effects of rifampicin on the pharmacokinetics of glimepiride suggest that rifampicin induced the CYP2C9-mediated metabolism of glimepiride and thereby slightly increased its systemic clearance. Because the interaction was modest and did not significantly alter the glucose-lowering effect of glimepiride in healthy volunteers, it is probably of limited clinical significance. However, in some patients the hypoglycaemic effect of glimepiride may be reduced during concomitant treatment with rifampicin.

Rifampin decreases the plasma concentrations and effects of repaglinide

OBJECTIVE

To study the effects of rifampin (INN, rifampicin) on the pharmacokinetics and pharmacodynamics of repaglinide, a new short-acting antidiabetic drug.

METHODS

In a randomized, two-phase crossover study, nine healthy volunteers were given a 5-day pretreatment with 600 mg rifampin or matched placebo once daily. On day 6 a single 0.5-mg dose of repaglinide was administered. Plasma repaglinide and blood glucose concentrations were measured up to 7 hours.

RESULTS

Rifampin decreased the total area under the concentration-time curve of repaglinide by 57% (P < .001) and the peak plasma repaglinide concentration by 41% (P = .001). The elimination half-life of repaglinide was shortened from 1.5 to 1.1 hours (P < .01). The blood glucose decremental area under the concentration-time curve from 0 to 3 hours was reduced from 0.94 to -0.23 mmol/L x h (P < .05), and the maximum decrease in blood glucose concentration from 1.6 to 1.0 mmol/L (P < .05) by rifampin.

CONCLUSIONS

Rifampin considerably decreases the plasma concentrations of repaglinide and also reduces its effects. This interaction is probably caused by induction of the CYP3A4-mediated metabolism of repaglinide. It is probable that the effects of repaglinide are decreased during treatment with rifampin or other potent inducers of CYP3A4, such as carbamazepine, phenytoin, or St John's wort.

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.

Effects of metronidazole on midazolam metabolism in vitro and in vivo

OBJECTIVE

Case reports have described elevated concentrations of CYP3A4 substrates (e.g. cyclosporin) during metronidazole treatment. Therefore, we wanted to study whether metronidazole affects CYP3A4 activity, using midazolam as a model substrate in vitro and in vivo.

METHODS

In the in vitro part of the study, the effects of various concentrations of metronidazole (0-500 microM) on the formation of 1'-hydroxymidazolam from midazolam were studied using human liver microsomal preparations (n = 4). In the in vivo part, the effects of metronidazole on the pharmacokinetics and pharmacodynamics of oral midazolam were evaluated in a randomised, placebo-controlled cross-over study in ten healthy subjects. The subjects took either 400 mg metronidazole or matched placebo orally twice daily for 3 days. On day 3, 15 mg midazolam was administered orally. Plasma concentrations of midazolam and 1'-hydroxymidazolam were determined up to 24 h. The effects of midazolam were measured up to 10 h.

RESULTS

Metronidazole (10-500 microM) showed no inhibitory effect on 1'-hydroxymidazolam formation by human liver microsomes. In healthy volunteers, metronidazole had no statistically significant effects on the pharmacokinetics of midazolam and 1'-hydroxymidazolam, and also the ratio of 1'-hydroxymidazolam to midazolam in plasma remained unchanged by metronidazole. The four employed psychomotor tests did not show significant differences between the metronidazole and placebo phases.

CONCLUSION

Metronidazole had no effects on the 1'-hydroxylation of midazolam in vitro or on the pharmacokinetics and pharmacodynamics of midazolam in vivo. These findings indicate that metronidazole is not an inhibitor of CYP3A4.

Duration of effect of grapefruit juice on the pharmacokinetics of the CYP3A4 substrate simvastatin

BACKGROUND

Grapefruit juice is a potent inhibitor of CYP3A4-mediated drug metabolism. We wanted to investigate how long the inhibitory effect of grapefruit juice lasts, with the CYP3A4 substrate simvastatin used as a model drug.

METHODS

This crossover study consisted of 5 study days, during which 10 healthy volunteers ingested 40 mg simvastatin with water (control), with "high-dose" grapefruit juice (200 mL double-strength grapefruit juice three times a day for 3 days), or 1, 3, and 7 days after ingestion of "high-dose" grapefruit juice. For safety reasons, the study was performed in three parts to allow simvastatin-free days between the study days. Serum concentrations of simvastatin and simvastatin acid were measured by liquid chromatography-tandem mass spectrometry up to 12 hours.

RESULTS

When simvastatin was taken with grapefruit juice, the mean peak serum concentration (Cmax) and the mean area under the serum concentration-time curve [AUC(0-infinity)] of simvastatin were increased 12.0-fold (P < .001) and 13.5-fold (P < .001), respectively, compared with control. When simvastatin was administered 24 hours after ingestion of the last dose of grapefruit juice, the Cmax and AUC(0-infinity) were increased 2.4-fold (P < .01) and 2.1-fold (P < .001), respectively, compared with control. When simvastatin was given 3 days after ingestion of grapefruit juice, the Cmax and AUC(0-infinity) were increased 1.5-fold (P = .12) and 1.4-fold (P = .09), respectively, compared with control. Seven days after ingestion of grapefruit juice, no differences in the Cmax or AUC(0-infinity) of simvastatin were seen. The mean Cmax and AUC(0-infinity) of simvastatin acid were increased 5.0-fold and 4.5-fold, respectively (P < .001), compared with control when simvastatin was taken with grapefruit juice and 1.7-fold (P < .01) when it was taken 24 hours after ingestion of grapefruit juice. After an interval of 3 or 7 days between ingestion of grapefruit juice and simvastatin, the pharmacokinetic variables of simvastatin acid did not differ significantly from those in the control phase.

CONCLUSIONS

When simvastatin is taken 24 hours after ingestion of "high-dose" grapefruit juice, the effect of grapefruit juice on the AUC of simvastatin is only about 10% of the effect observed during concomitant intake of grapefruit juice and simvastatin. The interaction potential of even high amounts of grapefruit juice with CYP3A4 substrates dissipates within 3 to 7 days after ingestion of the last dose of grapefruit juice.

Effect of an oral contraceptive preparation containing ethinylestradiol and gestodene on CYP3A4 activity as measured by midazolam 1'-hydroxylation

AIMS

To characterize the effect of an oral contraceptive (OC) containing ethinylestradiol and gestodene on the activity of CYP3A4 in vivo as measured by the 1'-hydroxylation of midazolam.

METHODS

In this randomised, double-blind, cross-over trial nine healthy female subjects received either a combined OC (30 microg ethinylestradiol and 75 microg gestodene) or placebo once daily for 10 days. On day 10, a single 7.5 mg dose of midazolam was given orally. Plasma concentrations of midazolam and 1'-hydroxymidazolam were determined up to 24 h and the effects of midazolam were measured with three psychomotor tests up to 8 h.

RESULTS

The combined OC increased the mean AUC of midazolam by 21% (95% CI 2% to 40%; P = 0.03) and decreased that of 1'-hydroxymidazolam by 25% (95% CI 10% to 41%; P = 0.01), compared with placebo. The metabolic ratio (AUC of 1'-hydroxymidazolam/AUC of midazolam) was 36% smaller (95% CI 19% to 53%; P = 0.01) in the OC phase than in the placebo phase. There were no significant differences in the Cmax, tmax, t(1/2) or effects of midazolam between the phases.

CONCLUSIONS

A combined OC preparation caused a modest reduction in the activity of CYP3A4, as measured by the 1'-hydroxylation of midazolam, and slightly increased the AUC of oral midazolam. This study suggests that, at the doses used, ethinylestradiol and gestodene have a relatively small effect on CYP3A4 activity in vivo.

Grapefruit juice can increase the plasma concentrations of oral methylprednisolone

OBJECTIVE

To investigate whether the pharmacokinetics of orally administered methylprednisolone and plasma cortisol concentrations are affected by administration of grapefruit juice.

METHODS

In a randomised, two-phase, cross-over study, ten healthy subjects received either 200 ml double-strength grapefruit juice or water three times a day for 2 days. On day 3, 16 mg methylprednisolone was given orally with 200 ml grapefruit juice or water. Additionally, 200 ml grapefruit juice or water was ingested 0.5 h and 1.5 h after methylprednisolone administration. Plasma concentrations of methylprednisolone and cortisol were determined using liquid chromatography/mass spectrometry (LC/MS/MS) over a 47-h period.

RESULTS

Grapefruit juice increased the total area under the plasma methylprednisolone concentration-time curve (AUC 0--infinity) by 75% (P < 0.001) and the elimination half-life (t1/2) of methylprednisolone by 35% (P < 0.001). The peak plasma concentration of methylprednisolone (Cmax) was increased by 27% (P < 0.01). Grapefruit juice delayed the time to the Cmax from 2.0 h to 3.0 h (P < 0.05). There was no significant difference in the plasma cortisol concentrations, measured after methylprednisolone administration, between the water and grapefruit juice phases. However, grapefruit juice slightly decreased the morning plasma cortisol concentrations before methylprednisolone administration (P < 0.05).

CONCLUSIONS

Grapefruit juice given in high amounts moderately increases the AUC 0--infinity and t1/2 of oral methylprednisolone. The increase in t1/2 suggests that grapefruit juice can affect the systemic methylprednisolone metabolism. The clinical significance of the grapefruit juice-methylprednisolone interaction is small, but in some sensitive subjects high doses of grapefruit juice might enhance the effects of oral methylprednisolone.

Involvement of CYP1A2 and CYP3A4 in lidocaine N-deethylation and 3-hydroxylation in humans

The roles of cytochrome P-450 (CYP) enzymes in the N-deethylation, i.e., formation of monoethylglycinexylidide (MEGX), and 3-hydroxylation of lidocaine were studied with human liver microsomes and recombinant human CYP isoforms. Both CYP1A2 and CYP3A4 were found to be capable of catalyzing the formation of MEGX and 3-OH-lidocaine. Lidocaine N-deethylation by liver microsomes was strongly inhibited by furafylline (by about 60%) and anti-CYP1A1/2 antibodies (>75%) at 5 microM lidocaine, suggesting that CYP1A2 was the major isoform catalyzing lidocaine N-deethylation at low (therapeutically relevant) lidocaine concentrations. Troleandomycin inhibited the N-deethylation of lidocaine by about 50% at 800 microM lidocaine, suggesting that the role of CYP3A4 may be more important than that of CYP1A2 at high lidocaine concentrations. Chemical inhibition and immunoinhibition studies also indicated that 3-OH-lidocaine formation was catalyzed almost exclusively by CYP1A2, CYP3A4 playing only a minor role. Although the CYP2C9 inhibitor sulfaphenazole (100 microM) inhibited MEGX formation by about 30%, recombinant human CYP2C9 showed very low catalytic activity, suggesting a negligible role for this enzyme in lidocaine N-deethylation. Chemical inhibition studies indicated that CYP2C19, CYP2D6, and CYP2E1 did not play significant roles in the metabolism of lidocaine in vitro. Taken together, these results demonstrate that CYP1A2 and CYP3A4 enzymes are the major CYP isoforms involved in lidocaine N-deethylation. Therefore, the MEGX test (formation of MEGX from lidocaine) is not a suitable marker of hepatic CYP3A4 activity in vivo.

Effect of grapefruit juice dose on grapefruit juice-triazolam interaction: repeated consumption prolongs triazolam half-life

OBJECTIVE

Grapefruit juice inhibits CYP3A4-mediated metabolism of several drugs during first pass. In this study, the effect of grapefruit juice dose on the extent of grapefruit juice-triazolam interaction was investigated.

METHODS

In a randomised, four-phase, crossover study, 12 healthy volunteers received 0.25 mg triazolam with water, with 200 ml normal-strength or double-strength grapefruit juice or, on the third day of multiple-dose [three times daily (t.i.d.)] administration of double-strength grapefruit juice. Timed blood samples were collected up to 23 h after dosing, and the effects of triazolam were measured with four psychomotor tests up to 10 h after dosing.

RESULTS

The area under the plasma triazolam concentration time curve (AUC(0-infinity)) was increased by 53% (P < 0.01), 49% (P < 0.01) and 143% (P < 0.001) by a single dose of normal-strength, a single dose of double-strength and multiple-dose administration of double-strength grapefruit juice, respectively. The peak plasma concentration (Cmax) of triazolam was increased by about 40% by a single dose of normal-strength grapefruit juice (P < 0.01) and multiple-dose grapefruit juice (P < 0.01) and by 25% by a single dose of double-strength grapefruit juice (P < 0.05). The elimination half-life (t(1/2)) of triazolam was prolonged by 54% during the multiple-dose grapefruit juice phase (P < 0.001). A significant increase in the pharmacodynamic effects of triazolam was seen during the multiple-dose grapefruit juice phase in the digit symbol substitution test (DSST, P < 0.05), in subjective overall drug effect (P < 0.05) and in subjective drowsiness (P < 0.05).

CONCLUSIONS

Even one glass of grapefruit juice increases plasma triazolam concentrations, but repeated consumption of grapefruit juice produces a significantly greater increase in triazolam concentrations than one glass of juice. The t(1/2) of triazolam is prolonged by repeated consumption of grapefruit juice, probably due to inhibition of hepatic CYP3A4 activity.

Plasma concentrations of active simvastatin acid are increased by gemfibrozil

BACKGROUND

Concomitant treatment with simvastatin and gemfibrozil, two lipid-lowering drugs, has been associated with occurrence of myopathy in case reports. The aim of this study was to determine whether gemfibrozil affects the pharmacokinetics of simvastatin and whether it affects CYP3A4 activity in vitro.

METHODS

A double-blind, randomized crossover study with two phases (placebo and gemfibrozil) was carried out. Ten healthy volunteers were given gemfibrozil (600 mg twice daily) or placebo orally for 3 days. On day 3 they ingested a single 40-mg dose of simvastatin. Plasma concentrations of simvastatin and simvastatin acid were measured up to 12 hours. In addition, the effect of gemfibrozil (0 to 1,200 micromol/L) on midazolam 1'-hydroxylation, a CYP3A4 model reaction, was investigated in human liver microsomes in vitro.

RESULTS

Gemfibrozil increased the mean total area under the plasma concentration-time curve of simvastatin [AUC(0-infinity)] by 35% (P < .01) and the AUC(0-infinity) of simvastatin acid by 185% (P < .001). The elimination half-life of simvastatin was increased by 74% (P < .05), and that of simvastatin acid was increased by 51% (P < .01) by gemfibrozil. The peak concentration of simvastatin acid was increased by 112%, from 3.20 +/- 2.73 ng/mL to 6.78 +/- 4.67 ng/mL (mean +/- SD; P < .01). In vitro, gemfibrozil showed no inhibition of midazolam 1'-hydroxylation.

CONCLUSIONS

Gemfibrozil increases plasma concentrations of simvastatin and, in particular, its active form, simvastatin acid, suggesting that the increased risk of myopathy in combination treatment is, at least partially, of a pharmacokinetic origin. Because gemfibrozil does not inhibit CYP3A4 in vitro, the mechanism of the pharmacokinetic interaction is probably inhibition of non-CYP3A4-mediated metabolism of simvastatin acid.

Efficacy of activated charcoal versus gastric lavage half an hour after ingestion of moclobemide, temazepam, and verapamil

OBJECTIVE

To compare the efficacy of activated charcoal and gastric lavage in preventing the absorption of moclobemide, temazepam, and verapamil 30 min after drug ingestion.

METHODS

In this randomized cross-over study with three phases, nine healthy volunteers received a single oral dose of 150 mg moclobemide, 10 mg temazepam, and 80 mg verapamil after an overnight fast. Thirty minutes later, they were assigned to one of the following treatments: 25 g activated charcoal as a suspension in 200 ml water, gastric lavage (10x200 ml), or 200 ml water (control). Plasma concentrations of moclobemide, temazepam, and verapamil were determined up to 24 h.

RESULTS

Activated charcoal reduced the area under the plasma concentration time curve from 0 h to 24 h (AUC0-24 h) of moclobemide and temazepam by 55% (P<0.05) and by 45% (P<0.05), respectively. The AUC0-24 h of verapamil was not significantly reduced by charcoal. Gastric lavage decreased the AUC0-24 h of moclobemide by 44% (P<0.05), but had no significant effect on that of temazepam or verapamil. The peak plasma concentration (Cmax) of moclobemide, temazepam, and verapamil was reduced by 40%, 29% (P<0.05), and 16%, respectively, by activated charcoal. Gastric lavage did not significantly decrease the Cmax of any of these drugs.

CONCLUSION

The absorption of moclobemide, temazepam, and verapamil can be moderately reduced by activated charcoal given 30 min after drug ingestion, while gastric lavage seems to be less effective.

Effect of fluconazole on plasma fluvastatin and pravastatin concentrations

OBJECTIVE

To study the effects of fluconazole on the pharmacokinetics of fluvastatin and pravastatin, two inhibitors of 3-hydroxy-3-methylglutaryl-coenzyme A (HMG-CoA) reductase.

METHODS

Two separate randomised, double-blind, two-phase, crossover studies with identical study design were carried out. In each study, 12 healthy volunteers were given a 4-day pretreatment with oral fluconazole (400 mg on day 1 and 200 mg on days 2-4) or placebo, according to a randomisation schedule. On day 4, a single oral dose of 40 mg fluvastatin (study I) or 40 mg pravastatin (study II) was administered orally. Plasma concentrations of fluvastatin, pravastatin and fluconazole were measured over 24 h.

RESULTS

In study 1, fluconazole increased the mean area under the plasma fluvastatin concentration-time curve (AUC0-infinity) by 84% (P < 0.01), the mean elimination half-life (t1/2) of fluvastatin by 80% (P < 0.01) and its mean peak plasma concentration (Cmax) by 44% (P < 0.05). In study II, fluconazole had no significant effect on the pharmacokinetics of pravastatin.

CONCLUSIONS

Fluconazole has a significant interaction with fluvastatin. The mechanism of the increased plasma concentrations and prolonged elimination of fluvastatin is probably inhibition of the CYP2C9-mediated metabolism of fluvastatin by fluconazole. Care should be taken if fluconazole or other potent inhibitors of CYP2C9 are prescribed to patients using fluvastatin. However, pravastatin is not susceptible to interactions with fluconazole or other potent CYP2C9 inhibitors.

Lack of correlation between in vitro and in vivo studies on the effects of tangeretin and tangerine juice on midazolam hydroxylation

BACKGROUND

Tangeretin is a flavonoid that stimulates the catalytic activity of cytochrome P450 3A4 (CYP3A4) and is found in high levels in tangerine juice.

METHODS

The effect of tangeretin on hydroxylation of midazolam, a CYP3A4 probe, was examined in vitro with human liver microsomes and recombinant CYP3A4. In addition, the effect of tangerine juice on the pharmacokinetics and pharmacodynamics of orally administered midazolam (15 mg) and its active 1'-hydroxymetabolite was studied in a randomized crossover study in eight healthy volunteers.

RESULTS

In microsomes from three human livers, tangeretin (1 to 100 micromol/L) increased 1'-hydroxymidazolam formation (12.5 micromol/L midazolam) by up to 212%. In complementary deoxyribonucleic acid-expressed CYP3A4, a 52% stimulation of midazolam 1'-hydroxylation was reached at 50 micromol/L tangeretin with no effect on midazolam 4-hydroxylation. In the pharmacokinetic-pharmacodynamic study, 200 mL tangerine juice reduced the area under the concentration versus time curve to 1.5 hours [AUC(O-1.5h)] of midazolam and 1'-hydroxymidazolam by 39% and 46%, respectively, and prolonged the time to reach peak concentration (P < .05) without affecting the total AUC values, elimination half-life values, or AUC ratios (1'-hydroxymidazolam/midazolam). These findings are consistent with a small delay in the absorption of midazolam and lack of effect on midazolam 1'-hydroxylation. Accordingly, tangerine juice slightly postponed the maximum pharmacodynamic effects of midazolam (P < .05).

CONCLUSION

Tangeretin is a potent regioselective stimulator of midazolam 1'-hydroxylation by human liver microsomes and complementary deoxyribonucleic acid-expressed CYP3A4. However, tangerine juice is unlikely to have any appreciable effect on CYP3A4 in humans. Further studies are required to assess whether in vitro stimulators of CYP3A4 can influence drug metabolism in vivo.

The effect of itraconazole on the pharmacokinetics and pharmacodynamics of oral prednisolone

OBJECTIVE

To examine the possible effect of itraconazole on the pharmacokinetics and pharmacodynamics of orally administered prednisolone.

METHODS

In this double-blind, randomised, two-phase cross-over study, ten healthy subjects received either 200 mg itraconazole or placebo orally once a day for 4 days. On day 4, 20 mg prednisolone was given orally. Plasma concentrations of prednisolone, cortisol, itraconazole, and hydroxyitraconazole were determined by means of high-performance liquid chromatography up to 47 h.

RESULTS

Itraconazole increased the total area under the plasma prednisolone concentration-time curve by 24% (P < 0.001) and the elimination half-life of prednisolone by 29% (P < 0.001) compared with placebo. The peak plasma concentration and time to the peak of prednisolone were not affected by itraconazole. The mean morning plasma cortisol concentration, measured 23 h after the ingestion of prednisolone, during the itraconazole phase was 73% of that during the placebo phase (P < 0.001).

CONCLUSIONS

The observed minor interaction between itraconazole and oral prednisolone is probably of limited clinical significance. The susceptibility of prednisolone to interact with CYP3A4 inhibitors is considerably smaller than that of methylprednisolone, and itraconazole and probably also other inhibitors of CYP3A4 can be used concomitantly with prednisolone without marked changes in the effects of this corticosteroid.

Diltiazem and mibefradil increase the plasma concentrations and greatly enhance the adrenal-suppressant effect of oral methylprednisolone

OBJECTIVE

To examine the possible interaction of the calcium channel blockers diltiazem and mibefradil with orally administered methylprednisolone.

METHODS

In this randomized, double-blind, placebo-controlled, three-phase crossover study, nine healthy SUBJECTS received 60 mg diltiazem three times a day, 50 mg mibefradil once a day, or placebo orally for 3 days. On day 3, each subject received a 16-mg oral dose of methylprednisolone. Plasma concentrations of methylprednisolone and cortisol were determined by HPLC up to 47 hours.

RESULTS

Compared with placebo, diltiazem and mibefradil increased the total area under the plasma concentration-time curve of methylprednisolone [AUC(0-infinity)] 2.6-fold (P < .001) and 3.8-fold (P < .001), the peak plasma concentration 1.6-fold (P < .001) and 1.8-fold (P < .001), and the elimination half-life 1.9-fold (P < .001) and 2.7-fold (P < .001), respectively. The nighttime exposure to methylprednisolone [AUC(12-23)] was increased 28.2-fold (P < .01) and 72.1-fold (P < .001) by diltiazem and mibefradil, respectively, and correlated negatively (r = -0.81, P < .001) with the morning plasma cortisol concentration (measured at 8 AM, 23 hours after the administration of methylprednisolone). During the diltiazem phase, the morning plasma cortisol concentration was 12% of that during the placebo phase (P < .001); during the mibefradil phase, the morning plasma cortisol concentration was 2% of that during the placebo phase (P < .001).

CONCLUSIONS

Coadministration of diltiazem or mibefradil with methylprednisolone resulted in increased plasma concentrations and a greatly enhanced adrenal-suppressant effect of oral methylprednisolone. Care should be taken if methylprednisolone is coadministered with a potent CYP3A4 inhibitor for a long period.

Gastric decontamination performed 5 min after the ingestion of temazepam, verapamil and moclobemide: charcoal is superior to lavage

AIMS

The aim was to study the efficacy of gastric lavage and activated charcoal in preventing the absorption of temazepam, verapamil and moclobemide when gastric decontamination was performed immediately after ingestion of the drugs.

METHODS

Nine healthy volunteers took part in a randomized cross-over study with three phases. The subjects were administered single oral doses of 10 mg temazepam, 80 mg verapamil and 150 mg moclobemide. Five minutes later, they were assigned to one of the following treatments: 200 ml water (control), 25 g activated charcoal as a suspension in 200 ml water or gastric lavage. Plasma concentrations and the cumulative excretion into urine of the three drugs were determined up to 24 h.

RESULTS

The mean AUC(0,24 h) of temazepam, verapamil and moclobemide was reduced by 95.2% (P < 0.01), 92.8% (P < 0.01) and 99. 7% (P < 0.01), respectively, by activated charcoal compared with control. Gastric lavage did not reduce significantly the AUC(0,24 h) of these drugs. The 24 h cumulative excretion of temazepam, verapamil and moclobemide into urine was reduced significantly (P < 0.05) by charcoal but not by gastric lavage. Charcoal reduced the AUC(0,24 h), Cmax and urinary excretion of all three drugs significantly more than lavage.

CONCLUSIONS

Activated charcoal is very effective and gastric lavage can be rather ineffective in preventing the absorption of temazepam, verapamil and moclobemide when the treatment is given very rapidly after ingestion of the drugs, before tablet disintegration has occurred.

Cytochrome P450-inducing antiepileptics increase the clearance of vincristine in patients with brain tumors

BACKGROUND

Vincristine is at least partly metabolized by CYP3A4. We have studied the possible effect of the CYP3A4-inducing antiepileptic agents carbamazepine and phenytoin on the pharmacokinetics of vincristine.

METHODS

Fifteen adult patients with brain tumors receiving combination chemotherapy with procarbazine, lomustine, and vincristine volunteered for this open parallel-group study. Nine of the patients used either carbamazepine or phenytoin and six of the patients used no obvious CYP3A4-inducing medication. After intravenous infusion of 2 mg vincristine, timed blood samples were collected up to 24 hours. Plasma vincristine concentrations were measured by liquid chromatography-tandem mass spectrometry. The pharmacokinetics of vincristine were compared between the two patient groups.

RESULTS

The systemic clearance of vincristine was 63% higher (925 +/- 61 versus 569 +/- 76 mL/min [mean +/- SEM]; P = .004), the elimination half-life was 35% shorter (12.7 +/- 0.6 versus 19.4 +/- 3.6 hours; P = .13), and the total area under the plasma concentration-time curve was 43% smaller (37.3 +/- 2.4 versus 65.1 +/- 10.1 ng x h/mL; P = .04) in patients who were receiving carbamazepine or phenytoin than in the control group.

CONCLUSIONS

Drugs that induce CYP3A4 can increase the elimination of vincristine. Further studies are needed to determine whether the increased clearance of vincristine by carbamazepine or phenytoin decreases the efficacy of vincristine.

Clozapine serum concentrations are lower in smoking than in non-smoking schizophrenic patients

Serum concentrations of clozapine and its main metabolite demethylclozapine were measured in 44 schizophrenic inpatients, of whom ten were non-smokers and 34 smokers. When comparing their clozapine dose and body weight-related serum drug levels, we found that clozapine and demethylclozapine concentrations were about 40% lower in the smoking than in the non-smoking group, probably due to an inducing effect of smoking on the cytochrome P450 (CYP) 1A2, which is involved in the metabolism of clozapine. We conclude that dosage adjustment may be necessary in clozapine-treated smokers.

Fluvoxamine is a more potent inhibitor of lidocaine metabolism than ketoconazole and erythromycin in vitro

CYP3A4 is generally believed to be the major CYP enzyme involved in the biotransformation of lidocaine in man; however, recent in vivo studies suggest that this may not be the case. We have examined the effects of the CYP3A4 inhibitors erythromycin and ketoconazole and the CYP1A2 inhibitor fluvoxamine on the N-deethylation, i.e. formation of monoethylglycinexylidide (MEGX), and 3-hydroxylation of lidocaine by human liver microsomes. The experiments were carried out at lidocaine concentrations of 5 microM (clinically relevant concentration) and 800 microM. The formation of both MEGX and 3-hydroxylidocaine was best described by a two-enzyme model. At 5 microM of lidocaine, fluvoxamine was a potent inhibitor of the formation of MEGX (IC50 1.2 microM). Ketoconazole and erythromycin also showed an inhibitory effect on MEGX formation, but ketoconazole (IC50 8.5 microM) was a much more potent inhibitor than erythromycin (IC50 200 microM). At 800 microM of lidocaine, fluvoxamine (IC50 20.7 microM) and ketoconazole (IC50 20.4 microM) displayed a modest inhibitory effect on MEGX formation, whereas erythromycin was a weak inhibitor (IC50 >250 microM). The 3-hydroxylation of lidocaine was potently inhibited by fluvoxamine at both lidocaine concentrations (IC50 0.16 microM at 5 microM and 1.8 microM at 800 microM). Erythromycin and ketoconazole showed a clear inhibitory effect on the 3-hydroxylation of lidocaine at 5 microM of lidocaine (IC50 9.9 microM and 13.9 microM, respectively), but did not show a consistent effect at 800 microM of lidocaine (IC50 >250 microM and 75.0 microM, respectively). Although further studies are needed to elucidate the role of distinct CYP enzymes in the biotransformation of lidocaine in humans, the findings of this study suggest that while both CYP1A2 and CYP3A4 are involved in the metabolism of lidocaine by human liver microsomes, CYP1A2 is the more important isoform at clinically relevant lidocaine concentrations.

Repeated consumption of grapefruit juice considerably increases plasma concentrations of cisapride

BACKGROUND

Grapefruit juice increases the bioavailability of several drugs that are metabolized during first pass by CYP3A4. In this study, the effect of grapefruit juice on the pharmacokinetics of orally administered cisapride was investigated.

METHODS

In a randomized, two-phase crossover study, 10 healthy volunteers took either 200 mL double-strength grapefruit juice or water three times a day for 2 days. On day 3, each subject ingested 10 mg cisapride with either 200 mL grapefruit juice or water, and an additional 200 mL was ingested 1/2 hour and 1 1/2 hours after cisapride administration. Timed blood samples were collected for 32 hours after cisapride intake, and a standard 12-lead ECG was recorded before the administration of cisapride and 2, 5, 8, and 12 hours later.

RESULTS

The mean peak plasma concentration of cisapride was increased by 81% (range, 38% to 138%; P < .01) and the total area under the plasma cisapride concentration-time curve by 144% (range, 65% to 244%; P < .01) by grapefruit juice. The time of the peak concentration of cisapride was prolonged from 1.5 to 2.5 hours (P < .05) and the elimination half-life from 6.8 to 8.4 hours (P < .05) by grapefruit juice. ECG tracings did not show any significant differences in the QTc interval between the grapefruit juice and control phases.

CONCLUSIONS

Grapefruit juice significantly increases plasma concentrations of cisapride, probably by inhibition of the CYP3A4-mediated first-pass metabolism of cisapride in the small intestine. Concomitant use of high amounts of grapefruit juice and cisapride should be avoided, at least in patients with risk factors for cardiac arrhythmia.

Midazolam alpha-hydroxylation by human liver microsomes in vitro: inhibition by calcium channel blockers, itraconazole and ketoconazole

The inhibitory effects of five calcium channel blockers (diltiazem, isradipine, mibefradil, nifedipine and verapamil) and three azole antifungal agents (itraconazole, hydroxyitraconazole and ketoconazole) on the alpha-hydroxylation of midazolam, a probe drug for CYP3A4-mediated interactions in humans, were studied in vitro using human liver microsomes. IC50 and Ki values were determined for each inhibitor. The kinetics of the formation of alpha-hydroxymidazolam were best described by simple Michaelis-Menten kinetics. The estimated values of Vmax and Km were 696 pmol min.-(1) mg(-1) and 7.46 micromol l(-1), respectively. All the compounds studied inhibited midazolam alpha-hydroxylation activity in a concentration-dependent manner, but there were marked differences in their relative inhibitory potency. Ketoconazole was the most potent inhibitor of midazolam alpha-hydroxylation (IC50 0.12 micromol l (-1)), being 10 times more potent than itraconazole (IC50 1.2 micromol l(-1)). The inhibitory effect of hydroxyitraconazole (IC50 2.3 micromol l (-1) was almost as large as that of itraconazole. Among the calcium channel blockers, mibefradil was the most potent inhibitor of the alpha-hydroxylation of midazolam, with an IC50 value (1.6 micromol l (-1)) similar to that of itraconazole. The other calcium channel blockers were much weaker inhibitors than mibefradil: verapamil exhibited a modest inhibitory effect with an IC50 of 23 micromol l(-1), while isradipine, nifedipine and diltiazem, with IC50 values ranging from 57 to >100 micromol l (-1), were weak inhibitors. This rank order of potency against the alpha-hydroxylation Qf midazolam was verified by the Ki values. With the exception of diltiazem, these in vitro results conform with the observed interaction potential of these agents with midazolam and many other CYP3A4 substrates in vivo in man.

Mibefradil but not isradipine substantially elevates the plasma concentrations of the CYP3A4 substrate triazolam

BACKGROUND

The calcium channel blockers mibefradil and isradipine inhibit CYP3A4 in vitro. However, their in vivo inhibitory effects on CYP3A4 are not known in detail, although mibefradil was recently withdrawn from the market because of serious drug interactions.

METHODS

The effects of mibefradil and isradipine on the pharmacokinetics and pharmacodynamics of oral triazolam, a model substrate of CYP3A4, were studied in a randomized, double-blind crossover study with three phases. Nine healthy subjects took 50 mg mibefradil, 5 mg isradipine, or placebo orally once a day for 3 days. On day 3, each subject received a single 0.25 mg oral dose of triazolam. Thereafter, blood samples were collected up to 18 hours, and pharmacodynamic effects of triazolam were measured up to 8 hours.

RESULTS

Mibefradil increased the total area under the plasma triazolam concentration-time curve [AUC(0 - infinity)] 9-fold compared with placebo (P < .001). The peak plasma concentration of triazolam was increased 1.8-fold (3.4+/-0.1 ng/mL versus 1.8+/-0.2 ng/mL [mean +/- SEM]; P < .001), and the elimination half-life (t 1/2) was increased 4.9-fold (18.5+/-1.9 hours versus 4.0+/-0.5 hours; P < .001) by mibefradil. In addition, mibefradil was associated with increased pharmacodynamic effects of triazolam. In contrast to mibefradil, isradipine reduced the AUC(0 - infinity) and t 1/2 of triazolam by about 20% (P < .05) and had no significant effects on the pharmacodynamics of triazolam.

CONCLUSION

Mibefradil but not isradipine markedly increases the plasma concentrations of triazolam and thereby enhances and prolongs its pharmacodynamic effects, consistent with potent inhibition of CYP3A4.

Effect of activated charcoal alone or given after gastric lavage in reducing the absorption of diazepam, ibuprofen and citalopram

AIMS

The efficacy of activated charcoal alone, and gastric lavage followed by charcoal in reducing the absorption of diazepam, ibuprofen and citalopram was studied in healthy volunteers.

METHODS

In a randomized cross-over study with three phases, nine healthy volunteers were administered single oral doses of 5 mg diazepam, 400 mg ibuprofen and 20 mg citalopram, taken simultaneously after an overnight fast. Thirty minutes later, the subjects were assigned to one of the following treatments: 200 ml water (control), 25 g activated charcoal as a suspension in 200 ml water or gastric lavage followed by 25 g charcoal in suspension given through the lavage tube. Plasma concentrations of diazepam, ibuprofen and citalopram were determined up to 10 h.

RESULTS

The AUC(0,10 h) of diazepam was reduced by 27% (P<0.05) by both charcoal alone and charcoal combined with lavage. The increase in plasma diazepam concentration from 0.5 h onwards was prevented by both interventions (P</=0.05), whereas the Cmax of diazepam was not significantly affected by either treatment. The AUC(0, 10 h) of ibuprofen was reduced by 49% (P<0.05) after the combination treatment and by 30% (P<0.05) after charcoal alone, but there was no significant difference between these two treatments. Both charcoal alone and the combination treatment were equally effective in preventing the increase in plasma ibuprofen from 0.5 h onwards (P<0.01). The Cmax of ibuprofen was reduced by 45% (P<0.05) and by 21% (P=NS), respectively. The AUC(0,10 h) of citalopram was reduced by 51% (P<0.05) after both charcoal alone and charcoal combined with lavage, and the Cmax by 52% (P<0.05) and 54% (P<0.05), respectively. The increase in plasma citalopram concentration from 0.5 h onwards was reduced by about 50% (P<0.01) by both interventions.

CONCLUSIONS

Activated charcoal alone and charcoal combined with lavage showed similar efficacy in preventing the absorption of diazepam, ibuprofen and citalopram. These results suggest that gastric lavage needs not be routinely performed before administration of charcoal.

Grapefruit juice increases serum concentrations of atorvastatin and has no effect on pravastatin

BACKGROUND

Grapefruit juice greatly increases the bioavailability of lovastatin and simvastatin. We studied the effect of grapefruit juice on the pharmacokinetics of atorvastatin and pravastatin.

METHODS

Two randomized, two-phase crossover studies were performed--study I with atorvastatin in 12 healthy volunteers and study II with pravastatin in 11 healthy volunteers. In both studies, volunteers took 200 mL double-strength grapefruit juice or water three times a day for 2 days. On day 3, each subject ingested a single 40 mg dose of atorvastatin (study I) or pravastatin (study II) with either 200 mL grapefruit juice or water, and an additional 200 mL was ingested 1/2 hour and 1 1/2 hours later. In addition, subjects took 200 mL grapefruit juice or water three times a day on days 4 and 5 in study I. In study I, serum concentrations of atorvastatin acid, atorvastatin lactone, 2-hydroxyatorvastatin acid, 2-hydroxyatorvastatin lactone, and active and total 3-hydroxy-3-methylglutaryl coenzyme A (HMG-CoA) reductase inhibitors were measured up to 72 hours. In study II, pravastatin, pravastatin lactone, and active and total HMG-CoA reductase inhibitors were measured up to 24 hours.

RESULTS

Grapefruit juice increased the area under the serum concentration-time curve of atorvastatin acid from time zero to 72 hours [AUC(0-72)] 2.5-fold (P < .01), whereas the peak serum concentration (Cmax) was not significantly changed. The time of the peak concentration (tmax) and the elimination half-life (t1/2) of atorvastatin acid were increased (P < .01). The AUC(0-72) of atorvastatin lactone was increased 3.3-fold (P < .01) and the Cmax 2.6-fold (P < .01) by grapefruit juice, and the tmax and t1/2 were also increased (P < .05). Grapefruit juice decreased the Cmax (P < .001) and AUC(0-72) (P < .001) of 2-hydroxyatorvastatin acid and increased its tmax and t1/2 (P < .01). Grapefruit juice also decreased the Cmax (P < .001) and AUC(O-72) (P < .05) of 2-hydroxyatorvastatin lactone. The AUC(0-72) values of active and total HMG-CoA reductase inhibitors were increased 1.3-fold (P < .05) and 1.5-fold (P < .01), respectively, by grapefruit juice. In study II, the only significant change observed in the pharmacokinetics of pravastatin was prolongation of the tmax of active HMG-CoA reductase inhibitors by grapefruit juice (P < .05).

CONCLUSIONS

Grapefruit juice significantly increased serum concentrations of atorvastatin acid, atorvastatin lactone, and active and total HMG-CoA reductase inhibitors, probably by decreasing CYP3A4-mediated first-pass metabolism of atorvastatin in the small intestine. On the other hand, grapefruit juice had no effect on the pharmacokinetics of pravastatin. Concomitant use of atorvastatin and at least large amounts of grapefruit juice should be avoided, or the dose of atorvastatin should be reduced accordingly.

Itraconazole decreases the clearance and enhances the effects of intravenously administered methylprednisolone in healthy volunteers

A possible interaction of itraconazole, a potent inhibitor of CYP3A4, with intravenously administered methylprednisolone, was examined. In this double-blind, randomized, two-phase cross-over study, 9 healthy volunteers received either 200 mg itraconazole or matched placebo orally once a day for 4 days. On day 4, a dose of 16 mg methylprednisolone as sodium succinate was administered intravenously. Plasma concentrations of methylprednisolone, cortisol, itraconazole, and hydroxyitraconazole were determined up to 24 hr. Itraconazole increased the total area under the plasma methylprednisolone concentration-time curve (AUC(0-infinity) 2.6-fold) (P<0.001), while the AUC (12-24) of methylprednisolone was increased 12.2-fold (P<0.001). The systemic clearance of methylprednisolone during the itraconazole phase was 40% of that during the placebo phase (P<0.01). The volume of distribution of methylprednisolone was not affected by itraconazole. The mean elimination half-life of methylprednisolone was increased from 2.1+/-0.3 hr to 4.8+/-0.8 hr (P<0.001) by itraconazole. The mean morning plasma cortisol concentration during the itraconazole phase, measured 24 hr after the administration of methylprednisolone, was only about 9% of that during the placebo phase (11.0+/-9.0 ng/ml versus 117+/-49.2 ng/ml; P<0.001). In conclusion, itraconazole decreases the clearance and increases the elimination half-life of intravenously administered methylprednisolone, resulting in greatly increased exposure to methylprednisolone during the night time and in enhanced adrenal suppression. Care should be taken when itraconazole or other potent inhibitors of CYP3A4 are used concomitantly with methylprednisolone.

Quantitative immunohistochemical analysis of the glutathione S-transferase GSTM1: in situ phenotyping in archival material

1. GSTM1 is present in only approximately 50% of Caucasian individuals and deficiency of GSTM1 is associated with susceptibility to a growing number of diseases, especially cancer. Thus, a method that would allow accurate, retrospective determination of the GSTM1 phenotype in different patient populations would have many applications. 2. Developed, therefore, is a quantitative, image-analysis-based immunohistochemical technique for the analysis of GSTM1 protein in paraffin-embedded tissue samples. It was applied to the determination of the GSTM1 phenotype using liver biopsies taken from 70 patients. 3. Of the 70 cases (depending on the cut-off point), 51-54% were deficient in GSTM1. A single 27 kD band characteristic for GSTM1 was found in seven of 16 cases analysed by Western blotting using the same GSTM1 antibody as in the immunohistochemical analysis. There was a good correlation (r = 0.87) between the staining intensity of the GSTM1 band and the staining intensity evaluated by immunohistochemistry. 4. It is concluded that this quantitative immunohistochemical method permits accurate determination of the GSTM1 phenotype and is well suited for retrospective analysis of GSTM1 expression in specific tissues in situ.

Determination of buspirone and 1-(2-pyrimidinyl)-piperazine (1-PP) in human plasma by capillary gas chromatography

Two separate gas chromatographic methods for the determination of buspirone and its active metabolite, 1-(2-pyrimidinyl)-piperazine (1-PP) in human plasma are described. Both procedures involve solid-phase extraction (the packing material of the cartridges used was C8 for buspirone and a mixed-mode sorbent for 1-PP), injection of the sample into a gas chromatograph equipped with a fused-silica capillary column and a nitrogen-phosphorus detector, and analysis with temperature programming (from 220 degrees C to 285 degrees C for buspirone and from 138 degrees C to 285 degrees C for 1-PP). The coating material of the analytical column was 5% diphenyl dimethyl silicone for buspirone and 50% diphenyl dimethyl silicone for 1-PP. Zolpidem was used as an internal standard in the buspirone assay and 1-phenylpiperazine in the 1-PP assay. Recovery of buspirone and 1-PP averaged 98% and 89%, respectively, and the limit of quantification was 0.2 ng/mL for both compounds. The between-run coefficients of variation ranged from 3.2% to 9.4% and from 2.9% to 8.6% for samples spiked with three different concentrations of buspirone and 1-PP, respectively. The suitability of these assays for pharmacokinetic studies was shown by analyzing timed plasma samples from volunteers after ingestion of a single therapeutic dose of buspirone (10 mg).

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.

Lack of effect of terfenadine on the pharmacokinetics of the CYP3A4 substrate buspirone

The effects of terfenadine, a non-sedating antihistamine on the pharmacokinetics and pharmacodynamics of buspirone, a CYP3A4 substrate, were investigated in a randomised, placebo-controlled, two-phase cross-over study. Ten healthy volunteers took either 120 mg terfenadine or matched placebo orally once daily for 3 days. On day 3, 10 mg buspirone was taken orally. Plasma concentrations of buspirone were measured up to 18 hr and its pharmacodynamic effects up to 8 hr. Terfenadine slightly but not significantly increased plasma concentrations of buspirone. No psychomotor deterioration was observed during the terfenadine phase. In conclusion, terfenadine did not significantly affect the pharmacokinetics of buspirone, a CYP3A4 substrate shown to be very susceptible to interactions with CYP3A4 inhibitors. Thus, terfenadine is expected to have little effect on the pharmacokinetics of CYP3A4 substrates in general.

Interactions of buspirone with itraconazole and rifampicin: effects on the pharmacokinetics of the active 1-(2-pyrimidinyl)-piperazine metabolite of buspirone

The effects of inhibition and induction of the metabolism of buspirone on the plasma concentrations of 1-(2-pyrimidinyl)-piperazine (a piperazine metabolite), the principal active metabolite of buspirone, were investigated. Two separate randomized, placebo-controlled cross-over studies with two phases were carried out in healthy volunteers. In Study I, six subjects took itraconazole 200 mg daily or matched placebo orally for 4 days. On day 4, 10 mg buspirone was administered orally. In study II, six subjects took rifampicin 600 mg daily or matched placebo orally for 5 days. On day 6, 30 mg buspirone was administered orally. Buspirone and piperazine metabolite concentrations in plasma were determined by gas chromatography. Itraconazole decreased the mean AUC of the piperazine metabolite by 50% (P<0.05) and the Cmax by 57% (P<0.05) compared with placebo, whereas the mean AUC and Cmax of unchanged buspirone were increased 14.5-fold (P<0.05) and 10.5-fold (P<0.05), respectively, by itraconazole. Rifampicin had no significant effect on the AUC of the piperazine metabolite, but it increased the mean Cmax of the piperazine metabolite by 35% (P=0.08). The mean AUC and Cmax of parent buspirone were reduced by 91% (P<0.05) and 85% (P<0.05), respectively, by rifampicin. The mean ratio of the AUC of the piperazine metabolite to that of buspirone was decreased 34-fold (P<0.05) by itraconazole and increased 7.6-fold (P<0.05) by rifampicin. In conclusion, itraconazole and rifampicin caused only relatively minor changes in the plasma concentrations of the active piperazine metabolite of buspirone, although they had drastic effects on the concentrations of parent buspirone.

Effect of itraconazole on cerivastatin pharmacokinetics

OBJECTIVE

To determine the effects of itraconazole, a potent inhibitor of CYP3A4, on the pharmacokinetics of cerivastatin, a competitive 3-hydroxy-3-methylglutaryl coenzyme A (HMG-CoA) reductase inhibitor.

METHODS

A randomized, double-blind, cross-over study design with two phases, which were separated by a washout period of 4 weeks, was used. In each phase ten healthy volunteers took 200 mg itraconazole or matched placebo orally once daily for 4 days according to a randomization schedule. On day 4, 0.3 mg cerivastatin was administered orally. Serum concentrations of cerivastatin, its major metabolites, active and total HMG-CoA reductase inhibitors, itraconazole and hydroxyitraconazole were measured up to 24 h.

RESULTS

Itraconazole increased the area under the concentration-time curve from time zero to infinity (AUC(0-infinity)) of the parent cerivastatin by 15% (P < 0.05). The mean peak serum concentration (Cmax) of cerivastatin lactone was increased 1.8-fold (range 1.1-fold to 2.4-fold, P < 0.001) and the AUC(0-24h) 2.6-fold (range 2.0-fold to 3.6-fold, P < 0.001) by itraconazole. The elimination half-life (t1/2) of cerivastatin lactone was increased 3.2-fold (P < 0.001). Itraconazole decreased the AUC(0-24h) of the active M-1 metabolite of cerivastatin by 28% (P < 0.05), whereas the AUC(0- 24h) of the more active metabolite, M-23, was increased by 36% (P < 0.05). The AUC(0-24h) and t1/2 of active HMG-CoA reductase inhibitors were increased by 27% (P < 0.05) and 40% (P < 0.05), respectively, by itraconazole.

CONCLUSIONS

Itraconazole has a modest interaction with cerivastatin. Inhibition of the CYP3A4-mediated M-1 metabolic pathway leads to elevated serum concentrations of cerivastatin, cerivastatin lactone and metabolite M-23, resulting in increased concentrations of active HMG-CoA reductase inhibitors.

Tamoxifen and toremifene concentrations in plasma are greatly decreased by rifampin

BACKGROUND

Rifampin (INN, rifampicin) is a potent inducer of cytochrome P450 (CYP) enzymes involved in drug metabolism and therefore causes many drug interactions.

METHODS

The effects of rifampin on the pharmacokinetics of tamoxifen (study I) and toremifene (study II) were examined in 2 randomized, placebo-controlled crossover studies. Ten (study I) or 9 (study II) healthy male volunteers took either 600 mg rifampin or placebo orally once a day for 5 days. On the sixth day, 80 mg tamoxifen or 120 mg toremifene was administered orally. Blood samples were collected up to 336 hours after drug administration.

RESULTS

Rifampin reduced the area under the plasma concentration-time curve (AUC) of tamoxifen by 86% (P < .001), peak plasma concentration (Cmax) by 55% (P < .001), and elimination half-life (t1/2) by 44% (P < .001). The AUC of toremifene was reduced by 87% (P < .001), Cmax by 55% (P < .001), and t1/2 by 44% (P < .01) with rifampin. During the rifampin phase, the AUC of N-demethyltamoxifen was 38% (P < .001) and the AUC of N-demethyltoremifene was 20% (P < .01) of that during the placebo phase.

CONCLUSIONS

Rifampin markedly reduces the plasma concentrations of tamoxifen and toremifene by inducing their CYP3A4-mediated metabolism. Concomitant use of rifampin or other potent inducers of CYP3A4 with tamoxifen and toremifene may reduce the efficacy of these antiestrogens.

Grapefruit juice substantially increases plasma concentrations of buspirone

BACKGROUND

Buspirone has a low oral bioavailability because of extensive first-pass metabolism. The effect of grapefruit juice on the pharmacokinetics and pharmacodynamics of orally administered buspirone is not known.

METHODS

In a randomized, 2-phase crossover study, 10 healthy volunteers took either 200 mL double-strength grapefruit juice or water 3 times a day for 2 days. On day 3, each subject ingested 10 mg buspirone with either 200 mL grapefruit juice or water, and an additional 200 mL was ingested 1/2 hour and 1 1/2 hours after buspirone administration. Timed blood samples were collected up to 12 hours after ingestion, and the effects of buspirone were measured with 6 psychomotor tests up to 8 hours after ingestion.

RESULTS

Grapefruit juice increased the mean peak plasma concentration of buspirone 4.3-fold (range, 2-fold to 15.6-fold; P < .01) and the mean area under the plasma buspirone concentration-time curve 9.2-fold (range, 3-fold to 20.4-fold; P < .01). The time of the peak concentration (tmax) of buspirone increased from 0.75 to 3 hours (P < .01), and the elimination half-life (t1/2) was slightly increased (P < .01) by grapefruit juice. A significant increase in the pharmacodynamic effects of buspirone by grapefruit juice was seen only in subjective overall drug effect (P < .01).

CONCLUSIONS

Grapefruit juice considerably increased plasma buspirone concentrations. The probable mechanism of this interaction is delayed gastric emptying and inhibition of the cytochrome P450 3A4-mediated first-pass metabolism of buspirone caused by grapefruit juice. Concomitant use of buspirone and at least large amounts of grapefruit juice should be avoided.

Grapefruit juice-simvastatin interaction: effect on serum concentrations of simvastatin, simvastatin acid, and HMG-CoA reductase inhibitors

BACKGROUND

Simvastatin is a cholesterol-lowering agent that is metabolized through CYP3A4. We studied the effect of grapefruit juice on the pharmacokinetics of orally administered simvastatin.

METHODS

In a randomized, 2-phase crossover study, 10 healthy volunteers took either 200 mL double-strength grapefruit juice or water 3 times a day for 2 days. On day 3, each subject ingested 60 mg simvastatin with either 200 mL grapefruit juice or water, and an additional 200 mL was ingested 1/2 and 1 1/2 hours after simvastatin administration. Serum concentrations of simvastatin and simvastatin acid were measured by liquid chromatography-tandem mass spectrometry (LC-MS-MS) and those of active (naive) and total (after hydrolysis) 3-hydroxy-3-methylglutaryl coenzyme A (HMG-CoA) reductase inhibitors by a radioenzyme inhibition assay.

RESULTS

Grapefruit juice increased the mean peak serum concentration (Cmax) of unchanged simvastatin about 9-fold (range, 5.1-fold to 31.4-fold; P < .01) and the mean area under the serum simvastatin concentration-time curve [AUC(0-infinity)] 16-fold (range, 9.0-fold to 37.7-fold; P < .05). The mean Cmax and AUC(0-infinity) of simvastatin acid were both increased about 7-fold (P < .01). Grapefruit juice increased the mean AUC(0-infinity) of active and total HMG-CoA reductase inhibitors 2.4-fold (P < .01) and 3.6-fold (P < .01), respectively. The time of the peak concentration of active and total HMG-CoA reductase inhibitors was increased by grapefruit juice (P < .05).

CONCLUSION

Grapefruit juice greatly increased serum concentrations of simvastatin and simvastatin acid and, to a lesser extent, those of active and total HMG-CoA reductase inhibitors. The probable mechanism of this interaction was inhibition of CYP3A4-mediated first-pass metabolism of simvastatin by grapefruit juice in the small intestine. Concomitant use of grapefruit juice and simvastatin, at least in large amounts, should be avoided, or the dose of simvastatin should be greatly reduced.