Plasma buspirone concentrations are greatly increased by erythromycin and itraconazole

BACKGROUND: The oral bioavailability of buspirone is very low as a result of extensive first-pass metabolism. Erythromycin and itraconazole are potent inhibitors of CYP3A4, and they increase plasma concentrations and effects of certain drugs, for example, oral midazolam and triazolam. The possible interactions of buspirone with erythromycin and itraconazole have not been studied before. METHODS: The pharmacokinetics and pharmacodynamics of buspirone were investigated in a randomized, double-blind, double-dummy crossover study with three phases. Eight young healthy volunteers took either 1.5 gm/day erythromycin, 200 mg/day itraconazole, or placebo orally for 4 days. On day 4, 10 mg buspirone was administered orally. Timed blood samples were collected up to 18 hours, and the effects of buspirone were measured with four psychomotor tests up to 8 hours. RESULTS: Erythromycin and itraconazole increased the mean area under the plasma concentration-time curve from time zero to infinity [AUC(0-infinity] of buspirone about sixfold (p < 0.05) and 19-fold (p < 0.01), respectively, compared with placebo. The mean peak plasma concentration (Cmax) of buspirone was increased about fivefold (p < 0.01) and 13-fold (p < 0.01) by erythromycin and itraconazole, respectively. These interactions were evident in each subject, although a striking interindividual variability in the extent of both interactions was observed. The elimination half-life of buspirone did not seem to be prolonged by either erythromycin or itraconazole. The effect of itraconazole on the Cmax and AUC(0-infinity) of buspirone was significantly (p < 0.01) greater than that of erythromycin. The greatly elevated plasma buspirone concentrations resulted in increased (p < 0.05) pharmacodynamic effects (as measured by the Digit Symbol Substitution test and the Critical Flicker Fusion test) and in side effects of buspirone. CONCLUSIONS: Both erythromycin and itraconazole greatly increased plasma buspirone concentrations, obviously by inhibiting its CYP3A4-mediated first-pass metabolism. These pharmacokinetic interactions were accompanied by impairment of psychomotor performance and side effects of buspirone. The dose of buspirone should be greatly reduced during concomitant treatment with erythromycin, itraconazole, or other potent inhibitors of CYP3A4.     

Pharmacokinetics and CNS pharmacodynamics of the 5-HT1A agonist buspirone in humans following acute L-tryptophan depletion challenge

This study was designed to evaluate the relationship between the pharmacokinetic(s) (PK) and CNS pharmacodynamic(s) (PD) of buspirone, an antidepressant/anxiolytic, in 6 healthy male volunteers placed on an acute L-tryptophan deficient (ATD) diet. The study was a randomized, double-blind, placebo-controlled, four-period, three-way crossover study. The first study period was a single-blind familiarization period in which all subjects received placebo. During the remaining three study periods, subjects received either placebo, 10 mg or 30 mg oral buspirone. Subjects were administered the ATD diets 5 h prior to buspirone/placebo administration during each study period. All subjects underwent serial measurements of resting electroencephalography (REEG) and vigilance electroence-phalography (VEEG), cognitive tests, subjective rating scales, and blood was sampled for determination of unbound plasma L-tryptophan, serum prolactin, serum cortisol and plasma buspirone and its active metabolite, 1-pyrimdylpiperazine (1-PP). The ATD diet reduced the unbound plasma L-tryptophan concentrations to 20% of their baseline values. The intraindividual and interindividual variability in the unbound L-tryptophan concentration drop was less than 10% and 15%, respectively. Peak L-tryptophan depletion occurred 5 h after ATD diet was administered; L-tryptophan depletion lasted for approximately 11 h, and L-tryptophan concentrations recovered to baseline values approximately 13 h after administration of the ATD diet. PK-PD analysis for buspirone showed that: 1) peak plasma concentration (Cmax) and total area under the plasma concentration-time curve (AUC infinity) for buspirone following the 10 mg dose in this study were higher than those reported previously in the literature; 2) there was a transient response in the neuroendocrine measures, subjective rating scales and the EEG, but no changes in the cognitive tests with increasing doses of buspirone; 3) the PD measures were correlated with the doses of buspirone, but not with plasma concentrations of buspirone and 1-PP; and 4) the subjective rating scales were the most sensitive indicators of buspirone's CNS effects. This study provides evidence that ATD diet is a simple, specific and non-toxic experimental method to lower plasma L-tryptophan concentrations and thereby (indirectly) deplete brain tryptophan and serotonin (5-HT) concentrations. The ATD challenge may serve as a model of depression in healthy volunteers because of its ability to induce transient symptoms of the disease. Comparison of the results from this study to those reported in the literature suggests that the use of the ATD diet decreases the buspirone-induced neuroendocrine response, increases the buspirone-induced changes in subjective rating scales and, at the same time, increases the systemic exposure to buspirone and 1-PP.     

Itraconazole increases plasma concentrations of quinidine

BACKGROUND: Quinidine is eliminated mainly by CYP3A4-mediated metabolism. Itraconazole interacts with some but not all of the substrates of CYP3A4; it is therefore important to study the possible interaction of itraconazole with quinidine. METHODS: A double-blind, randomized, two-phase crossover study design was used with nine healthy volunteers. Itraconazole (200 mg) or placebo was ingested once a day for 4 days. A single 100 mg oral dose of quinidine sulfate was ingested on day 4. Plasma concentrations of quinidine, itraconazole, and hydroxyitraconazole, as well as cumulative excretion of quinidine into urine, were determined up to 24 hours. The ECG, heart rate, and blood pressure were also recorded up to 24 hours. RESULTS: On average the peak plasma concentration of quinidine increased to 1.6-fold (p < 0.05), and the area under the concentration-time curve of quinidine increased to 2.4-fold (p < 0.01) by itraconazole. The elimination half-life of quinidine was prolonged 1.6-fold (p < 0.001), and the area under the 3-hydroxyquinidine/quinidine ratio-time curve decreased to one-fifth (p < 0.001) by itraconazole. The renal clearance of quinidine decreased 50% (p < 0.001) by itraconazole, whereas the creatinine clearance was unaffected. The QTc interval correlated with the concentrations of quinidine during both itraconazole and placebo phases (r2 = 0.71 and r2 = 0.79, respectively; p < 0.01), although only minor changes between the phases were observed in other pharmacodynamic variables. CONCLUSIONS: Itraconazole increases plasma concentrations of oral quinidine, probably by inhibiting the CYP3A4 isozyme during the first-pass and elimination phases of quinidine. The decreased renal clearance of quinidine might be the result of the inhibition of P-glycoprotein-mediated tubular secretion of quinidine by itraconazole. The concentrations of quinidine should be closely monitored if itraconazole or some other potent CYP3A inhibitors are used with quinidine.     

Pharmacokinetic interaction between itraconazole and rifampin in Yucatan miniature pigs

The objective of this study was to examine the effects of rifampin on itraconazole pharmacokinetics, at steady state, in three Yucatan miniature pigs. Daily for 3 weeks, the pigs received 200 mg of itraconazole orally at the beginning of each meal, and for the following 2 weeks they received itraconazole orally combined with intravenous administration of rifampin at 10 mg/kg/day. Coadministration of rifampin resulted in an 18-fold decrease in the maximum concentration of itraconazole in serum, from 113.0 (standard deviation [SD] 17.2) to 6.2 (SD, 3.9) ng/ml and a 22-fold decrease in the area under the concentration-time curve, from 1,652.7 (SD, 297.7) to 75.6 (SD, 30.0) ng.h/ml. The active metabolite of itraconazole, hydroxyitraconazole, was undetectable. This study demonstrates that rifampin affects itraconazole kinetics considerably at steady state in this miniature-pig model, probably by inducing hepatic metabolism of itraconazole.     

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.     

The effect of erythromycin on the CYP3A component of sertindole clearance in healthy volunteers

The effect of erythromycin on the pharmacokinetic disposition of oral sertindole, a new antipsychotic compound, was investigated. Ten subjects who completed the study received a single 4-mg dose of sertindole without or with concomitant erythromycin 250 mg taken orally 4 times daily. Coadministration of sertindole and erythromycin led to a 33% decrease (P < 0.05) in mean (+/- SD) time to reach maximum plasma concentration (tmax) value and a 15% elevation (P < 0.05) in the mean maximum plasma concentration (Cmax) value of sertindole. The mean area under the concentration-time curve (AUC) value of sertindole did not change significantly in the presence of erythromycin (alone: 159 +/- 111 ng.hr/mL, in combination: 179 +/- 144 ng.hr/mL, P > 0.05). The presence of erythromycin also significantly increased the dehydrosertindole Cmax and AUC means by 16% and 21%, respectively, possibly due to inhibition of the CYP3A metabolic isozyme responsible for the elimination of this metabolite. The rate of absorption of sertindole and the rate of appearance of dehydrosertindole in the systemic circulation after a 4-mg sertindole single dose were slightly enhanced by concomitant dosing of erythromycin. In conclusion, there is a small but noticeable effect of erythromycin on the pharmacokinetic disposition of sertindole. The effects are believed to have little clinical significance.     

The effect of the antimycotic itraconazole on the pharmacokinetics and pharmacodynamics of diazepam

The azole antimycotic itraconazole is a potent and relatively unspecific inhibitor of cytochrome P450 enzymes and has a potentially dangerous interaction with midazolam and triazolam. The possible interaction between itraconazole and diazepam was investigated in a double-blind, randomized, cross-over study. Ten healthy volunteers were given orally placebo or itraconazole 200 mg a day for 4 days. The challenge dose of 5 mg of diazepam was ingested on the fourth day, after which plasma samples were collected and psychomotor performance tests were carried out for 42 h. Despite a statistically significant small increase in the area under the plasma diazepam concentration-time curve and the elimination half-life of diazepam, there was no clinically significant interaction as determined by the psychomotor performance tests. The lack of significant first-pass metabolism and the different metabolic pathways of diazepam explain the smaller interaction potential of diazepam compared with midazolam and triazolam. Diazepam, unlike midazolam and triazolam, can be prescribed in usual doses for patients receiving itraconazole and probably other inhibitors of P4503A4, at least when diazepam is used as single doses.     

Pharmacokinetic interaction between oral cyclosporin and mibefradil in stabilized post-renal-transplant patients

BACKGROUND: The potential for interaction between oral cyclosporin (Sandimmun) and the new calcium antagonist mibefradil was assessed as part of the clinical development of the new compound. METHODS: Six stable renal transplant patients on long-term, oral, twice-daily (Q 12 H) cyclosporin (CsA) therapy received 25 mg mibefradil on Day 1, followed by 50 mg once daily for 5 or 6 days. At baseline, as well as on the last day of mibefradil dosing, complete steady-state CsA blood concentration-time profiles were characterized over a dosing interval. RESULTS: Mibefradil led to mean increases in minimum and maximum CsA blood concentrations and area under the curve of CsA by 2.7-, 2.1-, and 2.3-fold, respectively (all significantly different from CsA alone, P < 0.02). Mibefradil is therefore associated with a clinically relevant increase in CsA blood concentrations. The mechanism of elevation of CsA blood concentrations is probably mibefradil and/or metabolite inhibition of the cytochrome P-450 isoenzyme 3A4. CsA had no clinically significant effect on mibefradil plasma concentrations. CONCLUSIONS: These results confirm previous findings of cytochrome P-450 3A4 inhibition by mibefradil and suggest that, for patients receiving CsA, its dose must be adjusted and its plasma concentration must be monitored when adding or stopping mibefradil.     

Mallory-Weiss syndrome

Thalassemia is common in Southeast Asia, where artemisinin derivatives are frequently used in the treatment of malaria. It has been previously reported that artemisinin derivatives can be concentrated by uninfected thalassemic erythrocytes in vitro but not by normal erythrocytes. As a follow-up to this report, we studied the antimalarial kinetics of intravascular artesunate (2.4 mg/kg of body weight) in 10 persons with normal hemoglobins and in 10 patients with thalassemia (2 with alpha-thalassemia type 1-hemoglobin Constant Spring and 8 with alpha-thalassemia type 1-alpha-thalassemia type 2). Concentrations of artesunate and its active metabolites in plasma were measured by bioassay and expressed relative to those of dihydroartemisinin, the major biologically active metabolite. Concentrations of intravascular artesunate in plasma peaked in both the normal individuals and the thalassemic individuals 15 min after injection (the first time point). Plasma drug concentrations at all time intervals, except that at 1 h, were significantly higher in thalassemic subjects than in normal subjects (P < 0.05). The area under the concentration-time curve was 9-fold higher (P < 0.001) and the volume of distribution at steady state was 15-fold lower (P < 0.001) in thalassemic than in normal subjects. In light of the potential neurotoxicity of artemisinin derivatives, these results suggest that thalassemic subjects may need a drug administration regimen different from that of normal patients.     

The effects of the systemic antimycotics, itraconazole and fluconazole, on the pharmacokinetics and pharmacodynamics of intravenous and oral midazolam

We studied the interaction of azole antimycotics with intravenous (IV) and oral midazolam using a cross-over design in 12 volunteers, who ingested placebo, itraconazole, or fluconazole for 6 days. A 7.5-mg dose of midazolam was ingested on the first day, 0.05 mg/kg was administered IV on the fourth day, and 7.5 mg orally on the sixth day. Itraconazole reduced the clearance of IV midazolam by 69% and fluconazole reduced the clearance of IV midazolam by 51% (P < 0.001). A single dose of itraconazole and fluconazole increased the area under the oral midazolam concentration-time curve [AUC(0-infinity)] 3.5-fold (P < 0.001) and the peak concentration two-fold (P < 0.05) compared to placebo. On the sixth day the AUC(0-infinity) of oral midazolam was almost seven times greater with itraconazole (P < 0.001) and 3.6 times greater with fluconazole (P < 0.001) than without the antimycotics. The psychomotor effects of midazolam were also profoundly increased (P < 0.001). The psychomotor tests demonstrated only a weak interaction between the antimycotics and IV midazolam. When bolus doses of midazolam are given for short- time sedation, the effect of midazolam is not increased to a clinically significant degree by itraconazole and fluconazole, and it can be used in normal doses. However, the use of large doses of IV midazolam increases the risk of clinically significant interactions also after IV midazolam. Use of oral midazolam with itraconazole and fluconazole should be avoided.     

Pharmacokinetics and safety of propiverine in patients with fatty liver disease

OBJECTIVE: The present study was designed to assess the pharmacokinetics of propiverine after single and multiple dosing in patients with and without fatty liver disease. METHODS: The serum concentration-time curves of propiverine and its main metabolite propiverine-N-oxide were investigated in 12 patients with mild to moderate impairment of liver function (mean antipyrine clearance 26.0 ml x min(-1)) and in 12 controls (antipyrine clearance 42.8 ml x min(-1)). Subjects were treated orally with propiverine hydrochloride (Mictonorm) for 5 days (15 mg t. i. d.) to reach steady state. RESULTS: No significant differences were observed for propiverine and its main metabolite with regard to peak serum concentration (Cmax), area under the serum concentration-time curve (AUC) and elimination half-life (t1/2). Adverse events were reported by 12 patients. Five patients with fatty liver disease and seven patients with normal liver function complained of dry mouth and/or blurred vision. All adverse events reported were transient and mild. CONCLUSION: No pharmacokinetic differences relevant for safety were observed, comparing patients with and without fatty liver disease following repeated oral administration of propiverine. Thus there seems to be no need to adjust the dose in patients with mild to moderate impairment of liver function.     

Clinical effects of buspirone in social phobia: a double-blind placebo-controlled study

BACKGROUND: The results of open pilot studies suggest that the serotonin-1A (5-HT1A) receptor agonist buspirone might be effective in social phobia. METHOD: In the present study, the efficacy of buspirone was investigated in patients with social phobia using a 12-week double-blind placebo-controlled design. Thirty social phobic patients (DSM-IV) were treated with either buspirone 30 mg daily or placebo. Efficacy of treatment was measured using the Social Phobia Scale (subscores anxiety and avoidance) and the Hamilton Rating Scale for Anxiety. RESULTS: Taking a reduction of 50% or more on the Social Phobia Scale as a criterion for clinically relevant improvement, only 1 patient on buspirone and 1 on placebo were classified as responder to treatment. A subjective and clinically relevant improvement was reported by 4 patients (27%) on buspirone and 2 patients (13%) on placebo. There were no statistically significant differences between buspirone and placebo on any of the outcome measures. Generally speaking, buspirone was well tolerated. CONCLUSION: The results of the study do not support the results of open studies, in which a reduction of social anxiety and social avoidance was reported in patients with social phobia treated with buspirone.     

The impact of prostanoids on pulmonary gas exchange during abdominal surgery with mesenteric traction

We investigated the effect of intravenous (iv) ibuprofen on prostanoid release and on pulmonary gas exchange after abdominal mesenteric traction (MT) during either abdominal aortic surgery or pancreas resection. In a prospective, randomized, double-blind study, 400 mg ibuprofen (pancreas n = 13, aorta n = 13) or a placebo (pancreas n = 13, aorta n = 13) was administered iv before skin incision. MT was applied uniformly. The prostanoid plasma concentrations, venous admixture (Q(va)/Q(t)), and PaO2/FIO2 ratio were determined at baseline (before MT) and 5, 15, 45, and 90 min after MT. Patients who underwent aortic surgery were older and exhibited a lower preoperative PaO2 than those who underwent pancreas resection. Placebo-treated patients revealed a 30-fold peak increase in 6-keto-prostaglandin F1alpha (stable metabolite of prostacyclin) levels after intentional MT during aortic as well as pancreatic operations. This response was accompanied by an increase in Q(va)/Q(t) (ibuprofen: pancreas 7% +/- 1%, aorta 14% +/- 2%; placebo: pancreas 16% +/- 3%, aorta 26% +/- 3%/15 min after MT [mean +/- SEM, P < 0.05, placebo vs ibuprofen]), which resulted in decreased PaO2/ FIO2 ratio only in the aortic surgery patients (ibuprofen: 310 +/- 19; placebo: 237 +/- 24 15 min after MT, [mean +/- SEM, P < 0.05]). The authors conclude that ibuprofen-pretreated patients demonstrated almost constant prostanoid levels without changes in pulmonary gas exchange after MT.     

Can oral contraceptive steroids influence the elimination of nifedipine and its primary pryidine metabolite in humans?

OBJECTIVE: To investigate the influence of oral contraceptives on cytochrome P450 3A4 (P450NF) activity. METHODS: In 23 healthy women, the pharmacokinetics of nifedipine and its main metabolite dehydronifedipine in plasma were assessed after a single oral dose, prior to and after intake of one of two oral contraceptive formulations, one containing 2 mg dienogest and 0.03 mg ethinylestradiol (group A) and the other containing 0.125 mg levonorgestrel and 0.03 mg ethinylestradiol (group B). RESULTS: While the intake of two oral contraceptives for 21 days did not influence the plasma concentration-time curve of unchanged nifedipine, mean AUC0-23.5 h and the mean Cmax values of dehydronifedipine were significantly lower in both groups tested/(24% in group A and 25% in group B). This observation may indicate a reduced formation rate of metabolites and reflects an inhibition of cytochrome P450 3A4 activity. The activation of the same or other metabolic degradation mechanism(s) could explain this result. CONCLUSION: The investigation presented demonstrates the importance of metabolite measurement when in vivo studies are undertaken to investigate different influences on drug metabolizing ability.     

The evaluation of eustachian tube function in patients with chronic otitis media

To assess the clinical usefulness of salivary monitoring of irinotecan (CPT-11) and its active metabolite (SN-38), we examined the clinical pharmacological profile of both drugs in 9 patients with thoracic malignancies who received 60 mg/m2 CPT-11 (21 courses). Plasma and unstimulated whole saliva were collected over a 24-h period, and concentrations of CPT-11 and SN-38 were measured by high-performance liquid chromatography. Both CPT-11 and SN-38 were detectable in saliva, and the concentration-time curves in plasma and saliva showed a very similar pattern. A good correlation was observed between the saliva concentration (C3) and the plasma concentration (Cp) for both CPT-11 and SN-38 (r = 0.732, P < 0.0001 and r = 0.611, P < 0.0001, respectively). The area under the concentration-time curve calculated for saliva (AUCs) correlated with that generated for plasma (AUCp) for both CPT-11 and SN-38 (r = 0.531, P = 0.012 and r = 0.611, P = 0.0025, respectively). These results suggest that it may be feasible to use saliva instead of plasma for pharmacokinetics/pharmacodynamics studies of CPT-11.     

Effect of tolcapone on plasma levodopa concentrations after coadministration with levodopa/carbidopa to healthy volunteers

Tolcapone (Ro 40-7592) is a novel inhibitor of catechol-O-methyltransferase that is being developed for clinical use in the treatment of Parkinson's disease as add-on therapy to a combination of levodopa and a peripheral amino acid decarboxylase inhibitor (benserazide or carbidopa). The current single-blind, randomized study was designed to evaluate the effect of tolcapone compared with placebo on plasma levodopa concentrations in healthy volunteers concomitantly receiving 25 mg of carbidopa and 100 mg of levodopa (Sinemet 25-100) and to assess the tolerability and safety of this combination. Placebo or tolcapone at doses of 5, 10, 25, 50, 100, 200, 400, and 800 mg was coadministered orally with Sinemet 25-100. Each dose was tested in a crossover fashion in a new group of six participants who each received active drug on one occasion and placebo on the other. Tolcapone increased the area under the plasma concentration-time curve and half-life of levodopa approximately twofold, without appreciably increasing the peak concentration. The maximum effect on levodopa half-life was observed with the 200-mg dose. Adverse effects were minor at all doses.     

Pharmacokinetics of dolasetron after oral and intravenous administration of dolasetron mesylate in healthy volunteers and patients with hepatic dysfunction

In previous studies, dolasetron was shown to have both renal and hepatic elimination mechanisms. This study was conducted to determine the impact of varying degrees of hepatic dysfunction on the pharmacokinetics and safety of dolasetron and its reduced metabolites. Seventeen adults were studied: six healthy volunteers (group I), seven patients with mild hepatic impairment (Child-Pugh class A; group II), and four patients with moderate to severe hepatic impairment (Child-Pugh class B or C1; group III). Single 150-mg doses of dolasetron mesylate were administered intravenously and orally, with a 7-day washout period separating treatments. After intravenous administration, no differences were observed between healthy volunteers and patients with hepatic impairment in maximum plasma concentration (Cmax), areas under the plasma concentration-time curve (AUC), or elimination half-life (t1/2) of intact dolasetron. No significant differences were found in Cmax, AUC, or apparent clearance (C(lapp)) of hydrodolasetron, the primary metabolite of dolasetron. The mean t1/2 increased from 6.87 hours in group I to 11.69 hours in group III. After oral administration, C(lapp) of hydrodolasetron decreased by 42%, and Cmax increased by 18% in patients with moderate to severe hepatic impairment. There were less changes in patients with mildly hepatic impairment. Total percentage of dose excreted as metabolites was similar for healthy volunteers and patients with hepatic impairment, although urinary metabolite profiles differed slightly. Dolasetron was well tolerated and there were no apparent differences in adverse effects between groups or treatments. Because hepatic impairment did not influence Cl(app) of hydrodolasetron after intravenous administration, and the range of plasma concentrations of hydrodolasetron after oral administration was not different from those observed in healthy volunteers, dosage adjustments are not recommended for patients with hepatic disease and normal renal function.     

Bioavailability of dextromethorphan (as dextrorphan) from sustained release formulations in the presence of guaifenesin in human volunteers

A multiple dose bioavailability study with six healthy male human volunteers was conducted. The bioavailability of an experimental sustained release tablet containing dextromethorphan hydrobromide (DXP-HBr), was compared with a marketed sustained release DXP-HBr suspension in a three-way crossover study. Plasma samples, collected serially after oral drug administration, were analysed for the major metabolite of dextromethorphan (DXP), dextrorphan (DX), using a specific HPLC method with fluorescence detection. The bioavailability parameters; area under the concentration-time curve (AUC), maximum plasma concentration (Cmax), and time to peak (Tmax), were obtained from the plasma concentration-time data. Additionally, pharmacokinetic parameters such as mean residence time (MRT), accumulation factor (R), fluctuation index (Fi), total body clearance (Cl), and the average concentration (C) were estimated by using model independent kinetics approach. Analysis of variance of the data revealed that the presence of guaifenesin in the test formulation does not appear to have a statistically significant (p > 0.05) effect on the bioavailability of dextromethorphan as dextrorphan. The relative bioavailability of the tablet dosage form with respect to the suspension was found to be 113% on Day 1 and 110% on Day 6.