An overview of the pharmacokinetics of cilomilast (Ariflo), a new, orally active phosphodiesterase 4 inhibitor, in healthy young and elderly volunteers

The oral pharmacokinetics of cilomilast (Ariflo) were investigated in five separate studies in healthy volunteers. Cilomilast was rapidly absorbed, and pharmacokinetics were dose proportional after single and repeat dosing. The elimination half-life was 7 to 8 hours; accordingly, steady state was reached on the 3rd day of dosing. The degree of accumulation following repeat twice-daily dosing was predictable from the data following a single dose. Although systemic exposure (AUC) was, on average, 21% higher in elderly (65-84 years) compared with young subjects, values for Cmax and t(1/2) were similar, and no difference in tolerability was noted. Single and repeat doses of cilomilast up to and including 15 mg (dosed before or taken between meals) were well tolerated. Dosing with food reduced the rate of absorption without affecting total bioavailability. Hence, tolerability was optimal in the fed state; repeat doses up to and including 30 mg twice daily aftermeals were well tolerated following dose titration.     

Single-dose clinical pharmacokinetic studies of gefitinib

BACKGROUND: The objective of the five clinical studies presented in this article was to investigate the single-dose pharmacokinetics of gefitinib (IRESSA, ZD1839), an epidermal growth factor receptor (EGFR) tyrosine kinase inhibitor, in healthy volunteers and patients with advanced cancer. METHODS: Studies 1 and 3-5 recruited healthy male volunteers aged 18-65 years; study 2 recruited male or female patients aged>or=18 years with any solid malignant tumour expressing EGFR and refractory to standard therapy. Gefitinib administration was as follows: study 1 (bioavailability in healthy volunteers; n=12)--intravenous infusion of 50 or 100 mg followed by a single oral dose of 250 mg; study 2 (bioavailability in cancer patients; n=19)--intravenous infusion of 50 mg followed by a single oral dose of 250 mg; study 3 (intrasubject variability; n=24)--two single oral doses of 250 mg; study 4 (dose-proportionality; n=15)--three single oral doses of 50-500 mg; study 5 (effect of food; n=26)--two single doses of 250 mg under either fed or fasted conditions. In all studies, venous blood samples for determination of gefitinib plasma concentrations were collected at predetermined intervals. Plasma concentrations of gefitinib were measured using liquid-liquid extraction after basification followed by high-performance liquid chromatography with tandem mass spectrometric detection. Appropriate pharmacokinetic parameters were determined by noncompartmental methods. RESULTS: Study 1: Oral bioavailability of a gefitinib 250 mg dose was 57% in healthy volunteers. Absorption was moderately slow, with geometric mean (gmean) peak plasma concentration (Cmax) of 85 ng/mL (range 43.5-110 ng/mL) reached 5 hours following an oral dose of 250 mg. Study 2: Oral bioavailability of a gefitinib 250 mg dose was 59% in patients. Absorption was again moderately slow, with gmean Cmax of 159 ng/mL (range 48.7-324 ng/mL) typically reached 3 hours (range 1-8 hours) following an oral dose of 250 mg. Study 3: Area under the plasma concentration-time curve from time zero to infinity (AUCinfinity) and Cmax were variable--up to 15-fold between subjects and 2-fold within an individual. Study 4: AUCinfinity and Cmax increased with dose across the range of 50-500 mg, and increased dose-proportionally up to 250 mg. Study 5: Small, clinically insignificant increases in AUCinfinity and Cmax were seen in the presence of food (32% and 37%, respectively). CONCLUSIONS: The gefitinib 250 mg tablet is orally bioavailable in both healthy volunteers and cancer patients; bioavailability is independent of dose and unaffected by food to any clinically significant extent. Gefitinib undergoes rapid plasma clearance and has an extensive volume of distribution, resulting in a pharmacokinetic profile supportive of a once-daily dosage regimen.     

Effect of food on the pharmacokinetics and bioavailability of oral imiquimod relative to a subcutaneous dose

OBJECTIVES: The present study, the first clinical pharmacokinetic report of the immune response modifier imiquimod, was conducted to assess the effect of food on the oral absorption of imiquimod, to characterize its pharmacokinetics, and to estimate its oral bioavailability. SUBJECTS AND METHODS: Sixteen healthy male volunteers completed this open-label, randomized, three-period crossover study. Subjects received a 100 mg oral dose of imiquimod after fasting in one period, after a standarized, high fat meal in another, and a 30 mg subcutaneous dose in the third period. RESULTS: The oral bioavailability of imiquimod was on average 47%, and independent of whether imiquimod was administered with or without food. Oral imiquimod was absorbed in both fasted and non-fasted states with an absorption half-life of approximately 1 hour. However, there seemed to be a delay in the initiation of the absorption process when food was administered, which translated in to a Tmax of approximately 2.6 hours while fasting and one hour later in the non-fasted state. Imiquimod was rapidly eliminated with a half-life of approximately 2.5 hours and a total body clearance of approximately 970 ml/hxkg. Although equivalence could not be established due to the large intersubject variability, no significant differences in rate (Cmax) and extent (AUC) of oral absorption were observed between the fasted and non-fasted states. In addition, the Cmax, AUC and bioavailability values for individual subjects were consistent between both oral treatments. CONCLUSION: This study suggests that food does not have a major effect on the rate, extent of absorption or bioavailability of oral imiquimod, and thus, it is suitable to administer imiquimod orally in either the fasted or non-fasted states.     

The disposition and bioavailability of intravenous and oral nalbuphine in healthy volunteers

The pharmacokinetics of intravenous and oral nalbuphine were studied in 24 healthy male volunteers ranging in age from 21 to 30 years. On separate test days over a five-week period, subjects received single doses of each of four different formulations of nalbuphine, with a one-week washout period between treatments: 10 mg intravenously administered over two minutes, 45 mg orally given as a solution, and 45 mg orally administered in two tablet formulations (formulation A and formulation B). Blood samples were collected over 48 hours postadministration, and plasma nalbuphine concentrations were determined by reversed-phase high-performance liquid chromatography (HPLC) with electrochemical detection. The mean nalbuphine plasma concentration five minutes after 10 mg intravenously was 53 ng/mL, and the half-life of nalbuphine with this route of administration was 2.3 hours. In contrast, mean maximum nalbuphine concentrations (Cmax) after the three orally administered preparations ranged from 14.4 to 15.5 ng/mL, and occurred 0.9 to 1.2 hours after dose administration. Mean elimination half-lives after administration of the three nalbuphine oral formulations were essentially identical, ranging from 6.9 to 7.7 hours. Nalbuphine plasma concentration curves decayed biexponentially regardless of route of administration or type of formulation. Absolute bioavailability of the orally administered forms of nalbuphine ranged from 16.4 to 17.4% and Cmax and AUC data further established the bioequivalence of the three oral formulations. The low absolute bioavailability and prolonged elimination half-life of nalbuphine associated with oral administration are likely due to extensive first-pass metabolism and enterohepatic circulation, respectively.     

Steady-state pharmacokinetics of tacrine in patients with Alzheimer's disease

Neurochemical studies of Alzheimer's disease (AD) suggest deficiencies in the cholinergic system. We evaluated the steady-state pharmacokinetics of tacrine (Cognex), an oral cholinesterase inhibitor, in 12 patients with AD. Patients sequentially received nine doses of 10 mg, 20 mg, and 30 mg of tacrine every 6 hours. Blood samples were collected until 24 hours after the final dose. Plasma tacrine concentrations were measured using a validated high-performance liquid chromatographic method. Mean maximum plasma concentrations (Cmax) were 5.1 ng/ml, 20.7 ng/ml, and 33.9 ng/ml following administration of 10 mg, 20 mg, and 30 mg doses, respectively. Corresponding mean values for steady-state area under the curve (AUC) were 19.7 ng/ml, 82.9 ng/ml, and 139 ng/ml.hr. Dose-normalized Cmax and AUC values after administration of the 20 mg and 30 mg doses of tacrine were comparable to each other but were significantly greater (p less than .05) than those after the 10 mg doses. The apparent elimination half-life was approximately 3.4 hours for all dosing regimens. Dose-dependent increases in Cmax and AUC values in patients with AD were similar to those previously reported in normal volunteers. The mechanism of the nonlinearity in tacrine pharmacokinetics is unknown.     

Pharmacokinetics, tolerability, and safety of ACP-103 following single or multiple oral dose administration in healthy volunteers

The pharmacokinetics, safety, and tolerability of ACP-103, a selective serotonin 5-HT(2A) receptor inverse agonist, were evaluated in 2 double-blind, placebo-controlled, dose escalation studies in healthy male volunteers. Pharmacokinetic sampling was measured up to 216 hours after single oral/nasogastric doses of ACP-103 and after the last dose of once-daily oral administration of ACP-103 for 14 days. Single doses of ACP-103 (20-300 mg) resulted in dose-proportionate mean C(max) values (9-152 ng/mL) and AUC(0-infinity) (706-10 798 h x ng/mL), and multiple doses (50-150 mg) resulted in dose-proportionate mean C(max,ss) (93-248 ng/mL) and AUC(0-infinity,ss) (1839-4680 h x ng/mL). The half-life of ACP-103 was approximately 55 hours, with a t(max) at 6 hours. ACP-103 was well tolerated at single doses up to and including 300 mg and multiple doses up to 100 mg once daily for 14 days.     

Effect of colesevelam HCl on single-dose fenofibrate pharmacokinetics

OBJECTIVE: The primary aim of this study was to determine whether there is an effect of colesevelam HCl (WelChol; Sankyo Pharma Inc., Parsippany, NJ, USA) on fenofibric acid (active metabolite of fenofibrate, TriCor, Abbott Laboratories, North Chicago, IL, USA) pharmacokinetics following single-dose fenofibrate when colesevelam HCl and fenofibrate are administered concomitantly, or when colesevelam HCl is administered 4 hours following fenofibrate therapy. METHODS: Thirty healthy volunteers were enrolled in a randomised, open-label, three-way crossover, drug interaction study. Subjects received one of three treatments at each of three dose administration periods: (i) treatment A -- fenofibrate 160 mg plus colesevelam HCl 3750 mg (6 x 625 mg tablets) administered with breakfast; (ii) treatment B -- fenofibrate 160 mg administered with breakfast, followed 4 hours later by colesevelam HCl 3750 mg (6 x 625 mg tablets) administered with lunch; or (iii) treatment C -- fenofibrate 160 mg administered with breakfast. Treatments were separated by a 10-day washout period. Blood samples were collected at predetermined time intervals, both before and after drug administration. Plasma concentrations of fenofibrate and fenofibric acid were measured using a validated liquid chromatography/mass spectroscopy/mass spectroscopy method. RESULTS: Area under the concentration-time curve (AUC) from time zero to the timepoint of the lowest quantifiable concentration (AUCt), AUC from time zero to infinity (AUCinfinity) and maximum plasma concentration (Cmax) for fenofibric acid were 92.1%, 93.9% and 79.8%, respectively, of control values when colesevelam HCl and fenofibrate were coadministered with breakfast; and 91.9%, 93.9% and 99.1%, respectively, when fenofibrate was administered followed 4 hours later by administration of colesevelam HCl. The 90% confidence intervals for the ratios of geometric means for AUCt, AUCinfinity and Cmax comparing the three treatments were contained within the 80-125% equivalence range, with the exception of Cmax for treatment A. Coadministration of fenofibrate with colesevelam HCl resulted in an approximate 20% reduction in Cmax of the active metabolite (fenofibric acid). There were no significant differences in the time to Cmax, elimination rate constant or elimination half-life between any of the treatment groups. CONCLUSIONS: Colesevelam HCl had no significant effect on fenofibrate bioavailability when administered either concomitantly with fenofibrate or 4 hours after fenofibrate.     

Influence of food on the bioavailability of trimoprostil: an overview

The influence of food on the bioavailability of trimoprostil , a new antiulcer prostaglandin E2 derivative, was investigated in healthy male volunteers in four separate studies. Doses of 0.75, 1.5, and 3.0 mg were administered orally in both the presence and absence of food followed by serial blood sampling through 24 hours. Plasma trimoprostil concentrations were determined by a gas chromatograph-negative chemical ionization-mass spectrometric method for pharmacokinetic evaluation. Food decreased the absorption rate of trimoprostil as indicated by a later tmax (P less than 0.01) and corresponding lower Cmax at each dose. However, the food effect on tmax diminished as the dose increased. Although Cmax was reduced, food did not alter the extent of absorption, indicated by similar AUC (P greater than 0.05) between fed and fasted states. Both Cmax and AUC increased proportionately with an increase in dose. The harmonic mean half-lives of elimination were similar (P greater than 0.05) across all doses and ranged from 27 to 55 minutes.     

The relationship between buspirone bioavailability and dose in healthy subjects

Dose dependency of the pharmacokinetics of buspirone, a new anxiolytic agent, was tested in 24 healthy volunteers. Each subject received 10, 20, and 40 mg doses according to a randomized, three-way crossover design with a 7-day interval between treatments. Buspirone AUC values at 10, 20, and 40 mg doses were in the ratio of 1:1.7:3.5 while Cmax values had a ratio of 1:1.9:3.7. The dose normalized (10 mg basis) AUC and Cmax values, Tmax values, and half-lives were not significantly different (p greater than 0.05) among the doses. Buspirone half-life did not change as a function of dose (mg kg-1). It was concluded that buspirone exhibits linear pharmacokinetics following doses in the therapeutic range.     

Influence of food intake and formulation on the pharmacokinetics and metabolism of bosentan, a dual endothelin receptor antagonist

The purpose of the study was to investigate the effect of food intake on the pharmacokinetics and metabolism as well as the relative bioavailability of bosentan. Sixteen healthy male subjects were treated in a randomized, four-way, crossover design with single oral doses of 125 mg bosentan, given as one tablet (with or without food), two tablets of 62.5 mg (with food), and a suspension (without food). The pharmacokinetic parameters of bosentan (and also three of its metabolites) were very similar after the four treatments: geometric means for Cmax and AUC0-infinity, ranged from 1.3 to 1.6 microg/ml and from 7.8 to 8.9 microg x h/ml, respectively, and median t(max) from 3.0 to 4.0 hours. The bioavailability of the 125 mg tablet relative to that of the suspension, both given fasted, was 102%. In the presence of food, Cmax and AUC0-max increased by 22% and 10%, respectively, whereas the two 62.5 mg tablets were bioequivalent to the 125mg tablet, both under fed conditions. The pharmacokinetics of the metabolites was independent of the treatment administered. In conclusion, bosentan bioavailability from the newly developed 125 mg tablet formulation is similar to that of the suspension, and food intake does not influence its pharmacokinetics to a clinically relevant extent.     

Diltiazem pharmacokinetics in elderly volunteers after single and multiple doses

In young healthy volunteers diltiazem does not have linear kinetics between single and multiple doses. Elimination half-life increases and gives AUC's and Cmax higher than those predicted from single dose data. Kinetics of diltiazem were assessed in 16 healthy elderly after a single 60 mg dose and in 24 healthy elderly after 60 mg every 8 h for 7 days. Thirteen participants completed both studies. Elimination half-life, AUC0-24, AUC0-infinity, and Cmax were (mean +/- SE) 7.4 (1.2) h, 349 (34) ng/ml.h, 392 (44) ng/ml.h, and 43 (5) ng/ml respectively after a single dose. After multiple doses elimination half-life, AUC0-48, AUC0-infinity, Cmax and Cmin were respectively 5.7 (0.3) h, 974 (107) ng/ml.h, 1022 (108) ng/ml.h, 102 (7) ng/ml and 43 (5) ng/ml. Exploratory statistics on the 13 volunteers common to both studies showed that the ratio of AUC desacetyl-diltiazem (DAD)/AUC diltiazem rose between single and multiple doses while elimination half-life of both diltiazem and N-desmethyl-diltiazem (MA), tmax, and AUC MA/AUC diltiazem were not affected. The conclusion of this study is that elimination half-life of diltiazem does not increase in elderly between single and multiple doses, possibly due to an increased biotransformation into DAD.     

Diltiazem pharmacokinetics in elderly volunteers after single and multiple doses

In young healthy volunteers diltiazem does not have linear kinetics between single and multiple doses. Elimination half-life increases and gives AUC's and Cmax higher than those predicted from single dose data. Kinetics of diltiazem were assessed in 16 healthy elderly after a single 60 mg dose and in 24 healthy elderly after 60 mg every 8 h for 7 days. Thirteen participants completed both studies. Elimination half-life, AUC0-24, AUC0-infinity, and Cmax were (mean +/- SE) 7.4 (1.2) h, 349 (34) ng/ml.h, 392 (44) ng/ml.h, and 43 (5) ng/ml respectively after a single dose. After multiple doses elimination half-life, AUC0-48, AUC0-infinity, Cmax and Cmin were respectively 5.7 (0.3) h, 974 (107) ng/ml.h, 1022 (108) ng/ml.h, 102 (7) ng/ml and 43 (5) ng/ml. Exploratory statistics on the 13 volunteers common to both studies showed that the ratio of AUC desacetyl-diltiazem (DAD)/AUC diltiazem rose between single and multiple doses while elimination half-life of both diltiazem and N-desmethyl-diltiazem (MA), tmax, and AUC MA/AUC diltiazem were not affected. The conclusion of this study is that elimination half-life of diltiazem does not increase in elderly between single and multiple doses, possibly due to an increased biotransformation into DAD.     

The effect of food on the pharmacokinetics of ofloxacin

After oral administration of a single dose of ofloxacin (300 mg), with and without a standard breakfast, to 12 healthy male volunteers in an open, randomized crossover study, concentrations of the unchanged drug were estimated at various times in serum and urine, over 28 hours and 48 hours, respectively. Each dose was followed by a wash-out period of 1 week. Ofloxacin concentrations were determined using high pressure liquid chromatography (HPLC): parallel determinations using a microbiological assay were in close agreement. Maximum serum concentrations (Cmax) of ofloxacin, after fasting and with breakfast, respectively, were 3.7 and 3.1 micrograms/ml (HPLC, median values). The corresponding areas under the serum concentration-time curves (AUC0-28) were 29.9 and 24.5 micrograms/ml. The lower values of Cmax and AUC0-28 found after food intake were statistically significant (p less than 0.05) but not clinically relevant when compared to the fasting values. Time to reach Cmax and terminal elimination half-life (t1/2 beta) were not significantly affected by food intake: t1/2 beta was calculated as 5.3 and 5.9 hours (HPLC, median values), fasting and with breakfast, respectively. Urinary recovery (after 48 hours: 72% and 74%, respectively) was also not significantly affected by food intake, and urinary concentrations of ofloxacin remained far above 1 microgram/ml, i.e. above the minimum inhibitory concentration (MIC90) for most bacterial strains, for at least 48 hours after drug administration. General tolerability was good; no side-effects were reported.     

Clinical pharmacokinetics and pharmacodynamics of buspirone, an anxiolytic drug.

Buspirone is an anxiolytic drug given at a dosage of 15 mg/day. The mechanism of action of the drug is not well characterised, but it may exert its effect by acting on the dopaminergic system in the central nervous system or by binding to serotonin (5-hydroxytryptamine) receptors. Following a oral dose of buspirone 20 mg, the drug is rapidly absorbed. The mean peak plasma concentration (Cmax) is approximately 2.5 micrograms/L, and the time to reach the peak is under 1 hour. The absolute bioavailability of buspirone is approximately 4%. Buspirone is extensively metabolised. One of the major metabolites of buspirone is 1-pyrimidinylpiperazine (1-PP), which may contribute to the pharmacological activity of buspirone. Buspirone has a volume of distribution of 5.3 L/kg, a systemic clearance of about 1.7 L/h/kg, an elimination half-life of about 2.5 hours and the pharmacokinetics are linear over the dose range 10 to 40 mg. After multiple-dose administration of buspirone 10 mg/day for 9 days, there was no accumulation of either parent compound or metabolite (1-PP). Administration with food increased the Cmax and area under the plasma concentration-time curve (AUC) of buspirone 2-fold. After a single 20 mg dose, the Cmax and AUC increased 2-fold in patients with renal impairment as compared with healthy volunteers. The Cmax and AUC were 15-fold higher for the same dose in patients with hepatic impairment compared with healthy individuals. The half-life of buspirone in patients with hepatic impairment was twice that in healthy individuals. The pharmacokinetics of buspirone were not affected by age or gender. Coadministration of buspirone with verapamil, diltiazem, erythromycin and itraconazole substantially increased the plasma concentration of buspirone, whereas cimetidine and alprazolam had negligible effects. Rifampicin (rifampin) decreased the plasma concentrations of buspirone almost 10-fold.     

Dose-dependent increase of saquinavir bioavailability by the pharmaceutic aid cremophor EL

AIMS: Bioavailability of orally administered drugs depends on several factors including active excretion, e.g. by P-glycoprotein (PGP), and presystemic metabolism, e.g. by cytochrome P450 3A (CYP3A), in both gastrointestinal tract and liver. Many drugs including saquinavir are substrates of both PGP and CYP3A. It was the aim of this study to test whether the extremely low bioavailability of saquinavir can be increased dose-dependently in vivo by cremophor EL, an 'inactive' pharmaceutic aid known to inhibit PGP in vitro. METHODS: In a randomized, placebo-controlled, double-blind, four phase cross-over design single doses of oral saquinavir (Invirase, 600 mg, without food) were administered with increasing single doses of oral cremophor EL (up to 5000 mg) to eight healthy, male individuals. Saquinavir plasma concentrations were determined by LC/MS/MS up to 48 h after intake. Main outcome measures were area under the plasma concentration time curve (AUC), peak concentration (Cmax), time to reach Cmax (tmax) and terminal elimination half-life (t(1/2)). RESULTS: Cremophor EL dose-dependently increased Cmax, AUC(0,4 h), and AUC(0,infinity) of saquinavir. As compared with placebo, the increment observed after 5000 mg cremophor EL was 13-fold for both Cmax and AUC(0,4 h) and 5-fold for AUC(0,infinity). The terminal half-life and the time to reach Cmax (tmax) were unchanged. CONCLUSIONS: Cremophor EL increased the systemic availability of saquinavir without affecting its elimination suggesting that cremophor EL is not devoid of pharmacological action and acts as a modulator of the absorption process, probably by inhibiting intestinal PGP.     

Single-dose and steady-state pharmacokinetics of doxazosin given in combination with chlorothiazide to hypertensive subjects

The pharmacokinetics of doxazosin were determined in hypertensive subjects after a single dose of 1 mg, and at steady-state while receiving doses of 1, 2, 4 and 8 mg of the drug daily. Chlorothiazide 500 mg once daily was administered as additional therapy throughout the study. After a single dose doxazosin was rapidly absorbed, with peak plasma drug concentrations (Cmax) occurring after 2.1 +/- 0.4 hours. The elimination half-life in plasma was 10.7 +/- 1.2 hours. These parameters remained essentially unchanged during maintenance administration of doxazosin at each of the dose levels. Calculations of Cmax and area under the concentration-time curve (AUC0----infinity) indicated that the pharmacokinetic disposition of the drug remained linear over the dose range 1 to 8 mg.     

Oral quinine pharmacokinetics and dietary salt intake

OBJECTIVES: The objective was to determine whether or not dietary salt intake affects the relative bioavailability of oral quinine. Salt intake has been shown to alter quinidine bioavailability. METHODS: The pharmacokinetic properties of oral quinine sulphate (600 mg salt) were investigated in seven healthy Caucasian volunteers, in a randomised, crossover study, on low- and high-salt diets. Plasma quinine concentrations were measured by high-performance liquid chromatography (HPLC) and the 24-h urinary sodium excretion was assayed. RESULTS: Although the 24-h urine sodium excretion was significantly higher when the volunteers were on a high-salt diet, there were no significant differences in quinine AUC0-infinity, tmax, and Cmax after the two diets. The median (range) quinine elimination half-life was significantly shorter after a high-salt diet [8.5 (4.3-10.2) h] than after a low-salt diet [10.0 (7.6-14.8) h] (P = 0.04). CONCLUSION: Dietary salt does not affect the relative oral bioavailability of quinine sulphate.     

Pharmacokinetics of finrozole (MPV-2213ad), a novel selective aromatase inhibitor, in healthy men

AIMS: To investigate the pharmacokinetics of finrozole (MPV-2213ad), a novel competitive aromatase enzyme inhibitor, in healthy male volunteers. METHODS: The study was an open, partly randomized cross-over study including 23 volunteers receiving single doses of 3, 9 mg or 30 mg of finrozole as tablets or solution with 14 days between the administrations. The highest dose was given as tablets only. Serum concentrations of finrozole were determined using high performance liquid chromatography combined with mass spectrometry. RESULTS: The mean time to peak serum concentration ranged from 2.5 to 3.1, and 0.6-0.7 h after tablets and solution, respectively. The Cmax values increased as the dose increased. The calculated apparent mean elimination half-life (t(1/2,z)) was approximately 3 h after the solution, and approximately 8 h after the tablet. The AUC(0,infinity) after finrozole tablets increased proportionally from 3 mg to 9 mg and from 3 to 30 mg. The calculated relative mean bioavailabilities (AUC(0,infinity)-ratio) for the 3 mg and 9 mg doses of finrozole as tablets were 89% and 78%, respectively. CONCLUSIONS: The absorption of finrozole from the tablet formulation was relatively rapid, and the apparent elimination half-life was longer after the tablet than after the solution, probably reflecting overlap of the absorption with the elimination phase.     

Pharmacokinetics and pharmacodynamics of the ETA-selective endothelin receptor antagonist SPP301 in healthy human subjects

SPP301 is a competitive antagonist of ET-1 with a high selectivity for the ETA receptor. A double-blind, placebo-controlled study was performed to investigate the tolerability, pharmacokinetics, and pharmacodynamics of SPP301 after single oral doses in male healthy subjects; doses of 5, 20, 50, 100, and 200 mg were given to different groups of 4 or 8 subjects each. The effect of food on the pharmacokinetics of SPP301 was assessed for the 50-mg dose according to a sequential design in the same subjects. At regular intervals, blood pressure and pulse rate, plasma levels of ET-1 and of SPP301 and its hydroxymethyl metabolite, and urinary excretion of the parent drug and its metabolite were determined. SPP301 was generally well tolerated. At doses >20 mg, adverse events that are typical for vasodilating agents-namely, headache, nausea and vomiting, dizziness, and postural hypotension-were observed. Maximum plasma levels of SPP301 were reached within 4.5 hours. Cmax and AUC values increased linearly with doses up to 100 mg. The apparent terminal half-life was quite constant over the whole dose range and ranged from 7.5 to 15.2 hours. Urinary excretion of SPP301 was below 0.1% of any dose. Cmax and AUC of the metabolite amounted only to about 5% of the values for SPP301. Concomitant food intake had no effect on the overall exposure but increased average peak plasma concentrations of SPP301 by around 50%. Plasma ET-1 increased nearly twofold at the 5-mg SPP301 dose, with no further relevant increase at higher doses. In conclusion, SPP301 is an active ET-1 antagonist and is well tolerated. The pharmacokinetics of the drug and its metabolite are linear up to 100 mg. Food does not affect overall exposure of SPP301 but increases Cmax. Urinary excretion of SPP301 is below 0.1% of the dose administered.     

Amlodipine pharmacokinetics in healthy volunteers

In the present study we investigated the pharmacokinetics and comparative bioavailability of three oral doses of amlodipine in 12 healthy male volunteers. A randomized, open-label, three period crossover study design was employed. Each subject received, on three separate occasions a single oral dose of 2.5, 5 and 10 mg amlodipine. Standing diastolic blood pressure was reduced by 1.1, 4.8 and 8 mmHg six hours after 2.5, 5 and 10 mg amlodipine, respectively. There were no significant changes in pulse rate, nor on the EKG. The curves for the mean plasma concentrations versus time for the three doses showed parallel time-courses. Highly significant positive correlations were observed between dose and AUC (0-72 hrs) and between dose and Cmax. However, dose corrected AUC and Cmax were 10-20% lower with 2.5 mg, than with 5 and 10 mg. Peak levels were achieved 5.6 to 6.4 hours postdose. Half lives were 31.2, 33 and 36.8 hours for 2.5, 5 and 10 mg respectively. Headache was the most common side effect, and was more frequently observed with the highest dose. In summary, linear relationships were found between the dose and the plasma levels of amlodipine. Decreases in standing diastolic blood pressure were also dose related. Because of its long half-life and gradual absorption, amlodipine should be effective in lowering blood pressure given once daily and the incidence of side effects due to rapid absorption should be minimized.