Multiple-dose kinetics in healthy volunteers and in vitro antimalarial activity of proguanil plus dapsone

The multiple-dose kinetics of a daily dose of proguanil (200 mg) coadministered with dapsone (10 mg) was investigated in 6 healthy adult male volunteers. The kinetics of dapsone (DDS), monoacetyldapsone (MADDS), proguanil (PROG) and its active metabolite cycloguanil (CYCLO) were derived from plasma drug concentrations after the last maintenance dose. The following kinetic parameters (mean values) were estimated for DDS and PROG, respectively: maximum concentration (Cmax) = 285 and 151 ng/ml, minimum concentration (Cmin) = 125 and 31 ng/ml, elimination half-life (t1/2) = 23.3 and 18.3 h, plasma clearance (Cl) = 0.032 and 1.27 l/h/kg and apparent volume of distribution (Vss) = 1.05 and 33.32 l/kg. The Cmax, Cmin and t1/2 of CYCLO were 56 ng/ml, 17 ng/ml and 15.0 h, respectively. The antimalarial activity of the proguanil/dapsone combination was assessed in vitro by measuring the inhibition of re-invasion of two Plasmodium falciparum isolates grown in the presence of volunteers' sera. Both FC-27 [chloroquine (CQ)- and pyrimethamine (PYR)-sensitive] and K1 (CQ- and PYR-resistant) isolates were completely inhibited by the drug combination at steady-state concentrations. These findings suggest that the drug regimen may be effective against drug-resistant falciparum malaria.     

Pharmacokinetics of chlorproguanil in man after a single oral dose of Lapudrine

The pharmacokinetic parameters of chlorproguanil (Lapudrine) and its active metabolite, chlorcycloguanil, were determined in 6 healthy male volunteers after a single oral dose of 4 Lapudrine tables (80 mg). The mean maximum plasma chlorproguanil concentration was 36.7 +/- (SD) 7.9 ng/ml and was reached at 3.8 +/- 1.3 h. The chlorproguanil elimination half-life was 17.5 +/- 6.7 h and its plasma clearance was 1.28 +/- 0.12 l/h/kg. The mean whole blood to plasma ratio was 3.1 at 4 h after dosing. Chlorcycloguanil could not be quantified in plasma and whole blood at the detection limit of 10 ng/ml using a high-performance liquid chromatographic method. An excretion rate-time plot from urine data shows a rapid (t1/2 = 20 h) and a slow phase (t1/2 = 51 h) in the elimination of chlorcycloguanil. Our findings suggest that the current prophylactic regimen of chlorproguanil hydrochloride (20 mg weekly) may not be optimal in preventing infections with chloroquine-resistant falciparum malaria.     

Nifedipine: kinetics and dynamics in healthy subjects

Kinetics and pharmacologic effects of three formulations of nifedipine were examined in six healthy young men in a crossover design. Each subject received intravenous nifedipine, 0.015 mg/kg body weight, 20 mg in a capsule, and 20 mg in a slow-release tablet. Changes in heart rate (HR), blood pressure, heart dimensions, and plasma norepinephrine levels (PNE) were examined serially. Plasma concentrations of nifedipine (Cp) and urinary metabolite concentrations were measured by liquid chromatography. After intravenous injection the elimination t1/2 was 1.7 +/- 0.4 hr, systemic clearance was 26.7 +/- 5.4 l/hr, and volume of distribution was 0.8 +/- 0.2 l/kg. After the capsule, Cp rose rapidly, to a maximum concentration (Cmax) of 117 +/- 15 ng/ml at a maximum time (tmax) of 1.4 +/- 0.5 hr. After the sustained release tablet tmax was 4.2 +/- 0.7 hr and Cmax was 26 +/- 10 ng/ml. Nifedipine bioavailability was 56% +/- 25% for the capsule and 52% +/- 13% for the tablet, but there were large interindividual differences. Urinary excretion was 58% +/- 13% 24 hr after intravenous injection, and after 32 hr was 55% +/- 13% after capsules and 32% +/- 8% after tablets. HR increased briefly after intravenous injection and after capsules (15 to 20 bpm), but not significantly after tablets. Diastolic blood pressure (DBP) fell briefly after capsules (8 to 10 mm Hg), but there was a sustained effect after tablets. Cardiac dimensions were unchanged. PNE levels paralleled plasma drug levels in the three experiments.(ABSTRACT TRUNCATED AT 250 WORDS)     

Single-dose pharmacokinetics of a pleconaril (VP63843) oral solution in children and adolescents. Pediatric Pharmacology Research Unit Network

Pleconaril is an orally active, broad-spectrum antipicornaviral agent which demonstrates excellent penetration into the central nervous system, liver, and nasal epithelium. In view of the potential pediatric use of pleconaril, we conducted a single-dose, open-label study to characterize the pharmacokinetics of this antiviral agent in pediatric patients. Following an 8- to 10-h period of fasting, 18 children ranging in age from 2 to 12 years (7.5 +/- 3.1 years) received a single 5-mg/kg of body weight oral dose of pleconaril solution administered with a breakfast of age-appropriate composition. Repeated blood samples (n = 10) were obtained over 24 h postdose, and pleconaril was quantified from plasma by gas chromatography. Plasma drug concentration-time data for each subject were fitted to the curve by using a nonlinear, weighted (weight = 1/Ycalc) least-squares algorithm, and model-dependent pharmacokinetic parameters were determined from the polyexponential parameter estimates. Pleconaril was well tolerated by all subjects. A one-compartment open-model with first-order absorption best described the plasma pleconaril concentration-time profile in 13 of the subjects over a 24-h postdose period. Pleconaril pharmacokinetic parameters (means +/- standard deviations) for these 13 patients were as follows. The maximum concentration of the drug in serum (Cmax) was 1,272.5 +/- 622.1 ng/ml. The time to Cmax was 4.1 +/- 1.5 h, and the lag time was 0.75 +/- 0.56 h. The apparent absorption rate constant was 0.75 +/- 0.48 1/h, and the elimination rate constant was 0.16 +/- 0.07 1/h. The area under the concentration-time curve from 0 to 24 h was 8,131.15 +/- 3,411.82 ng.h/ml. The apparent total plasma clearance was 0.81 +/- 0.86 liters/h/kg, and the apparent steady-state volume of distribution was 4.68 +/- 2.02 liters/kg. The mean elimination half-life of pleconaril was 5.7 h. The mean plasma pleconaril concentrations at both 12 h (250.4 +/- 148.2 ng/ml) and 24 h (137.9 +/- 92.2 ng/ml) after the single 5-mg/kg oral dose in children were higher than that from in vitro studies reported to inhibit > 90% of nonpolio enterovirus serotypes (i.e., 70 ng/ml). Thus, our data support the evaluation of a 5-mg/kg twice-daily oral dose of pleconaril for therapeutic trials in pediatric patients with enteroviral infections.     

Pharmacokinetics of Ceftriaxone in Pediatric Patients With Meningitis

Pharmacokinetics of ceftriaxone after a single dose of 50 or 75 mg/kg were determined in 30 pediatric patients with bacterial meningitis. Data for doses of 50 and 75 mg/kg, respectively, were as follows (mean +/- standard deviation): maximum plasma concentrations, 230 +/- 64 and 295 +/- 76 mug/ml; elimination rate constant, 0.14 +/- 0.06 and 0.14 +/- 0.04 h(-1); harmonic elimination half-life, 5.8 +/- 2.8 and 5.4 +/- 2.1 h; plasma clearance, 51 +/- 24 and 55 +/- 18 ml/h per kg; volume of distribution, 382 +/- 129 and 387 +/- 56 ml/kg; mean concentration in cerebrospinal fluid 1 to 6 h after infusion, 5.4 and 6.4 mug/ml. A dosage schedule of 50 mg/kg every 12 h for bacterial meningitis caused by susceptible organisms is suggested for pediatric patients over 7 days of age.     

Pharmacokinetic-pharmacodynamic relationships of morphine in neonates.

Morphine pharmacokinetics and pharmacodynamics (analgesia and sedation) were evaluated after continuous intravenous infusion of morphine in 19 neonates, both preterm and term, whose lungs were ventilated to relieve respiratory distress. Elimination half-life, total plasma clearance, and volume of distribution (mean +/- SD) were 9.6 +/- 3.0 hours, 2.55 +/- 1.65 ml/min/kg (area analysis) or 2.09 +/- 1.19 ml/min/kg (steady-state data), and 2.05 +/- 1.05 L/kg, respectively, and were not significantly different in preterm and term neonates. In neonates with adverse effects of morphine, the plasma clearance was decreased twofold. Mean morphine concentration required to produce adequate sedation in 50% of patients was found to be 125 ng/ml, but concentrations above 300 ng/ml may be associated with adverse effects of morphine. Morphine-6-glucuronide was not detected in the plasma of any neonate, which may explain why neonates require high plasma concentrations of unchanged morphine for sedation.     

The disposition and dynamics of labetalol in patients on dialysis

The disposition of labetalol was assessed in 16 patients on dialysis after intravenous dosing with 0.7 to 1.0 mg/kg during an interdialytic period and just before hemodialysis (n = 8) and during continuous ambulatory peritoneal dialysis (CAPD) (n = 8). The plasma concentration time data exhibited triexponential decay in all patients. The terminal t 1/2 of labetalol was 12.90 +/- 4.68 hours, the total body clearance was 1198.2 +/- 249.4 ml/min, and the AUC was 921.4 +/- 175.2 ng hr/ml during the interdialytic period. No significant changes were observed in these parameters after dosing with labetalol just before dialysis. The hemodialysis clearance of labetalol was 30.67 +/- 5.49 ml/min, and only 0.189 +/- 0.042 mg of labetalol was removed by hemodialysis. The terminal t 1/2 averaged 13.05 +/- 6.32 hours during CAPD. Steady-state volume of distribution, total body clearance (Clp), and CAPD clearance were 10.39 +/- 2.77 L/kg, 1397.2 +/- 372.3 ml/min, and 1.94 +/- 0.65 ml/min, respectively. The fraction of the dose recovered in the CAPD dialysate during the 72-hour study period was 0.14% +/- 0.09%. The decay of the antihypertensive effect of labetalol was gradual and paralleled the decline in the log plasma concentration. There was a significant correlation between labetalol plasma concentration and the fall in supine diastolic and mean blood pressure after the interdialytic dose and during CAPD. Although labetalol is removed by dialysis, dialysis does not significantly enhance Clp.     

Effects of Metoclopramide and Bromocriptine on the Renin-Angiotensin-Aldosterone System in Man: DOPAMINERGIC CONTROL OF ALDOSTERONE

This study was designed to investigate the possible role of dopaminergic mechanisms in the control of the renin-angiotensin-aldosterone system in normal man. Six normal male subjects in metabolic balance at 150 meq sodium, 60 meq potassium constant intake received the specific dopamine antagonist, metoclopramide, 10 mg i.v. or placebo followed by angiotensin II infusion 1 h later on 2 consecutive days. Metoclopramide increased plasma aldosterone concentration from 8.2+/-2.2 to 21.0+/-3.3 ng/100 ml (P < 0.005) and plasma prolactin concentration from 18.0+/-4.0 to 91.7+/-4.0 ng/ml (P < 0.001) within 15 min of its administration. At 1 h, plasma aldosterone and prolactin concentrations remained elevated at 16.8+/-2.1 ng/100 ml (P < 0.01) and 86.8+/-15.9 ng/ml (P < 0.005), respectively. Angiotensin II at 2, 4, and 6 pmol/kg per min further increased plasma aldosterone concentration to 27.2+/-3.4, 31.9+/-5.7, and 36.0+/-6.7 ng/100 ml (P < 0.02), respectively. Placebo did not alter plasma aldosterone or prolactin concentrations, but angiotensin II increased plasma aldosterone concentration to 13.7+/-2.4, 19.0+/-1.9, and 23.3+/-3.2 ng/100 ml (P < 0.005). The increment of plasma aldosterone concentration in response to angiotensin II was similar after metoclopramide or placebo.The six subjects also received the dopamine agonist, bromocriptine, 2.5 mg or placebo at 6 p.m., midnight, and 6 a.m. followed by angiotensin II infusion on 2 consecutive d. Bromocriptine suppressed prolactin to <3 ng/ml. After placebo, plasma aldosterone concentration increased from 5.2+/-1.4 to 12.3+/-1.7, 17.2+/-2.2, and 21.8+/-3.5 ng/100 ml (P < 0.01) and after bromocriptine from 7.2+/-1.0 to 14.7+/-3.0, 19.8+/-3.2, and 23.4+/-1.6 ng/100 ml (P < 0.001) with each respective angiotensin II dose. No difference in the response to angiotensin II after bromocriptine or placebo was observed. Plasma renin activity, free 11-hydroxycorticoid concentration, and serum potassium concentration were unchanged by metoclopramide or bromocriptine.The results suggest that aldosterone production is under maximum tonic dopaminergic inhibition which can be overridden with stimulation by angiotensin II in normal man.     

Single-dose pharmacokinetics of intravenous itraconazole and hydroxypropyl-beta-cyclodextrin in infants, children, and adolescents

This investigation was designed to evaluate the single-dose pharmacokinetics of itraconazole, hydroxyitraconazole, and hydroxypropyl-beta-cyclodextrin (HP-beta-CD) after intravenous administration to children at risk for fungal infection. Thirty-three children aged 7 months to 17 years received a single dose of itraconazole (2.5 mg/kg in 0.1-g/kg HP-beta-CD) administered over 1 h by intravenous infusion. Plasma samples for the determination of the analytes of interest were drawn over 120 h and analyzed by high-pressure liquid chromatography, and the pharmacokinetics were determined by traditional noncompartmental analysis. Consistent with the role of CYP3A4 in the biotransformation of itraconazole, a substantial degree of variability was observed in the pharmacokinetics of this drug after IV administration. The maximum plasma concentrations (C(max)) for itraconazole, hydroxyitraconazole, and HP-beta-CD averaged 1,015 +/- 692 ng/ml, 293 +/- 133 ng/ml, and 329 +/- 200 mug/ml, respectively. The total body exposures (area under the concentration-time curve from 0 to 24 h) for itraconazole, hydroxyitraconazole, and HP-beta-CD averaged 4,922 +/- 6,784 ng.h/ml, 3,811 +/- 2,794 ng.h/ml, and 641.5 +/- 265.0 mug.h/ml, respectively, with no significant age dependence observed among the children evaluated. Similarly, there was no relationship between age and total body clearance (702.8 +/- 499.4 ml/h/kg); however, weak associations between age and the itraconazole distribution volume (r(2) = 0.18, P = 0.02), C(max) (r(2) = 0.14, P = 0.045), and terminal elimination rate (r(2) = 0.26, P < 0.01) were noted. Itraconazole infusion appeared to be well tolerated in this population with a single adverse event (stinging at the site of infusion) deemed to be related to study drug administration. Based on the findings of this investigation, it appears that intravenous itraconazole can be administered to infants beyond 6 months, children, and adolescents using a weight-normalized approach to dosing.     

Pharmacodynamic and pharmacokinetic interactions between lidocaine and verapamil

Lidocaine (3 mg/kg i.v.) injected during steady-state verapamil infusions (3 micrograms/kg i.v.) induced slight and transient hemodynamic changes in nine conscious dogs. Systemic vascular resistance and left ventricular dP/dt decreased by 16% from 41 +/- 4 mm Hg/liter/min and by 20% from 2876 +/- 137 mm Hg/sec, respectively, whereas heart rate and cardiac output increased by 18% from 100 +/- 5 beats/min and by 17% from 2.5 +/- 0.2 liters/min, respectively. Simultaneously, lidocaine induced a transient but more pronounced decrease in verapamil plasma concentration of 48% from 60 +/- 3 ng/ml. This pharmacokinetic interaction was not the result of a lidocaine-induced decrease in the fraction of verapamil bound to plasma protein because in vitro lidocaine failed to displace verapamil from its protein binding site. Moreover, an increase in verapamil total clearance was not the only mechanism because steady-state lidocaine (6 mg/kg over 5 min followed by 60 micrograms/kg/min) in the presence of steady-state verapamil (200 micrograms/kg over 3 min followed by 3 micrograms/kg/min) also resulted in a transient decrease in verapamil plasma concentration from 59 +/- 9 to 23 +/- 2 ng/ml in six conscious dogs. Although verapamil did not affect lidocaine pharmacokinetics, in the presence of the steady-state lidocaine we recorded an increase in verapamil initial volume of distribution of 44% from 40 +/- 4 liters, and intercompartmental clearance increased by 88% from 101 +/- 20 liters/hr, combined with an increase in verapamil total clearance of 47% from 54 +/- 6 liters/hr (n = 6).     

Moxalactam kinetics during continuous ambulatory peritoneal dialysis after intraperitoneal administration.

Moxalactam kinetics during continuous ambulatory peritoneal dialysis (CAPD) was followed in eight patients after a single intraperitoneal dose of 1 g. Approximately 60% of the dose was absorbed after a dwell time of 4 h. Dialysis solutions were exchanged at 4-h intervals with an overnight dwell of 8 h. The mean (+/- standard deviation) elimination half-life was 13.2 +/- 2.9 h, and the mean apparent volume of distribution was 0.22 +/- 0.08 liters/kg. Mean total clearance was 11.5 +/- 2.4 ml/min, with a mean dialysis clearance of 2.3 +/- 0.5 ml/min. The maximum concentration in plasma ranged from 24.5 to 54.1 micrograms/ml. Moxalactam concentrations in the peritoneal dialysis fluid were above 80 micrograms/ml during the first exchange and above 2 micrograms/ml for a further three exchanges. A suggested intraperitoneal dose regimen for patients undergoing CAPD is 1 g initially, followed by 15 to 25% of the recommended dose for normal patients given at the same time intervals, or 30 to 50% of the recommended dose at twice the usual intervals. Moxalactam is suggested for initial treatment of peritonitis in CAPD patients who do not have ready access to the antibiotic of choice.     

Pharmacokinetics of michellamine B, a naphthylisoquinoline alkaloid with in vitro activity against human immunodeficiency virus types 1 and 2, in the mouse and dog.

Michellamine B (MB) is a naturally occurring naphthylisoquinoline alkaloid of novel chemical structure with activity against human immunodeficiency virus (HIV) types 1 and 2 in vitro. In conjunction with its preclinical evaluation, the plasma pharmacokinetics of MB was characterized in mice and dogs treated by intravenous infusions of 1- and 15-min durations, respectively. At doses ranging from 1 to 9 mg/kg of body weight, the drug exhibited apparent first-order kinetics in both species, affording triexponential plasma concentration-time profiles. Treatment with doses of 5 to 9 mg/kg provided peak plasma levels within the range that completely inhibits the cytopathic effects of HIV upon cultured human lymphoblastoid cells (50 to 100 micrograms/ml) without evidence of toxicity. MB had a biological half-life of 2.8 +/- 0.8 h in mice, with a mean residence time of 2.1 +/- 0.3 h, and a total plasma clearance of 2.4 +/- 0.5 ml/min/kg (mean +/- standard deviation; n = 3); however, the terminal-phase contribution to the area under the plasma profile from time zero to infinity was 44.6% +/- 12.9%. In contrast, the terminal phase was the primary determinant of drug disposition in dogs, accounting for 74.1% +/- 2.8% (n = 3) of the area under the curve. Furthermore, the systemic duration of MB was significantly longer in the dogs than in mice, as indicated by mean values of the apparent half-life (11.6 +/- 1.2 h), mean residence time (12.3 +/- 1.8 h), and clearance (0.50 +/- 0.08 ml/min/kg). However, there were no statistical difference between its apparent volume of distribution in the mice (0.60 +/- 0.08 liters/kg) and dogs (0.50 +/- 0.07 liters/kg). A single dog was also treated with a total dose of 97 mg/kg given as a 72-h constant-rate intravenous infusion, since prolonged systemic exposure to potentially therapeutic drug concentrations will very likely be required for clinical anti-HIV effects. Within 4 h after starting the infusion, the plasma MB concentration exceeded 18 micrograms/ml, it reported 50% effective concentration against HIV in vitro, and subsequently increased to 41 micrograms/ml at the end of the infusion. There were no clinical or pathological indications of toxicity. Whereas the total plasma clearance (0.48 ml/min/kg) was within the range observed for dogs treated by 15-min infusion, extension of the postinfusion sampling period from 24 h to 4 days facilitated better definition of the terminal exponential phase, yielding a value of 25.6 h for the biological half-life of MB. The amount of drug excreted by dogs unchanged in the urine ranged from 3.7 to 11.1% of the administered dose. Thus, the major pathways by which the drug is eliminated from the body remain to be identified. On the basis of these findings, continued development of MB as a novel lead compound for the treatment of HIV infection is warranted.     

Pharmacokinetics of rosiglitazone in patients with end-stage renal disease

The pharmacokinetics and tolerability of a single 8-mg oral dose of rosiglitazone, an anti-diabetic agent, were compared in 10 long-term haemodialysis patients and 10 healthy volunteers. Haemodialysis patients received rosiglitazone 4 h after haemodialysis (non-dialysis day) and 3 h before haemodialysis (dialysis day). Haemodialysis did not influence rosiglitazone pharmacokinetics, and dialytic clearance was low (0.10 1/h). The mean area under the concentration-time curve (AUC(0-infinity)), the maximum observed plasma concentration (Cmax) and the half-life for rosiglitazone were similar in haemodialysis patients (non-dialysis day) and healthy individuals (2192 +/- 598 ng.h/ml versus 2388 +/- 494 ng.h/ml, 338 +/- 114 ng/ml versus 373 +/- 95 ng/ml, and 3.70 +/- 0.75 h versus 3.81 +/- 0.86 h, respectively). AUC(0-infinity) and Cmax were not markedly influenced by haemodialysis. Rosiglitazone dose adjustments are not warranted in patients with type 2 diabetes with end-stage renal failure on haemodialysis.     

Pharmacokinetics and tissue penetration of tazobactam and piperacillin in patients undergoing colorectal surgery.

The pharmacokinetics of tazobactam and piperacillin in plasma and different tissues after a 30-min intravenous infusion of 4 g of piperacillin and 0.5 g of tazobactam were investigated in 18 patients who underwent elective colorectal surgery. Serial blood samples were collected for up to 6 h after the initiation of the infusion. The types of tissue collected were fatty tissue, muscle, skin, appendix, and intestinal mucosa (proximal and distal). On the basis of concentrations in plasma, the following pharmacokinetic parameter values were obtained (values are means +/- standard deviations): maximum concentration of drug in serum, tazobactam, 27.9 +/- 7.67 micrograms/ml; piperacillin, 259 +/- 81.8 micrograms/ml; time to maximum concentration of drug in serum, tazobactam, 0.51 +/- 0.03 h; piperacillin, 0.51 +/- 0.03 h; area under the concentration-time curve, tazobactam, 47.6 +/- 13.3 micrograms.h/ml; piperacillin, 361 +/- 80.3 micrograms.h/ml; clearance, tazobactam, 188 +/- 52.3 ml/min; piperacillin, 194 +/- 42.9 ml/min; half-life, tazobactam, 1.42 +/- 0.32 h; piperacillin, 1.27 +/- 0.24 h; apparent volume of distribution, tazobactam, 0.31 +/- 0.07 liter/kg of body weight; piperacillin, 0.29 +/- 0.06 liter/kg; volume of distribution at steady state, tazobactam, 0.28 +/- 0.04 liter/kg; piperacillin, 0.25 +/- 0.05 liter/kg. The concentrations of tazobactam and piperacillin in fatty tissue and muscle tissue were 10 to 13 and 18 to 30% of the levels in plasma, respectively. In skin, the concentrations of piperacillin were 60 to 95% of the levels in plasma, whereas the concentrations of tazobactam in plasma were 49 to 93% of the levels in skin tissue. The mean concentration of tazobactam in the investigated gastrointestinal tissues (appendix, proximal and distal mucosa) exceeded levels in plasma after 1 h, while piperacillin showed a mean penetration into these tissues of 43 and 53%. The mechanisms that can be used to explain the extent of penetration of piperacillin and tazobactam are discussed. Simple diffusion may take place in fatty and muscle tissue, while penetration into skin and gastrointestinal tissue is governed by more complex mechanisms which lead to differences in penetration between piperacillin and tazobactam. For all tissues investigated (except fatty tissue), the time course of the concentrations of both compounds was similar, with a peak in concentration at between 1 and 2 h after the start of infusion followed by a decline of concentrations that were almost parallel to the curves of the drug concentrations in plasma. In plasma and in all investigated tissues, piperacillin as well as tazobactam reached or exceeded the concentrations found to be effective in vitro.     

Kinetics of fenoximone, a new cardiotonic, in healthy subjects

Fenoximone, a new cardiotonic, was given to six healthy men as a single intravenous dose of 1 mg/kg and a single oral dose of 3 mg/kg as solution in a crossover study. Plasma concentrations were monitored for 8 hr and urine was collected for 24 hr. Peak plasma concentrations (Cmax) were reached 30 min after the oral dose. Decay of plasma concentrations was fitted to a mean (+/- SD) elimination t1/2 (t1/2 beta) of 60 +/- 14 min after intravenous injection and 78 +/- 26 min after oral dosing. Mean total body clearance for intravenous dosing was 2062 +/- 846 ml/min, renal clearance (ClR) was 5.3 +/- 2.4 ml/min, and extrapolated volume of distribution was 0.37 +/- 0.26 l/kg. The sulfoxide derivative was detected as the main metabolite. Cmax of the sulfoxide metabolite occurred 10 min after the end of the intravenous infusion and 20 to 60 min after oral dosing. From the decay of the plasma concentrations of the sulfoxide, the t1/2 beta s were calculated as 132 +/- 15 min after intravenous injection and 140 +/- 27 min after oral dosing of fenoximone. ClR of the sulfoxide was 499 +/- 106 ml/min after intravenous injection; 24-hr urinary recovery of the sulfoxide was 75.7% +/- 5.7% after intravenous injection and 64.3% +/- 10.4% after oral dosing. Mean oral bioavailability of fenoximone was 53% (range 44% to 69%).     

Coupling between renal tubular secretion and effect of bumetanide

The relationship between renal tubular secretion of bumetanide and its saluretic effect was studied in six healthy subjects before and after probenecid (1 gm IV). Bumetanide was determined in serum and urine by HPLC. Continuous intravenous infusion of bumetanide (200 micrograms/hr) gave an average diuresis at steady state of 15 +/- 3 ml/min. Corresponding plasma concentration, urinary excretion rate, and renal clearance of bumetanide averaged 14.3 +/- 2.3 ng/ml, 64 +/- 31 micrograms/30 min, and 145 +/- 59 ml/min. After probenecid there was a marked change in bumetanide kinetics. Average plasma concentration rose to 41.7 +/- 8.1 ng/ml, whereas renal clearance and urinary excretion rate fell to 15.1% and 29.5% of control. There was also a concomitant decrease in diuresis and saluresis to 47% and about 40% of control. Probenecid also reduced the renal clearance of para-aminohippurate and inulin to 67% and 75% of control. Since the fractional water and sodium chloride excretion was also reduced about 33% and 42%, it is concluded that a large part of the diuretic effect of bumetanide depends on its active tubular secretion. As with furosemide and piretanide, bumetanide diuresis is elicited from the luminal side of the human nephron.     

Trimipramine kinetics and absolute bioavailability: use of gas-liquid chromatography with nitrogen-phosphorus detection

Kinetic parameters were derived from trimipramine and desmethyltrimipramine plasma concentrations after administration of intravenous (12.5 mg) and oral (50 mg) trimipramine in nine subjects. Elimination t1/2 after intravenous dosing was (mean +/- SE) 23 +/- 1.9 hr. Volume of distribution by the area method was 30.9 +/- 3.5 l/kg and total metabolic clearance was 15.9 +/- 1.5 ml/min/kg. Plasma protein binding of trimipramine, as determined by equilibrium dialysis, averaged 94.9%, with a range of 93.8% to 96.4%. Peak plasma level attained was 28.2 +/- 4.4 ng/ml at 3.1 +/- 0.6 hr after oral dosing. Absolute bioavailability was 41.4% +/- 4.4% (range of 17.8% to 62.7%). These data indicate that trimipramine has incomplete and variable systemic availability, that it is more highly protein bound than other tricyclic antidepressants, and, on the basis of its elimination t1/2, that it could be administered on a twice-daily basis without marked interdose fluctuations in plasma levels.     

Effects of d,l-verapamil on atrioventricular conduction in relation to its stereoselective first-pass metabolism

After the oral administration of 160 mg pseudoracemic verapamil (80 mg dideuterodextro (d) isomer and 80 mg levo (l) isomer), the prolongation of the PR interval was assessed in relation to d- and l-verapamil plasma concentrations. Concentration-effect curves were analyzed with the sigmoidal Emax model. Because of stereoselective first-pass metabolism, the mean plasma d- to l-verapamil concentration ratio of 4.5 +/- 1.2 was substantially greater than that of 2.1 +/- 0.3 after intravenous dosing. Compared with the concentration after intravenous injection, the total verapamil concentration after oral dosing consisted of a substantially smaller proportion of the more potent l-isomer. These differences in isomer composition of the total verapamil plasma concentration as a result of the route of administration explain the diminished negative dromotropic potency of racemic verapamil after oral dosing. The concentration required to reach 50% of the maximum effect (EC50) for total verapamil concentration was 129.0 +/- 22.9 ng/ml, which was more than three times higher than that after intravenous injection. To assess the relative contributions of the d- and l-isomers to overall dromotropic potency, changes in the PR interval were measured after separate oral dosing with 250 mg d-verapamil and 100 mg l-verapamil. The EC50 showed an 11-fold difference between the l- (36.9 +/- 14.7 ng/ml) and d- (363.1 +/- 64.2 ng/ml) isomers. The EC50 for the l-isomer concentration after oral pseudoracemic verapamil (20.2 +/- 6.3 ng/ml) did not differ significantly from that after l-verapamil alone (36.9 +/- 14.7 ng/ml). We conclude that the l-isomer determines the negative dromotropic effects of verapamil and that the d-isomer is of minor importance.     

Kinetics of alpha-difluoromethylornithine: an irreversible inhibitor of ornithine decarboxylase

We gave alpha-difluoromethylornithine (DFMO), a selective, irreversible inhibitor of ornithine decarboxylase, to six health men in single intravenous doses of 5 and 10 mg/kg body weight and oral doses of 10 and 20 mg/kg. Plasma concentrations were monitored during the 24 hr after each dose. Urine was collected from 0 to 24 hr after drug and amount of unchanged drug excreted was determined. Peak plasma concentrations were reached within 6 hr after oral doses. The decay of the plasma concentrations followed first-order kinetics with a mean half-life (t 1/2) for all four doses studied of 199 +/- 6 min (+/- SD). Mean total body clearance (ClT) for the four doses was 1.20 +/- 0.06 ml . min-1 . kg-1. Mean renal clearance was determined as 0.99 +/- 0.03 ml . min-1 . kg-1, accounting for 83% of drug elimination. Mean apparent volume of distribution (aVD) was 0.337 +/- 0.031 l/kg-1, corresponding to 24 l for 70 kg of body weight. The amount of unchanged drug in 24-hr urine samples was 47 +/- 7% and 40 +/- 11% after 10 and 20 mg/kg orally, and 78% and 81 +/- 8% after 5 and 10 mg/kg intravenously. Bioavailability of the 10 mg/kg dose was estimated as 58% from the urinary recoveries and as 54% from the areas under the plasma concentration curves (AUC 0 leads to infinity). Since doubling of the dose resulted in a doubling of the mean AUC 0 leads to infinity and since other kinetic parameters, such as aVD, t 1/2, ClT, and the urinary recovery of unchanged drug, were essentially the same at all doses, DFMO kinetics follow a dose-linear model.     

Didanosine pharmacokinetics in patients with normal and impaired renal function: influence of hemodialysis.

The pharmacokinetics of didanosine were investigated following oral administration of a single 375-mg dose to eight human immunodeficiency virus-seropositive patients with normal renal function and eight human immunodeficiency virus-seropositive uremic patients. In uremic patients, the plasma half-life was longer than that in control patients (respectively, 4.5 +/- 2.2 and 1.6 +/- 0.4 h). The ratio of total plasma clearance to absolute bioavailability was four- to fivefold lower in uremic patients than in patients with normal renal function (respectively, 491 +/- 181 and 2,277 +/- 738 ml/min). Because of the decrease in elimination, concentrations in plasma were higher for uremic patients than for control patients; the maximum concentrations of drug in plasma were, respectively, 3,978 +/- 1,607 and 1,948 +/- 994 ng/ml; the areas under the concentration-time curve were, respectively, 14,050 +/- 4,262 and 3,000 +/- 956 ng.h/ml. Didanosine was removed by hemodialysis with an extraction ratio of 53% +/- 8%, a hemodialysis clearance value of 107 +/- 21 ml/min, and a fractional drug removal during a 4-h dialysis of 20% +/- 8% of the dose. Dosage adjustments are necessary in uremic patients.