Mass Balance and Metabolite Profiling of Steady-State Faldaprevir,a Hepatitis C Virus NS3/4 Protease Inhibitor,in Healthy Male Subjects

The pharmacokinetics, mass balance, and metabolite profiles of faldaprevir, a selective peptide-mimetic hepatitis C virus NS3/NS4 protease inhibitor, were assessed at steady state in 7 healthy male subjects. Subjects received oral doses of 480 mg faldaprevir on day 1, followed by 240 mg faldaprevir on days 2 to 8 and 10 to 15. [¹⁴C]faldaprevir (240 mg containing 100 μCi) was administered on day 9. Blood, urine, feces, and saliva samples were collected at intervals throughout the study. Metabolite profiling was performed using radiochromatography, and metabolite identification was conducted using liquid chromatography-tandem mass spectrometry. The overall recovery of radioactivity was high (98.8%), with the majority recovered from feces (98.7%). There was minimal radioactivity in urine (0.113%) and saliva. Circulating radioactivity was predominantly confined to plasma with minimal partitioning into red blood cells. The terminal half-life of radioactivity in plasma was approximately 23 h with no evidence of any long-lasting metabolites. Faldaprevir was the predominant circulating form, accounting for 98 to 100% of plasma radioactivity from each subject. Faldaprevir was the only drug-related component detected in urine. Faldaprevir was also the major drug-related component in feces, representing 49.8% of the radioactive dose. The majority of the remainder of radioactivity in feces (41% of the dose) was accounted for in almost equal quantities by 2 hydroxylated metabolites. The most common adverse events were nausea, diarrhea, and constipation, all of which were related to study drug. In conclusion, faldaprevir is predominantly excreted in feces with negligible urinary excretion.     

Metabolism of Vitamin D3-3H in Human Subjects: Distribution in Blood, Bile, Feces, and Urine

Vitamin D(3)-(3)H has been administered intravenously to seven normal subjects, three patients with biliary fistulas, and four patients with cirrhosis. Plasma D(3)-(3)H half-times normally ranged from 20 to 30 hours. in vivo evidence that a metabolic transformation of vitamin D occurs was obtained, and a polar biologically active vitamin D metabolite was isolated from plasma.Urinary radioactivity averaged 2.4% of the administered dose for the 48-hour period after infusion, and all the excreted radioactivity represented chemically altered metabolites of vitamin D. The metabolites in urine were mainly water-soluble, with 26% in conjugated form.From 3 to 6% of the injected radioactivity was excreted in the bile of subjects with T-tube drainage and 5% in the feces of patients having no T-tube. The pattern of fecal and biliary radioactivity suggested that the passage of vitamin D and its metabolites from bile into the intestine represents an essential stage for the fecal excretion of vitamin D metabolites in man.Abnormally slow plasma disappearance of vitamin D(3)-(3)H in patients with cirrhosis was associated with a significant decrease in the quantity and rate of glucuronide metabolite excretion in the urine.     

Disposition of [14C]aztreonam in rats, dogs, and monkeys

[14C]aztreonam was administered as single 25-mg/kg doses to dogs (intravenously and subcutaneously) and monkeys (intramuscularly and intravenously) and as single 50-mg/kg doses (intramuscularly and intravenously) to rats. In rats and dogs, radioactive moieties were excreted primarily in urine; in monkeys, they were excreted about equally in urine and feces. Unchanged aztreonam accounted for 77 to 86% of the radioactivity excreted in the urine of rats, dogs, and monkeys; SQ 26,992, the metabolite resulting from hydrolysis of the monobactam ring, accounted for 10 to 15%; and minor, unidentified metabolites accounted for the remainder. In rats with cannulated bile ducts, about 15% of an intramuscular dose was excreted in bile in 24 h; the bile contained a greater percentage of metabolites than that found in urine. In dogs, the apparent elimination half-life of aztreonam in serum was 0.7 h after intravenous administration. Aztreonam and SQ 26,992 accounted for most of the radioactivity in the sera of dogs and monkeys. Serum protein binding of aztreonam and its metabolites ranged from 28 to 35% in dogs and from 49 to 59% in monkeys. In the three species studied, aztreonam was most extensively metabolized in monkeys; SQ 26,992 and other minor metabolites from monkey urine were tested and found to be devoid of any significant antimicrobial activity.     

Metabolism of [14C]Cefmenoxime in normal subjects after intramuscular administration.

The metabolism of cefmenoxime (SCE-1365) was studied in four healthy male volunteers after intramuscular administration of a single 500-mg dose of the 14C-labeled drug. Plasma levels of total radioactivity and cefmenoxime peaked at 0.5 and 1.0 h, corresponding to 16.5 micrograms eq/ml and 15.8 micrograms/ml, respectively. Thereafter, parent drug levels declined rapidly, with a terminal elimination half-life of ca. 1.5 h. No significant differences were noted between total radioactivity and parent drug levels up to 2 h after drug administration. After 3 h, low but persistent levels of radioactivity were significantly greater than parent drug levels, indicating metabolism or degradation of cefmenoxime. The terminal elimination half-life of total radioactivity was estimated to be ca. 40 h. The radioactive plasma metabolite(s) remaining at the end of the 5-day study represented only 1% of the administered dose. Urinary excretion was the major route of elimination of cefmenoxime, accounting for ca. 86% of the dose in 12 h. Analysis of cefmenoxime in urine by total radioactivity, high-pressure liquid chromatography, and a microbiological assay showed that 80 to 92% of the excreted dose was parent drug. Radioactivity was also excreted into the feces via the bile and represented ca. 11% of the dose after 5 days. Although extensive degradation of cefmenoxime was found in fecal samples, it was proposed that this may be due to the metabolic activity of the intestinal flora rather than in vivo biotransformation in the liver. This study supports the concept that cefmenoxime undergoes minimal metabolism in humans and is excreted largely as unchanged drug.     

Metabolism and disposition of amifloxacin in laboratory animals.

Sprague-Dawley rats received [14C]amifloxacin mesylate either orally or intravenously at 20 mg (base equivalent) per kg. Blood radioactivity peaked at 0.5 h after oral administration and was equivalent to 7.54 micrograms/ml for males and 6.73 micrograms/ml for females. After intravenous administration to rats, 52.5% of the dose was recovered in the urine of males and 45.3% in the urine of females within 72 h. The corresponding values after oral administration were 50.8% for males and 37.2% for females. The remainder of the dose was recovered in the feces. After intravenous administration of [14C]amifloxacin mesylate at 10 mg (base equivalent) per kg to female rhesus monkeys, 80.3% of the radioactivity was excreted in the urine at 24 h. The apparent first-order terminal elimination half-life of intact amifloxacin in plasma was 2.3 h; radioactivity in plasma was eliminated more slowly. Male rats excreted 26.2% of the dose in the urine as amifloxacin and 17.8% as the piperazinyl-N-oxide derivative of amifloxacin after intravenous administration. The corresponding amounts for female rats were 29.0% as amifloxacin and 7.8% as the piperazinyl-N-oxide metabolite. Similar excretion profiles were observed after oral administration. After intravenous administration, female monkeys excreted 54.5% of the dose in the urine as amifloxacin, 12.9% as the piperazinyl-N-desmethyl metabolite, and 5.6% as the piperazinyl-N-oxide during the first 12 h. In contrast, there was no evidence of the piperazinyl-N-desmethyl metabolite in rats.     

Disposition of posaconazole following single-dose oral administration in healthy subjects

Posaconazole is a potent, broad-spectrum triazole antifungal agent currently in clinical development for the treatment of refractory invasive fungal infections. Eight healthy male subjects received a single 399-mg (81.7 microCi) oral dose of [(14)C]posaconazole after consuming a high-fat breakfast. Urine, feces, and blood samples were collected for up to 336 h postdose and assayed for total radioactivity; plasma and urine samples were also assayed for parent drug. Posaconazole was orally bioavailable, with a median maximum posaconazole concentration in plasma achieved by 10 h postdose. Thereafter, posaconazole was slowly eliminated, with a mean half-life of 20 h. The greatest peak in the radioactivity profile of pooled plasma extracts was due to posaconazole, with smaller peaks due to a monoglucuronide, a diglucuronide, and a smaller fragment of the molecule. The mean total amount of radioactivity recovered was 91.1%; the cumulative excretion of radioactivity in feces and in urine was 76.9 and 14.0% of the dose, respectively. Most of the fecal radioactivity was associated with posaconazole, which accounted for 66.3% of the administered dose; however, urine contained only trace amounts of unchanged posaconazole. The radioactivity profile of pooled urine extracts included two monoglucuronide conjugates and a diglucuronide conjugate of posaconazole. These observations suggest that oxidative (phase 1) metabolism by cytochrome P450 isoforms represents only a minor route of elimination for posaconazole, and therefore cytochrome P450-mediated drug interactions should have a limited potential to impact posaconazole pharmacokinetics.     

Pharmacokinetics of [14C]FCE 22891, a penem antibiotic, following oral administration to healthy volunteers.

FCE 22891 is a prodrug of the penem antibiotic FCE 22101 and is suitable for oral administration. The pharmacokinetics of FCE 22891 were investigated in four healthy male volunteers following the oral administration of 500 mg of [14C]FCE 22891. Levels of radioactivity in plasma were always higher and persisted for longer than those of FCE 22101. The time to the maximum concentration of radioactivity in plasma generally coincided with that of FCE 22101. The respective values for the maximum concentrations of radioactivity in plasma were, on average, 8.57 +/- 2.95 micrograms equivalent/ml and 2.97 +/- 2.05 micrograms/ml. Over a 5-day period, mean urinary and fecal recovery of radioactivity accounted for 53.2 and 41.0% of the dose, respectively. The average amount of FCE 22101 excreted in urine and feces corresponded to 9.0 and 1.6% of the dose, respectively. The urinary recovery of the open-ring metabolite P1 and of its 5-S epimer P2 accounted for about 6.5 and 1.2% of the dose, respectively. Other chromatographic peaks corresponding to nonidentified compounds accounted for about 14.0% (polar metabolite fraction; peak P), 3.7% (less polar fraction; peak X), and 15.4% (least polar fraction) of the dose. Elimination of radioactivity and FCE 22101 in urine was rapid. Intersubject variability in the kinetics of total radioactivity in plasma was far less than that observed for FCE 22101. The results of the present study support suggestions that presystemic metabolism of FCE 22101 and/or transformation of the prodrug to compounds other than FCE 22101 are the main cause of intersubject variability in the kinetics of FCE 22101 produced in plasma following oral administration of its prodrug.     

Metabolism of S-1108, a new oral cephem antibiotic, and metabolic profiles of its metabolites in humans.

The metabolism and pharmacokinetics of pivalic acid, a major metabolite of S-1108, were studied with three healthy volunteers. Concentrations of S-1006 (the active compound), pivalic acid, and pivaloylcarnitine in plasma and urine were measured after administration of S-1108. Recoveries in urine at the doses of S-1108 given (100 and 200 mg) were 33 to 41% for S-1006, 93% for total pivalic acid, and 89 to 94% for pivaloylcarnitine in 24 h, and maximum concentrations in plasma were 2 micrograms of S-1006 per ml, 1 micrograms of total pivalic acid per ml, and 2 micrograms of pivaloylcarnitine per ml after a 200-mg oral administration of S-1108. More than 90% of the pivalic acid was excreted as pivaloylcarnitine, and no measurable amount of free pivalic acid was present in urine samples, indicating that the pivalic acid liberated from S-1108 was almost quantitatively conjugated with carnitine in the human body. The level of free carnitine in plasma was unaffected by a single 200-mg administration of S-1108, whereas urinary excretion of free carnitine decreased as levels of acylcarnitine increased. The acylcarnitines were excreted primarily in the form of pivaloylcarnitine. This study clearly showed how the pivalic acid was metabolized and excreted in humans. The importance of monitoring carnitine, an essential cofactor in fatty acid metabolism, was also discussed in terms of its utilization by pivalic acid.     

Disposition, metabolism, and excretion of [14C]doripenem after a single 500-milligram intravenous infusion in healthy men

In this open-label, single-center study, eight healthy men each received a single 500-mg dose of [¹⁴C]doripenem, containing 50 μCi of [¹⁴C]doripenem, administered as a 1-h intravenous infusion. The concentrations of unchanged doripenem and its primary metabolite (doripenem-M-1) resulting from β-lactam ring opening were measured in plasma and urine by a validated liquid chromatography method coupled to a tandem mass spectrometry assay. Total radioactivity was measured in blood, plasma, urine, and feces by liquid scintillation counting. Further metabolite profiling was conducted on urine samples using liquid chromatography coupled to radiochemical detection and high-resolution mass spectrometry. Unchanged doripenem and doripenem-M-1 accounted for means of 80.7% and 12.7% of the area under the plasma total-radioactivity-versus-time curve (area under the concentration-time curve extrapolated to infinity) and exhibited elimination half-lives of 1.1 and 2.5 h, respectively. Total clearance of doripenem was 16 liters/h, and renal clearance was 12.5 liters/h. At 7 days after the single dose, 95.3% of total doripenem-related radioactivity was recovered in urine and 0.72% in feces. A total mean of 97.2% of the administered dose was excreted in the urine as unchanged doripenem (78.7% ± 5.7%) and doripenem-M-1 (18.5% ± 2.6%). Most of the urinary recovery occurred within 4 h of dosing. Three additional minor metabolites were identified in urine: the glycine and taurine conjugates of doripenem-M-1 and oxidized doripenem-M-1. These results show that doripenem is predominantly eliminated in urine as unchanged drug, with only a fraction metabolized to doripenem-M-1 and other minor metabolites.     

Disposition of S-1108, a new oral cephem antibiotic, and metabolic fate of pivalic acid liberated from [pivaloyl-14C]S-1108 in rats and dogs.

[pivaloyl-14C]S-1108, which is 14C labeled at the pivalic acid moiety of the pivaloyloxymethyl side chain of S-1108, was administered orally to rats and dogs, and the disposition of pivalic acid cleft from S-1108 was examined. Besides pivaloylcarnitine and pivaloylglucuronide, pivaloylglycine was identified in dog urine as a metabolite of pivalic acid by thin-layer chromatography and high-performance liquid chromatography analysis. The concentrations in the plasma of rats to which doses of 6.65, 26.6, and 532 mg/kg of body weight were administered showed dose-proportionate levels. The radioactivity was eliminated rapidly, with a half-life of approximately 3 h until 24 h at both the 6.65- and 26.6-mg/kg doses. Free pivalic acid in plasma accounted for more than 80% of the concentration of radioactivity. Radioactivity was distributed throughout the body and was eliminated quickly at a rate similar to that of radioactivity from plasma. Most of the absorbed radioactivity was excreted in the urine, and it was completed within 24 h after administration. In dogs, the half-life of radioactivity in plasma was longer than that in the rats. The ratio of free pivalic acid in plasma was 60 to 70% of the radioactivity in plasma. The concentration of radioactivity in the liver, cortex of the kidney, and skeletal muscle 144 h after oral dosing was more than 10 times higher than the concentration in plasma for all doses. Urinary excretion in dogs was slower than that in rats. The differences in the disposition of pivalic acid between dogs and rats may account for differences in the degree of skeletal muscle disorders. The safety in humans of S-1108 given at 200 mg three times a day is discussed in relation to the metabolic formation of the carnitine conjugate of pivalic acid and the reduction of the carnitine concentration in plasma.     

Pharmacokinetics and metabolism of genaconazole, a potent antifungal drug, in men.

The pharmacokinetics of genaconazole, a racemic triazole antifungal agent comprising 50% RR and 50% SS enantiomers, were studied in 12 healthy male volunteers after a single oral dose of 200 mg. The serum samples were analyzed for the two enantiomers by using a chiral high-pressure liquid chromatography assay. The concentrations of the RR and SS enantiomers in serum were virtually identical. The mean values for the maximum concentrations in serum (Cmax) (1.7 micrograms/ml), times to Cmax (4.0 to 4.2 h), half-lives (83 h), and areas under the concentration-time curve from 0 h to infinity (195 to 199 micrograms.h/ml) were similar for the two enantiomers. The results showed that the pharmacokinetic profiles of the two enantiomers were similar after a single oral dosing of the racemate. The pharmacokinetics of the RR enantiomer were also evaluated in 12 healthy male volunteers after a single oral dose of 100 or 200 mg. The ratios of the Cmaxs and of the areas under the concentration-time curves from 0 h to infinity for the two doses were about 2, indicating a dose proportionality. In a separate study, six healthy male volunteers received a single oral dose of 50 mg of 14C-labeled genaconazole. The Cmax values for total radioactivity (14C) and intact genaconazole were virtually identical (0.6 micrograms/ml). The mean half-lives in serum were about 73 h for both total radioactivity and genaconazole. The amounts of total radioactivity excreted in the 0 to 240-h interval (representing approximately three half-lives) in urine and feces were 66.6 and 9.3% of the dose, respectively; 64.4% of the dose was excreted in urine as parent drug. There were no detectable metabolites in either serum or urine. The data demonstrate that genaconazole (racemate) is well absorbed, undergoes negligible biotransformation, and is slowly excreted, primarily in the urine.     

Pharmacokinetics of [(14)C]abacavir, a human immunodeficiency virus type 1 (HIV-1) reverse transcriptase inhibitor, administered in a single oral dose to HIV-1-infected adults: a mass balance study

Abacavir (1592U89) ((-)-(1S, 4R)-4-[2-amino-6-(cyclopropylamino)-9H-purin-9-yl]-2-cyclopentene- 1-m ethanol) is a 2'-deoxyguanosine analogue with potent activity against human immunodeficiency virus (HIV) type 1. To determine the metabolic profile, routes of elimination, and total recovery of abacavir and metabolites in humans, we undertook a phase I mass balance study in which six HIV-infected male volunteers ingested a single 600-mg oral dose of abacavir including 100 microCi of [(14)C]abacavir. The metabolic disposition of the drug was determined through analyses of whole-blood, plasma, urine, and stool samples, collected for a period of up to 10 days postdosing, and of cerebrospinal fluid (CSF), collected up to 6 h postdosing. The radioactivity from abacavir and its two major metabolites, a 5'-carboxylate (2269W93) and a 5'-glucuronide (361W94), accounted for the majority (92%) of radioactivity detected in plasma. Virtually all of the administered dose of radioactivity (99%) was recovered, with 83% eliminated in urine and 16% eliminated in feces. Of the 83% radioactivity dose eliminated in the urine, 36% was identified as 361W94, 30% was identified as 2269W93, and 1.2% was identified as abacavir; the remaining 15.8% was attributed to numerous trace metabolites, of which <1% of the administered radioactivity was 1144U88, a minor metabolite. The peak concentration of abacavir in CSF ranged from 0.6 to 1.4 microg/ml, which is 8 to 20 times the mean 50% inhibitory concentration for HIV clinical isolates in vitro (0.07 microg/ml). In conclusion, the main route of elimination for oral abacavir in humans is metabolism, with <2% of a dose recovered in urine as unchanged drug. The main route of metabolite excretion is renal, with 83% of a dose recovered in urine. Two major metabolites, the 5'-carboxylate and the 5'-glucuronide, were identified in urine and, combined, accounted for 66% of the dose. Abacavir showed significant penetration into CSF.     

Absorption of colesevelam hydrochloride in healthy volunteers

OBJECTIVE: To assess whether colesevelam hydrochloride is absorbed in healthy volunteers. METHODS: A single-center, open-label, radiolabeled study was performed with 16 healthy volunteers. Subjects were administered non-radiolabeled colesevelam hydrochloride 1.9 g twice daily for 4 weeks, followed by a single dose of [14C]-colesevelam 2.4 g (480 pCi). These subjects continued to receive non-radioactive colesevelam 1.9 g twice daily for 4 days after administration of the radiolabeled dose. Blood, urine, and feces were collected immediately prior to administration of [14C]-colesevelam and at specified intervals after administration. The whole-blood equivalent concentration of colesevelam was calculated using data collected throughout the 96 hours following radiolabeled drug administration. The proportion of [14C]-colesevelam excreted through urine or feces was calculated based on the amount of radioactivity recovered up to 216 hours after the radiolabeled dose. RESULTS: The mean cumulative total recovery of [14C]-colesevelam in urine and feces was 0.05% and 74%, respectively. Excluding 2 subjects for whom cumulative recovery was <25%, the mean cumulative fecal recovery was 82%. The mean maximum whole-blood equivalent concentration of colesevelam was 0.165+/-0.10 microg equiv/g 72 hours after administration of [14C]-colesevelam, which was estimated to be 0.04% of the administered dose. All blood samples contained <4 times the number of background counts (dpm). CONCLUSIONS: The cumulative recovery data in urine and feces are consistent with the conclusion that colesevelam is not absorbed and is excreted entirely through the gastrointestinal system.     

Spironolactone. II. Bioavailability.

The bioavailability of commercial 25-mg spironolactone tablets and a new tablet preparation containing 100 mg of the drug has been determined in 12 healthy male subjects. After a 200-mg oral dose of the drug given in a solution of polyethylene glycol-400, the peak plasma level of the dethioacetylated metabolite canrenone was 633 +/- 154 ng/ml (mean +/- SD) and was reached at 1.4 +/- 0.43 hr. This peak was higher and was achieved earlier than after either eight 25-mg tablets (480 +/- 155 ng/ml at 2.9 +/- 1.03 hr) or two 100-mg tablets (474 +/- 182 ng/ml at 3.0 +/- 1.37 hr). From the ratio of the 24-hr area under the plasma concentration-time curves, the bioavailabilities of the two tablet preparations relative to the solution were 99.6 +/- 18.2% and 92.1 +/- 22.9%, respectively. The amount of canrenone excreted in the urine by 48 hr was 4.48 +/- 1.26 mg (solution), 6.36 +/- 2.02 mg (eight 25-mg tablets), and 7.81 +/- 1.87 mg (two 100-mg tablets), representing 2% to 4% of the administered dose. It is concluded that urinary excretion of canrenone alone is not a reliable method for determining the bioavailability of spironolactone.     

Comparative metabolism of chloramphenicol in germfree and conventional rats.

The action of gut microflora on the metabolism of chloramphenicol (CP) was studied in germfree (GF) and conventional (CV) rats after administration of single oral doses of tritiated CP. There were similarities in the metabolic pathways of CP in the GF and CV animals, i.e., rapid absorption, hepatic glucuroconjugation, and biliary excretion of the CP conjugate. CP, CP-oxamic acid, CP-alcohol, and CP-base were present in similar proportions in the urine of both GF and CV rats. Differences observed included the slow elimination of total radioactivity and a reduced proportion of the urinary excretion versus the fecal excretion in the GF Reduction products which were present in much greater quantities in the urine and feces of CV rats are compatible with the generally described hydrolysis of the CP-glucuronide, followed by a nitroreduction of the CP by the gut microflora and the reabsorption of a part of the products formed. In GF rats, CP-glucuronide was the major fecal metabolite, a portion of it having been reabsorbed and excreted in the urine. Although in lesser amounts, reduction products were still present as urinary metabolites in GF rats. Such a reduction in the tissues might produce active intermediate that could be related to CP toxicity.     

The anaerobic metabolism of metronidazole forms N-(2-hydroxyethyl)-oxamic acid.

N-(2-hydroxyethyl)-oxamic acid is formed when metronidazole is reduced either chemically or by the action of the intestinal bacteria. When metronidazole, labeled with carbon-14 in the hydroxyethyl side chain, is administered by gavage to rats in doses of 200 mg/kg, an average of 1.4% of the administered radioactivity is recovered in the urine in the form of N-(2-hydroxyethyl)-oxamic acid. The presence of conjugated N-(2-hydroxyethyl)-oxamic acid in some samples was suggested by the detection of small additional amounts of the free acid after treatment of the urine with beta-glucuronidase. The metabolite is not found in the feces. In contrast N-(2-hydroxyethyl)-oxamic acid is not found in the urine or feces of germfree rats which receive metronidazole. Thus, the finding of N-(2-hydroxyethyl)-oxamic acid in the urine of rats which receive metronidazole appears to depend on the activity of the bacterial flora.     

Plasma amprenavir pharmacokinetics and tolerability following administration of 1,400 milligrams of fosamprenavir once daily in combination with either 100 or 200 milligrams of ritonavir in healthy volunteers

Once-daily (QD) fosamprenavir (FPV) at 1,400 mg boosted with low-dose ritonavir (RTV) at 200 mg is effective when it is used in combination regimens for the initial treatment of human immunodeficiency virus infection. Whether a lower RTV boosting dose (i.e., 100 mg QD) could ensure sufficient amprenavir (APV) concentrations with improved safety/tolerability is unknown. This randomized, two 14-day-period, crossover pharmacokinetic study compared the steady-state plasma APV concentrations, safety, and tolerability of FPV at 1,400 mg QD boosted with either 100 mg or 200 mg of RTV QD in 36 healthy volunteers. Geometric least-square (GLS) mean ratios and the associated 90% confidence intervals (CIs) were estimated for plasma APV maximum plasma concentrations (Cmax), the area under the plasma concentration-time curve over the dosing period (AUC0-tau), and trough concentrations (Ctau) during each dosing period. Equivalence between regimens (90% CIs of GLS mean ratios, 0.80 to 1.25) was observed for the plasma APV AUC0-tau (GLS mean ratio, 0.90 [90% CI, 0.84 to 0.96]) and Cmax (0.97 [90% CI, 0.91 to 1.04]). The APV Ctau was 38% lower with RTV at 100 mg QD than with RTV at 200 mg QD (GLS mean ratio, 0.62 [90% CI, 0.55 to 0.69]) but remained sixfold higher than the protein-corrected 50% inhibitory concentration for wild-type virus, with the lowest APV Ctau observed during the 100-mg QD period being nearly threefold higher. The GLS mean APV Ctau was 2.5 times higher than the historical Ctau for unboosted FPV at 1,400 mg twice daily. Fewer clinical adverse drug events and smaller increases in triglyceride levels were observed with the RTV 100-mg QD regimen. Clinical trials evaluating the efficacy and safety of FPV at 1,400 mg QD boosted by RTV at 100 mg QD are now under way with antiretroviral therapy-na?ve patients.     

Interaction of ritonavir-boosted tipranavir with loperamide does not result in loperamide-associated neurologic side effects in healthy volunteers

Loperamide (LOP) is a peripherally acting opioid receptor agonist used for the management of chronic diarrhea through the reduction of gut motility. The lack of central opioid effects is partly due to the efflux activity of the multidrug resistance transporter P-glycoprotein (P-gp) at the blood-brain barrier. The protease inhibitors are substrates for P-gp and have the potential to cause increased LOP levels in the brain. Because protease inhibitors, including tipranavir (TPV), are often associated with diarrhea, they are commonly used in combination with LOP. The level of respiratory depression, the level of pupil constriction, the pharmacokinetics, and the safety of LOP alone compared with those of LOP-ritonavir (RTV), LOP-TPV, and LOP-TPV-RTV were evaluated in a randomized, open-label, parallel-group study with 24 healthy human immunodeficiency virus type 1-negative adults. Respiratory depression was assessed by determination of the ventilatory response to carbon dioxide. Tipranavir-containing regimens (LOP-TPV and LOP-TPV-RTV) caused decreases in the area under the concentration-time curve from time zero to infinity for LOP (51% and 63% decreases, respectively) and its metabolite (72% and 77% decreases, respectively), whereas RTV caused increases in the levels of exposure of LOP (121% increase) and its metabolite (44% increase). In vitro and in vivo data suggest that TPV is a substrate for and an inducer of P-gp activity. The respiratory response to LOP in combination with TPV and/or RTV was not different from that to LOP alone. There was no evidence that LOP had opioid effects in the central nervous system, as measured indirectly by CO2 response curves and pupillary response in the presence of TPV and/or RTV.     

Spironolactone. I. Disposition and metabolism.

This study describes absorption, excretion, and metabolism of[20(-3)H]-spironolactone (SP) in 5 healthy men. After a single oral dose (200 mg + 200 muCi) of the drug given in alcoholic solution, the peak serum levels of the ethyl acetate-extractable tritium and the dethioacetylated metabolite canrenone were 763 +/- 400 ng/ml (mean +/- SD) and 415 +/- 145 ng/ml, respectively. These levels occurred within 3 hr. The serum half-life (T1/2) of the extractable materials was 37.3 +/- 6.53 hr. Canrenone levels declined in two phases. The T1/2 from 2.5 to 12 hr was 4.42 +/- 1.07 hr and from 12 to 72 hr was 16.8 +/- 2.75 hr. In the blood both SP and canrenone were confined largely in the plasma, and their protein binding exceeded 89% at concentrations of 550 and 710 ng/ml, respectively. In 5 days 31.6 +/- 5.87% of the radioactivity was excreted in the urine and 22.7 +/- 14.1% in the feces. Unchanged SP was not detected in the urine. The major urinary metabolites were canrenone (5.04 +/- 2.83% of dose), 6beta-OH-sulfoxide (5.21 +/- 0.93% of dose), and canrenoate ester glucuronide (6.2% of dose).     

Mass balance study of [14C]M100240, a dual angiotensin-converting enzyme/neutral endopeptidase inhibitor,in healthy male subjects

[4S-[4alpha,7alpha(R*),12bbeta]]-7[[2-(acetylthio)-1-oxo-3-phenylpropyl]amino]-1,2,3,4,6,7,8,12b-octahydro-6-oxo-pyrido[2,1-a][2]benzazepine-4-carboxylic acid (M100240) is an acetate thioester of MDL 100,173-a dual angiotensin-converting enzyme/neutral endopeptidase inhibitor currently in phase II development. The mass balance of [(14)C]M100240 was assessed following oral administration of [(14)C]M100240. Healthy male subjects were given a single 25-mg dose of [(14)C]M100240 (50 microCi) as an oral solution under fasting conditions. Blood samples and excreta were collected postdose. (14)C-radioactivity was measured by liquid scintillation counting. Plasma concentrations of M100240 and MDL 100,173 were determined by LC/MS/MS methods. Pharmacokinetic parameters were calculated. About 98% of the total radioactive dose was recovered within 7 days of oral administration, with most of the radioactivity recovered within 72 hours. Of the recovered radioactive dose, 49.4% and 48.5% were recovered in the urine and feces, respectively. Unchanged M100240 and MDL 100,173 were not detected in the excreta. On average, 76% of the total radioactivity in the blood was associated with the plasma fraction. M100240 accounted for less than 0.06% of the (14)C-radioactivity in plasma and MDL 100,173 accounted for 15.8% (AUC( infinity )) of (14)C-radioactivity in plasma after oral dosing. These data suggest that the drug was absorbed but rapidly converted to its metabolites either presystemically or postsystemically. Up to 78% of the total radioactivity was identified as MDL 100,173. The apparent terminal elimination half-life of MDL 100,173 was longer than that of (14)C-radioactivity, attributable to assay sensitivity and the saturable binding phenomenon commonly associated with angiotensin-converting enzyme inhibitors. M100240 undergoes extensive metabolism in humans, and its metabolites are excreted relatively equally in feces and urine.