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.     

Absorption,pharmacokinetics and excretion of levovirin in rats,dogs and cynomolgus monkeys

The absorption, pharmacokinetics and excretion of levovirin were studied in Sprague-Dawley rats (30 mg/kg) and Beagle dogs (30 mg/kg) following intravenous (iv) and oral administration of [(3)H]levovirin, and in Cynomolgus monkeys following iv and oral administration of [(14)C]levovirin. Oral absorption was 31.3% in rats, 67.3% in dogs and 17.5% in monkeys, and the bioavailability was 29.3% in rats, 51.3% in dogs and 18.4% in monkeys. After iv administration, the elimination half-life (t(1/2)) was 1.47 h in rats, 3.70 h in dogs and 3.50 h in monkeys. The total body clearance was 8.24, 2.96 and 2.58 mL/min per kg, respectively, in rats, dogs and monkeys and the apparent volume of distribution was 0.79, 0.95 and 0.65 L/kg. No metabolite was detected in plasma or urine of rats, dogs or monkeys, indicating negligible metabolism of levovirin in these animals. Excretion of total radioactivity in urine after oral dosing accounted for 15.4% of the administered dose in rats, 49.9% in dogs and 21.4% in monkeys. Biliary excretion did not play a significant role in the elimination of levovirin.     

Pharmacokinetics and metabolism of [14C]viramidine in rats and cynomolgus monkeys

The pharmacokinetics of [(14)C]viramidine, a prodrug of ribavirin, were studied in rats (30 mg/kg of body weight) and monkeys (10 mg/kg) following intravenous (i.v.) and oral administration. The levels of oral absorption and bioavailabilities were 61.7 and 9.91%, respectively, in rats and 43.9 and 13.6%, respectively, in monkeys. Following i.v. administration, the elimination half-lives were 2.7 h in rats and 28.9 h in monkeys. Total body clearances were 14.0 liters/h/kg in rats and 1.23 liters/h/kg in monkeys; the apparent volumes of distribution were 15.6 liters/kg in rats and 18.6 liters/kg in monkeys. Following oral administration, viramidine was extensively converted to ribavirin, followed by further metabolism of ribavirin in both species, with a faster rate of metabolism in rats than in monkeys. In rats, excretion of total radioactivity in urine accounted for 77.0% of the i.v. dose and 60.8% of the oral dose, while in monkeys it accounted for 44.4% of the i.v. dose and 39.0% of the oral dose. The amount of unchanged viramidine and ribavirin in urine was small in both species after i.v. and oral administration of viramidine.     

Preclinical pharmacology and pharmacokinetics of the anti-hepatitis virus agent 2''-fluoro-5-ethyl-1-beta-D-arabinofuranosyluracil in mice and rats.

The preclinical pharmacology and pharmacokinetics of 2'-fluoro-5-ethyl-1-beta-D-arabinofuranosyluracil (FEAU), a selective inhibitor of herpesvirus and hepatitis virus replication, were investigated in the mouse and rat. Following intravenous (i.v.) or oral (p.o.) administration, FEAU was cleared from the plasma primarily unchanged, with a terminal half-life of 58 to 80 min in the mouse and 63 to 78 min in the rat. The steady-state volumes of distribution times bioavailabilities of FEAU were approximately 2.1 and 3.4 times the total body water volumes after p.o. administration of 10 mg of drug per kg of body weight in mice and rats, respectively. A comparison of the area under the concentration-time curve after i.v. and p.o. FEAU administration indicated that the p.o. dose was completely absorbed in both species. When tritiated FEAU was used in mice, 35.0% of the i.v. dose and 33.5% of the p.o. dose were excreted in urine as unchanged FEAU, 8.1% (i.v. dose) and 9.2% (p.o. dose) were excreted as tritiated water, and 15.6% (i.v. dose) and 18.1% (p.o. dose) were excreted as unknown metabolite(s) in urine within 24 h of dosing. Only 1.24% (i.v. dose) and 2.6% (p.o. dose) of the total doses were found in urine as 3H2O when the FEAU dose was increased to 50 mg/kg. However, a higher percentage of the total dose (59.6% for the i.v. dose and 61.3% for the p.o. dose) was recovered within 24 h as intact FEAU in rat urine, less than 1.4% (i.v. dose) and 2.7% (p.o. dose) of the total dose were found to be 3H2O, and 5.6% (i.v. dose) and 6.7% (p.o. dose) of the total dose were excreted as known metabolite(s). The distribution ratios for total radioactivity in tissue relative to those in plasma were 0.5 to 1.3 in spleen, testes, muscle, and liver during the first hour after a 10-mg/kg dose in rats. Of the total FEAU radioactivity administered, only 1.38% was excreted in bile as unchanged FEAU. No FEAU glucuronide metabolite was detected. Tissue concentrations of 0.15 to 0.6 microM at 6 h after dosing are in the range of the effective antiviral concentration for FEAU. In conclusion, FEAU administered p.o. to mice and rats was well absorbed; FEAU was rapidly distributed into tissues and remained above in vitro antiviral concentrations for more than 6 h; in mice, [3H]FEAU showed metabolism-mediated tritium exchange with water; and in rats, FEAU was less extensively metabolized than in mice and clearance was primarily via renal processes, mainly in the form of unchanged FEAU.     

Preliminary study of the pharmacokinetics of oral amifloxacin in elderly subjects.

Amifloxacin pharmacokinetics after a single oral dose in healthy elderly subjects were determined. Five males and five females aged 65 to 79 years and having creatinine clearances of 39.3 to 87.2 ml/h per kg of body weight were given a 200-mg amifloxacin caplet following an overnight fast. Mean (standard deviation) pharmacokinetic parameters for amifloxacin were as follows: maximum observed concentration in plasma, 1.13 (0.48) and 1.95 (0.52) micrograms/ml; half-life, 5.37 (0.96) and 4.47 (0.87) h; total plasma clearance (unadjusted for fraction absorbed), 259 (53) and 199 (55) ml/h per kg; renal clearance, 113 (20) and 86 (26) ml/h per kg; Varea/F (Varea is volume of distribution; F is fraction absorbed), 2.05 (0.75) and 1.28 (0.39) liter/kg; and amifloxacin excreted in the urine, 42.5% (14.5%) and 42.8% (10.6%) for males and females, respectively. There were no statistically significant differences in pharmacokinetic parameters between sexes that could not be attributed to differences in body weight. Except for a modest 23% reduction in renal clearance and the suggestion of reduced bioavailability, mean values of pharmacokinetic parameters for elderly male subjects were similar to those previously determined for younger male volunteers. Therefore, a modification in amifloxacin dosage regimen based solely on age may not be necessary.     

Analysis of amifloxacin in plasma and urine by high-pressure liquid chromatography and intravenous pharmacokinetics in rhesus monkeys.

An analytical method for the quantitation of amifloxacin, 6-fluoro-1,4-dihydro-1-(methylamino)-7-(4-methyl-1-piperazinyl)-4-oxo-3- quinolinecarboxylic acid, in plasma and urine has been developed. The method involves extraction with chloroform, back-extraction into 0.1 M sodium hydroxide, and subsequent analysis by reverse-phase high-pressure liquid chromatography with UV detection. The precision of the assay calculated as the overall standard deviation was +/- 4.9% in plasma and +/- 1.1% in urine. The range of mean percent differences from the nominal values was used as an estimate of accuracy and was 93.6 to 103% of the nominal values in plasma and 95.2 to 107% of the nominal values in urine. The minimum quantifiable levels were 0.032 micrograms/ml in plasma and 2.7 micrograms/ml in urine. The methods were employed in a pharmacokinetic analysis of amifloxacin after intravenous administration to rhesus monkeys. The decline in drug plasma levels was described by a biexponential process with mean rates of 8.4 h-1 and 0.32 h-1 with corresponding half-lives of ca. 5 min and 2.2 h. Amifloxacin was rapidly excreted, with ca. 53% of the dose appearing in the urine within 48 h after medication. The mean renal clearance +/- standard deviation was 4.4 +/- 1.0 ml X kg-1 X min-1 and is compatible with passive glomerular filtration in this species.     

Pharmacokinetics and metabolism of [14C]rosaramicin in dogs.

The pharmacokinetics and metabolism of [14C]rosaramicin were studied in dogs after intravenous (i.v.; 10 mg/kg [bodyweight]) and oral (25 mg/kg) administration. After i.v. administration, rosaramicin levels in plasma declined rapidly, with half-lives of 0.22 h for the distribution phase and 0.97 h for the elimination phase. The apparent volume of distribution was 3.43 liters/kg, and the total body clearance was 106 mg/min . kg, indicating extensive distribution in tissue or metabolism or both. The absorption of oral solution was 58%, and the absolute bioavailability of rosaramicin was 35%. The plasma area under the curve of unchanged rosaramicin was only 5% that of total radioactivity after oral administration and 8% after i.v. administration, indicating extensive metabolism of the drug. The total radioactivity excreted in urine accounted for only 24% of the i.v. dose and 17% of the oral dose. Fecal radioactivity accounted for 71% of the i.v. dose and 68% of the oral dose. Several metabolites were observed in the plasma and urine. The amount of unchanged rosaramicin in urine (1 to 2% of the dose) was quite small after drug administration by either route.     

Metabolic disposition of DQ-2556, a new cephalosporin, in rats, rabbits, dogs, and monkeys.

The metabolic disposition of DQ-2556 was studied in rats, rabbits, dogs, and monkeys after an intravenous administration of 20 mg of 14C-labeled drug per kg of body weight. The serum data were analyzed by the two-compartment open model. The mean half-lives for the drug in serum at excretion phase were 18.1, 54.4, 21.8, and 63.6 min in rats, rabbits, dogs, and monkeys, respectively. The volume of distribution and total body clearance ranged from 0.18 to 0.30 liter/kg and 0.065 to 0.45 liter/h/kg, respectively. This compound was distributed to the tissues rapidly and well, especially to the kidney, trachea, liver, thyroid, skin, and lung. Tissue concentrations declined rapidly in a few hours and then very slowly. However, no accumulation was observed in any tissues. The results of a protein-binding study by ultracentrifugation indicated that DQ-2556 was 20 to 30% bound to serum proteins in animals and its affinity was low. Almost 90% of the administered radioactivity was excreted into urine in all species. Biliary excretion in rats was 3.1% of the dose. Nearly 70% of the dose or more was excreted into urine as unchanged drug, and the amounts of urinary metabolites were small except in rabbits, in which substantial amounts of polar metabolites were detected.     

Pharmacokinetics and metabolism of [(14)C]ribavirin in rats and cynomolgus monkeys

Absorption, pharmacokinetics, distribution, metabolism, and excretion of [(14)C]ribavirin were studied in rats (30 mg/kg of body weight) and cynomolgus monkeys (10 mg/kg) after intravenous (i.v.) and oral administration. The oral absorption and bioavailability were 83 and 59%, respectively, in rats and 87 and 55%, respectively, in monkeys. After i.v. administration, the elimination half-life (t([1/2])) was 9.9 h in rats and 130 h in monkeys and the total body clearance was 2,600 ml/h/kg in rats and 224 ml/h/kg in monkeys. The apparent volume of distribution was 11.4 liter/kg in rats and 29.4 liter/kg in monkeys. There was extensive distribution of drug-derived radioactivity into red blood cells and extensive metabolism of ribavirin in rats and a lesser degree of metabolism in monkeys. Excretion of total radioactivity in urine from rats accounted for 84% of the i.v. dose and 83% of the oral dose, whereas that from monkeys accounted for 47% of the i.v. dose and 67% of the oral dose. Several metabolites were observed in plasma and urine from both species. The amount of unchanged ribavirin in urine from both species was quite small after either i.v. or oral administration.     

Absorption, disposition, and urinary metabolism of 14C-rifabutin in rats.

14C-rifabutin was given orally (25 mg/kg) and intravenously (i.v.) (10 mg/kg) to female Sprague-Dawley rats. Radioactivity was eliminated by both the renal and fecal routes, amounting to 44.49 and 43.39% of the dose, respectively, in urine and feces at 96 h after the oral dose and to 47.81 and 40.76% of the dose, respectively, in urine and feces after the i.v. dose. Differences between the two routes of administration were negligible. Tissue distribution of radioactivity after the oral dose was investigated by the combustion technique. At 2 h, the highest concentration of radioactivity was observed in the liver, followed by the lung, abdominal adipose tissue, and spleen, whereas at 72 h, the sequence was abdominal adipose tissue, liver, spleen, bone marrow, and lung. Brain levels of radioactivity were very low. The results of whole-body autoradiography after i.v. administration confirmed the above. Whole-body autoradiography of pregnant rats showed higher concentrations of radioactivity in the uterus than in the placenta and trace levels in the fetuses up to 8 h. Radioactivity was absent in the amniotic fluid. The urinary metabolism was studied by radio-high-pressure liquid chromatography. Rifabutin accounted for 7.4 and 7.2% of the dose in 0- to 48-h urine after oral and i.v. administration, respectively. Metabolites 31-OH rifabutin and 25-O-deacetyl rifabutin amounted to 4.3 and 1.6% of the dose, respectively, after oral administration and to 2.6 and 0.7% of the dose, respectively, after i.v. administration. The remaining urinary radioactivity was mainly due to polar compounds.     

Single-dose pharmacokinetics and metabolism of [14C]remofovir in rats and cynomolgus monkeys

Single-dose pharmacokinetics and metabolism of [(14)C]remofovir was studied in rats and monkeys following intravenous (i.v.) and oral administration (30 mg/kg of body weight). Oral absorption and bioavailability were 29.7 and 5.42% in rats and 65.6 and 19.4% in monkeys, respectively. Following i.v. administration, the elimination half-life for remofovir was 0.7 h in both rats and monkeys. Total body clearance was 5.85 liters/h/kg in rats and 2.60 liters/h/kg in monkeys; apparent volume of distribution was 5.99 liters/kg in rats and 2.70 liters/kg in monkeys. Following oral administration, remofovir was extensively converted to 9-(2-phosphonylmethoxyethyl)adenine (PMEA) and other metabolites in both species. In rats, excretion of total radioactivity in urine accounted for 61.8% of the i.v. dose and 12.9% of the oral dose, while in monkeys it accounted for 43.3% of the i.v. dose and 34.9% of the oral dose. Following i.v. dosing of [(14)C]remofovir, fecal excretion of radioactivity accounted for 37.5% of the dose in rats and 17.4% of the dose in monkeys, indicating significant biliary excretion of the drug in animals. PMEA and metabolite A were the major urinary metabolites in both species after i.v. and oral administration of remofovir.     

The disposition and urinary metabolism of 14C-labelled FCE 22891, a pro-drug of FCE 22101, in animals

[2-14C]FCE 22891 was given orally and intravenously to the rat, orally to the dog and monkey. Radioactivity was eliminated by both the renal and faecal route after oral administration, but mainly in the urine after the iv route in the rat. Radioactivity as expired 14CO2 was detected in the rat and accounted for less than 1% of the dose after iv and 3.2% after oral dosage within 72 h. After oral FCE 22891 labelled by 14C in the acetoxymethyl moiety, radioactivity recovered as expired 14CO2 accounted for over 55% of the dose at 72 h in the rat. No FCE 22891 was detected in plasma, whereas consistent amounts of FCE 22101 were detected. The metabolism was studied by radio-HPLC in the urine of the animals treated with [2-14C]FCE 22891. No unchanged drug was detected at any time interval. FCE 22101 was the main urinary metabolite with the exception of the dog and accounted for about one-half of the radioactivity excreted in 0-24 h urine. Significant amounts of metabolite P1, an open beta-lactam ring derivative obtained by action of dehydropeptidase, were found in the urine of rat and monkey but not in the dog. The remaining urinary radioactivity was due to other metabolites, named P, X and LP, which might originate from P1, as stability of P1 is pH-dependent.     

Steady-state disposition of the nonpeptidic protease inhibitor tipranavir when coadministered with ritonavir

The pharmacokinetic and metabolite profiles of the antiretroviral agent tipranavir (TPV), administered with ritonavir (RTV), in nine healthy male volunteers were characterized. Subjects received 500-mg TPV capsules with 200-mg RTV capsules twice daily for 6 days. They then received a single oral dose of 551 mg of TPV containing 90 microCi of [(14)C]TPV with 200 mg of RTV on day 7, followed by twice-daily doses of unlabeled 500-mg TPV with 200 mg of RTV for up to 20 days. Blood, urine, and feces were collected for mass balance and metabolite profiling. Metabolite profiling and identification was performed using a flow scintillation analyzer in conjunction with liquid chromatography-tandem mass spectrometry. The median recovery of radioactivity was 87.1%, with 82.3% of the total recovered radioactivity excreted in the feces and less than 5% recovered from urine. Most radioactivity was excreted within 24 to 96 h after the dose of [(14)C]TPV. Radioactivity in blood was associated primarily with plasma rather than red blood cells. Unchanged TPV accounted for 98.4 to 99.7% of plasma radioactivity. Similarly, the most common form of radioactivity excreted in feces was unchanged TPV, accounting for a mean of 79.9% of fecal radioactivity. The most abundant metabolite in feces was a hydroxyl metabolite, H-1, which accounted for 4.9% of fecal radioactivity. TPV glucuronide metabolite H-3 was the most abundant of the drug-related components in urine, corresponding to 11% of urine radioactivity. In conclusion, after the coadministration of TPV and RTV, unchanged TPV represented the primary form of circulating and excreted TPV and the primary extraction route was via the feces.     

Pharmacokinetic evaluation of UK-49,858, a metabolically stable triazole antifungal drug, in animals and humans.

The pharmacokinetic profile of UK-49,858 (fluconazole), a novel triazole antifungal agent which is being developed for oral and intravenous use, was determined in mice, rats, dogs, and humans. Comparative data following oral and intravenous administration showed that bioavailability was essentially complete in all four species. Peak concentrations in plasma of drug normalized to a 1-mg/kg dose level following oral administration, were relatively high: 0.7, 0.6, 1.1, and 1.4 micrograms/ml in mice, rats, dogs, and humans, respectively. The volumes of distribution ranged between 1.1 liter/kg in mice and 0.7 liter/kg in humans, which are approximate to the values for total body water. Whole body autoradiography studies in mice following intravenous administration of [14C]UK-49,858 demonstrated that the drug was evenly distributed throughout the tissues, including the central nervous system and the gastrointestinal tract. Plasma protein binding was low (11 to 12%) in all species. Marked species differences were observed in elimination half-lives, with mean values of 4.8, 4.0, 14, and 22 h in mice, rats, dogs, and humans, respectively. The major route of elimination of the drug was renal clearance, with about 70% of the dose being excreted unchanged in the urine in each species. Studies with [14C]UK-49,858 on metabolism and excretion (intravenous and oral) in mice and dogs showed that about 90% of the dose was recovered as unchanged drug in urine and feces, confirming the metabolic stability of the drug. This pharmacokinetic profile is markedly different from that of imidazole antifungal drugs and undoubtedly contributes to the excellent efficacy of UK-49,858 in vivo.     

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.     

Single- and Multiple-Dose Pharmacokinetics of Reduced Metabolite (MDL 74,156) following Oral Administration of Dolasetron Mesylate to Normal Male Subjects

Dolasetron, a 5-hydroxytryptamine(3) receptor antagonist, is under investigation for prevention of nausea and vomiting due to chemotherapy. The keto-reduced metabolite of dolasetron has been identified in human plasma and is likely responsible for the antiemetic activity. This study evaluated single and multiple dose pharmacokinetics of the reduced metabolite following oral administration of dolasetron mesylate in healthy male subjects. Five groups (six active/two placebo each) of subjects received either oral doses of dolasetron mesylate ranging from 25 to 200 mg or placebo on day 1 and every 12 h on days 2 through 9. Because plasma dolasetron concentrations were low and sporadic, pharmacokinetics of the parent compound could not be determined. The reduced metabolite appeared rapidly in the plasma and reached a maximal plasma concentration in about 1 h. The maximal plasma concentrations and areas under plasma concentration--time curves were proportional to the dose. The mean apparent oral clearance ranged from 9.89 to 23.10 ml min(minus sign1) kg(minus sign1). The half-life ranged from 5.20 to 10.80 h. Mean renal clearance and fraction of dose excreted in urine were 0.97 to 3.97 ml min(minus sign1) kg(minus sign1) and 7.47 to 31.9%, respectively. The pharmacokinetics of reduced metabolite appears to be dose independent after single and multiple dosing.     

Disposition of moxalactam and N-methyltetrazolethiol in rats and monkeys.

The disposition of moxalactam (MOX) and N-methyltetrazolethiol (NMTT) in rats and monkeys after intravenous injection was investigated, focusing on the in vivo liberation of NMTT, by using [NMTT-14C]MOX and [14C]NMTT. After [NMTT-14C]MOX injection, MOX levels in plasma quickly became high in both rats and monkeys and then declined, with half-lives at the beta phase of 18.8 and 67.1 min, respectively. The levels of NMTT liberated from MOX were much lower than those of MOX, but the apparent elimination was significantly slow. The levels of MOX and NMTT in rat liver were almost comparable but lower than those in plasma. With [14C]NMTT administration, the level of NMTT in plasma declined, with half-lives at the beta phase of 21.5 min in rats and 54.0 min in monkeys. After [NMTT-14C]MOX injection, most of the radioactivity was excreted in urine as MOX, with 11% of the dose in rats and 8% of the dose in monkeys eliminated as NMTT until 24 h. Total biliary excretion was 26% of the injected radioactivity in rats, and most of it was due to MOX. In one monkey, the total biliary excretion was only 0.2% of the injected radioactivity. With [14C]NMTT administration, most radioactivity was excreted in the urine as unchanged NMTT in both animals. Oral administration in rats showed that part of the biliary-excreted MOX was degraded to NMTT in the intestine and then absorbed. Repeated administration of [NMTT-14C]MOX to rats did not change the levels of MOX and NMTT in plasma or liver nor did it change the excretion profiles. Thus, accumulation of MOX and NMTT did not occur.     

Pharmacokinetics of fosmidomycin, a new phosphonic acid antibiotic.

The pharmacokinetics of fosmidomycin was investigated in animals and humans after parenteral and oral dosing. In dogs the serum concentration was 54.8 microgram/ml at 0.25 h after an intravenous dose of 20 mg/kg, and the half-life was 1.14 h. Peak concentration was 41.4 microgram/ml after an intramuscular dose of 20 mg/kg and 16.6 microgram/ml after an oral dose of 40 mg/kg. In volunteers, the serum concentrations 0.25 h after dosing was 157 microgram/ml after an intravenous dose of 30 mg/kg, 12.3 microgram/ml after an intramuscular dose of 7.5 mg/kg, and 2.45 microgram/ml after an oral dose of 500 mg. More than 90% of the given dose was excreted in the 24-h urine in rats and dogs after parenteral dosing with 20 mg/kg. The 24-h urinary recovery was 45.8% of the given dose in rats after oral dosing with 100 mg/kg and 37.8% in dogs after oral dosing with 40 mg/kg. In volunteers 85.5% of the intravenous dose (30 mg/kg), 66.4% of the intramuscular dose (7.5 mg/kg), and 26.0% of the oral dose (500 mg) were excreted unchanged in the 24-h urine. In the multiple-dose study, there was no accumulation of fosmidomycin in the serum even after 21 consecutive intramuscular dosings of 1 g every 6 h or 29 consecutive 0.5-h drip infusions of 2 g every 6 h. Biliary excretion was extremely low in rats. Fosmidomycin was well distributed to the tissues of rats after parenteral and oral dosing. The lymph concentrations in dogs were nearly the same as serum concentrations. Serum protein binding was low (4% or less) to mouse, rat, dog, and human serum.     

In vitro and in vivo disposition and metabolism of 3'-deoxy-2',3'-didehydrothymidine.

The disposition and metabolic fate of 3'-deoxy-2',3'-didehydrothymidine (D4T) were evaluated both in isolated hepatocytes and in nonhuman primates. Rapid formation of thymine and beta-aminoisobutyric acid (BAIBA) occurred following incubation of hepatocytes with 10 microM [5(-3)H]D4T. Substantial levels of tritiated water were also detected. Exposure of cells to D4T in the presence of either 1 mM thymine or 10 microM benzyloxybenzyluracil, an inhibitor of dihydropyrimidine dehydrogenase, decreased intracellular BAIBA levels by approximately 89 and 63%, respectively. Concurrently, [3H]thymine levels increased two- to fivefold. These results are consistent with D4T being cleaved to thymine, which is then degraded to BAIBA. A similar metabolic disposition was observed in monkeys following administration of 25 mg of [5(-3)H]D4T per kg of body weight. BAIBA, thymine, and tritiated water were identified in plasma and urine. Approximately 50% of the administered dose was recovered in urine within 24 h, with the majority of the radioactivity representing unchanged drug. After administration intravenously or orally of 25 mg of [4(-14)C]D4T per kg of body weight to monkeys, a novel metabolite, designated X, in addition to unchanged D4T, thymine, and BAIBA, was also detected. The sum of the three metabolites and unchanged drug accounted for virtually all of the radioactivity in plasma and urine. Thymine and X exhibited kinetic profiles similar to that of D4T, with plasma elimination half-life of 2 to 3 h, whereas BAIBA levels remained constant for extended periods and declined slowly; this metabolite could be detected 24 h after intravenous drug administration. Mean oral bioavailability of D4T was high at approximately 70%. As observed in the [5(-3)H]D4T study performed in monkeys, approximately half of the administered [4(-14)C]D4T was recovered unchanged. The remainder was not recovered in urine or feces collected up to 30 days after drug administration. These data suggest that D4T metabolites are further metabolized by salvage pathways and/or converted to biological macromolecules.     

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.