The disposition of [14C]iprindole in man, dog, miniature swine, rhesus monkey and rat.

1. Absorption of a single oral dose of [14C]iprindole was rapid in rats, rhesus monkeys, miniature swine, dogs and human volunteers. In all species except the rat, most of the radioactivity in the blood resided in the plasma. Small amounts of unchanged iprindole were detected in the plasma of rats and rhesus monkeys but not in man and miniature swine. 2. Radioactivity was excreted mainly in the urine of man, miniature swine and rhesus monkey, but in the faeces of rat and dog. 3. Urinary radioactivity was associated with basic (free and conjugated), acidic and highly polar, water soluble metabolites. At least 20 metabolites as well as small amounts of unchanged drug were detected in the basic fractions of each species' urine. 4. Many of these metabolites were common to all species; however, qualitative as well as quantitative differences were apparent. Mass-spectrometric analysis of several metabolites indicated N-demethylation and oxidation of the alicylic ring or a combination of both pathways.     

Metabolism of the anti-psoriatic agent 5-methoxypsoralen in humans: comparison with rat and dog.

1. Single oral doses of 14C-5-methoxypsoralen (5-MOP) to human subjects (50 mg), rats (1 mg/kg) and dogs (1 mg/kg) were fairly well absorbed but subjected to extensive first-pass metabolism, at least in rat and human. Means of 62, 51 and 40% dose in urine and 31, 38 and 48% dose in faeces, were excreted by humans (during 5 days), rats (3 days) and dogs (1 day), respectively. In dogs, faecal 14C was probably derived, in part, from biliary excreted material. 2. Total 14C in human plasma reached peak concentrations after 2 h (mean 235 ng 5-MOP equivalent/ml) and declined relatively slowly, to about 60% of this value within 24 h. Unchanged 5-MOP was not detected in plasma using h.p.l.c. (< 5 ng/ml). 3. Tissue concentrations of 14C were generally greater in dogs than rats and reached peak levels at 1 h in dogs but at 24 h in rats. Apart from liver and bile, dog tissue 14C concentrations were lower than those in the corresponding plasma, whereas in rat they were lower only until the time of peak concentrations, after which they were generally greater. 4. 5-MOP was extensively metabolized in all three species. The major 14C-components in human and dog urine were glucuronic acid conjugates, mainly of an arylacetic acid and arylalcohols, resulting from initial oxidative metabolism of the furan ring of 5-MOP. In rat, these metabolites were excreted mainly unconjugated. An unusual metabolite was formed by reduction of the lactone moiety of 5-MOP, probably by the gut flora, giving rise to an arylpropionic acid, excreted as a glucuronic acid conjugate in the urine of all three species. 5. Unchanged drug was a very minor component of human and rat plasma, but a major component of dog plasma. In all three species, circulating 14C-metabolites were similar to those in the urine but were present mainly unconjugated. On the basis of these data, the metabolic fate of 5-MOP in humans was more similar to that in dog than to that in rat, although humans appeared to metabolize 5-MOP more rapidly than did dog.     

Metabolism of the anti-psoriatic agent 5-methoxypsoralen in humans: comparison with rat and dog

1. Single oral doses of ₁₄C-5-methoxypsoralen (5-MOP) to human subjects (50 mg), rats (1 mg/kg) and dogs (1 mg/kg) were fairly well absorbed but subjected to extensive first-pass metabolism, at least in rat and human. Means of 62, 51 and 40% dose in urine and 31, 38 and 48% dose in faeces, were excreted by humans (during 5 days), rats (3 days) and dogs (1 day), respectively. In dogs, faecal ₁₄C was probably derived, in part, from biliary excreted material.

2. Total ₁₄C in human plasma reached peak concentrations after 2 h (mean 235 ng 5-MOP equivalent/ml) and declined relatively slowly, to about 60% of this value within 24 h. Unchanged 5-MOP was not detected in plasma using h.p.l.c. (< 5 ng/ml).

3. Tissue concentrations of ₁₄C were generally greater in dogs than rats and reached peak levels at 1 h in dogs but at 24 h in rats. Apart from liver and bile, dog tissue ₁₄C concentrations were lower than those in the corresponding plasma, whereas in rat they were lower only until the time of peak concentrations, after which they were generally greater.

4. 5-MOP was extensively metabolized in all three species. The major ₁₄C-components in human and dog urine were glucuronic acid conjugates, mainly of an arylacetic acid and arylalcohols, resulting from initial oxidative metabolism of the furan ring of 5-MOP. In rat, these metabolites were excreted mainly unconjugated. An unusual metabolite was formed by reduction of the lactone moiety of 5-MOP, probably by the gut flora, giving rise to an arylpropionic acid, excreted as a glucuronic acid conjugate in the urine of all three species.

5. Unchanged drug was a very minor component of human and rat plasma, but a major component of dog plasma. In all three species, circulating ₁₄C-metabolites were similar to those in the urine but were present mainly unconjugated. On the basis of these data, the metabolic fate of 5-MOP in humans was more similar to that in dog than to that in rat, although humans appeared to metabolize 5-MOP more rapidly than did dog.     

Disposition and biotransformation of quinpirole, a new D-2 dopamine agonist antihypertensive agent, in mice, rats, dogs, and monkeys

The disposition and metabolism of quinpirole were studied in rats, mice, dogs, and monkeys. A single 2 mg/kg dose of 14C-quinpirole was administered orally to rats, mice, and monkeys. Dogs were given a single 0.2 mg/kg iv dose of 14C-quinpirole. Of the dose administered, 75-96% was recovered in the urine within 72 hr, with the majority being excreted during the first 24 hr. Peak plasma concentrations of radioactivity and quinpirole were coincident and were observed within 0.25 hr in rodents and at 2 hr in monkeys. Unchanged quinpirole accounted for 0.9%, 36%, and 69% respectively. Biotransformation of quinpirole was compared by quantitating the urinary metabolites by HPLC. The percentage of the radioactivity in urine representing unchanged drug was determined for each species: monkey (3%), dog (13%), mouse (40%), and rat (57%). The majority of 14C-quinpirole was shown to be biotransformed in rats, mice, and monkeys through common metabolic pathways but to various extents. Most metabolites resulted from structural alterations (N-dealkylation, lactam formation, omega and omega-1 hydroxylation) that centered around the piperidine ring portion of the molecule. These metabolites were less important in dogs. The major metabolic pathway in dogs involved hydroxylation of a methylene carbon adjacent to the pyrazole nucleus of quinpirole followed by O-glucuronidation. Evidence of metabolism of the pyrazole moiety was found in the isolation of an N-glucuronide conjugate of quinpirole from monkey urine.     

Pharmacokinetics, metabolism, and disposition of 6-chloro-2,3,4,5-tetrahydro-3-methyl-1H-3-benzazepine (SK&F 86466) in rats and dogs

The pharmacokinetics and metabolism of 6-chloro-2,3,4,5-tetrahydro-3-methyl-1H-3-benzazepine (SK&F 86466) have been studied in rats and dogs. Using radiolabeled SK&F 86466, it was shown that the compound was completely absorbed from the gastrointestinal tract following oral administration. Most of the administered radioactivity (approximately 80%) was excreted in urine with the remainder excreted in feces via the bile. Very little of the parent compound was excreted unchanged in the urine. The major urinary metabolite, accounting for about 55% of the dose in rat and 35% in dog, was the N-oxide. N-Demethylation also occurs in both species, and in the rat approximately 20% of the dose is metabolized by this route. The plasma concentration vs. time curves following iv administration were analyzed using a two-compartment open model. The distribution phase half-life was 0.24 hr in the rat and 0.37 hr in the dog. In both species the terminal half-life was approximately 2 hr. The volume of distribution at steady state in the rat was 12.1 liters/kg and in the dog was 8.2 liters/kg. About 55% of the drug in plasma was bound to protein in both species so that the volume of distribution of the free drug was 27 liters/kg in the rat and 19 liters/kg in the dog. The clearance of SK&F 86466 from blood was very high in both the dog (56 ml/min/kg) and the rat (191 ml/min/kg). Since less than 1% of the compound was excreted unchanged in urine, the clearance was almost entirely metabolic.(ABSTRACT TRUNCATED AT 250 WORDS)     

The absorption, distribution, metabolism and excretion of rofecoxib, a potent and selective cyclooxygenase-2 inhibitor, in rats and dogs.

Absorption, distribution, metabolism, and excretion studies were conducted in rats and dogs with rofecoxib (VIOXX, MK-0966), a potent and highly selective inhibitor of cyclooxygenase-2 (COX-2). In rats, the nonexponential decay during the terminal phase (4- to 10-h time interval) of rofecoxib plasma concentration versus time curves after i.v. or oral administration of [(14)C]rofecoxib precluded accurate determinations of half-life, AUC(0-infinity) (area under the plasma concentration versus time curve extrapolated to infinity), and hence, bioavailability. After i.v. administration of [(14)C]rofecoxib to dogs, plasma clearance, volume of distribution at steady state, and elimination half-life values of rofecoxib were 3.6 ml/min/kg, 1.0 l/kg, and 2.6 h, respectively. Oral absorption (5 mg/kg) was rapid in both species with C(max) occurring by 0.5 h (rats) and 1.5 h (dogs). Bioavailability in dogs was 26%. Systemic exposure increased with increasing dosage in rats and dogs after i.v. (1, 2, and 4 mg/kg), or oral (2, 5, and 10 mg/kg) administration, except in rats where no additional increase was observed between the 5 and 10 mg/kg doses. Radioactivity distributed rapidly to tissues, with the highest concentrations of the i.v. dose observed in most tissues by 5 min and by 30 min in liver, skin, fat, prostate, and bladder. Excretion occurred primarily by the biliary route in rats and dogs, except after i.v. administration of [(14)C]rofecoxib to dogs, where excretion was divided between biliary and renal routes. Metabolism of rofecoxib was extensive. 5-Hydroxyrofecoxib-O-beta-D-glucuronide was the major metabolite excreted by rats in urine and bile. 5-Hydroxyrofecoxib, rofecoxib-3',4'-dihydrodiol, and 4'-hydroxyrofecoxib sulfate were less abundant, whereas cis- and trans-3,4-dihydro-rofecoxib were minor. Major metabolites in dog were 5-hydroxyrofecoxib-O-beta-D-glucuronide (urine), trans-3, 4-dihydro-rofecoxib (urine), and 5-hydroxyrofecoxib (bile).     

The pharmacokinetics and disposition of MK-0524, a Prosglandin D2 Receptor 1 antagonist, in rats, dogs and monkeys

MK-0524 is a potent, selective and orally active Prosglandin D(2) Receptor 1 (DP(1)) antagonist currently under clinical development for the treatment of niacin-induced flushing. Experiments to study the pharmacokinetics, metabolism and excretion of MK-0524 were conducted in rats, dogs and monkeys. MK-0524 displayed linear kinetics and rapid absorption following an oral dose. Following intravenous (i.v.) administration of MK-0524 to rats and dogs (1 and 5 mg/kg), the mean Cl(p) was approximately 2 and approximately 6 ml/min/kg, the T(1/2) was approximately 7 and approximately 13 h and the Vd(ss) was approximately 1 and approximately 5 L/kg, respectively. In monkeys dosed i.v. at 3 mg/kg, the corresponding values were 8 ml/min/kg, 3 h and 1 L/kg, respectively. Following oral dosing of MK-0524 to rats (5, 25 and 100 mg/kg), dogs (5 mg/kg) and monkeys (3 mg/kg), the absorption was rapid with the mean C(max) occurring between 1 and 4 h. Absolute oral bioavailability values in rats, dogs and monkeys were 50, 70 and 8%, respectively. The major circulating metabolite was the acyl glucuronide of MK-0524 (M2), with ratios of glucuronide to the parent aglycone being highest in the monkey followed by dog and rat. In bile duct-cannulated rats and dogs, MK-0524 was eliminated primarily via acyl glucuronidation followed by biliary excretion of the acyl glucuronide, M2, the major drug-related entity in bile.     

The pharmacokinetics and disposition of MK-0524, a Prostaglandin D2 receptor 1 antagonist,in rats,dogs and monkeys

MK-0524 is a potent, selective and orally active Prostaglandin D₂ receptor 1 (DP₁) antagonist currently under clinical development for the treatment of niacin-induced flushing. Experiments to study the pharmacokinetics, metabolism and excretion of MK-0524 were conducted in rats, dogs and monkeys. MK-0524 displayed linear kinetics and rapid absorption following an oral dose. Following intravenous (i.v.) administration of MK-0524 to rats and dogs (1 and 5?mg/kg), the mean Cl_p was ～2 and ～6?ml/min/kg, the T_1/2 was ～7 and ～13?h and the Vd_ss was ～1 and ～5 L/kg, respectively. In monkeys dosed i.v. at 3?mg/kg, the corresponding values were 8?ml/min/kg, 3?h and 1?L/kg, respectively. Following oral dosing of MK-0524 to rats (5, 25 and 100?mg/kg), dogs (5?mg/kg) and monkeys (3?mg/kg), the absorption was rapid with the mean C_max occurring between 1 and 4?h. Absolute oral bioavailability values in rats, dogs and monkeys were 50, 70 and 8%, respectively. The major circulating metabolite was the acyl glucuronide of MK-0524 (M2), with ratios of glucuronide to the parent aglycone being highest in the monkey followed by dog and rat. In bile duct-cannulated rats and dogs, MK-0524 was eliminated primarily via acyl glucuronidation followed by biliary excretion of the acyl glucuronide, M2, the major drug-related entity in bile.     

Metabolism and disposition of sulfinalol in laboratory animals

Peak levels of radioactivity in blood occurred 1.0 hr after oral administration of 3H-sulfinalol hydrochloride to rats, dogs, and monkeys. The plasma decay curve for intact sulfinalol in the dog was biphasic, with apparent first-order half-lives of 0.55 and 6.2 hr. Rats excreted 42.5% of the dose in the urine and 31.8% in the feces after 24 hr. Urinary and fecal recovery were 53.8% and 41.2%, respectively, after 10 days for dogs and 57.8% and 38.0%, respectively, after 9 days for monkeys. Free sulfinalol (11.8% of the dose) was the major component in dog feces with lesser amounts of the sulfide and sulfone metabolites, also in the unconjugated form. All metabolites in dog urine were conjugated with glucuronic acid, with sulfinalol (28.5%) and desmethylsulfinalol (8.5%) representing the major constituents, whereas the sulfone and sulfide metabolites were minor ones. Monkey feces contained primarily unconjugated forms of the desmethyl sulfide metabolite (17.0%) and sulfinalol (7.5%); lesser amounts of desmethylsulfinalol and the sulfone metabolite were present. Desmethylsulfinalol (8.7%) and its sulfate (7.0%) and glucuronide (4.0%) conjugates were the major urinary metabolites in the monkey; sulfinalol (1.4%), its glucuronide conjugate (5.1%), the desmethyl sulfide metabolite (and its sulfate conjugate), and the sulfone metabolite were also present.     

2,4,5,2',4',5'-Hexachlorobiphenyl: distribution, metabolism, and excretion in the dog and the monkey

The tissue distribution, metabolism, and excretion of 2,4,5,2′,4′,5′-hexachlorobiphenyl (2,4,5-HCB) were investigated in beagle dogs and cynomolgus monkeys (Macacca fascicularis). Following a single iv dose of [¹⁴C]2,4,5-HCB (0.6 mg/kg), excreta, blood, and tissues were collected at time intervals ranging from 30 min to 15 days for dogs and 2 hr to 90 days for monkeys. The concentration of 2,4,5-HCB and its metabolites was determined in all samples. Elimination of the parent PCB from the blood of both species was biphasic with a terminal phase elimination rate constant of 0.045 day^?1 for the dog and 0.015 day^?1 for the monkey. By 15 days the dog had excreted 66% of the dose, 63% in the feces, and 3% in the urine. The percentage dose remaining was found largely as parent compound in the adipose tissue (16%), skin (6%), and muscle (2%). By 90 days, the monkey had excreted only 18% of the dose (17% in feces, 1% in urine). Again, the major storage depots for nonexcreted dose were adipose tissue 945%) and skin (5%). In anesthetized dogs, 0.8% of the dose appeared in the bile within 2 hr, while only 0.2% of the dose appeared in the bile of anesthetized monkeys in 2 hr. The monkey excreted a greater percentage of dose as parent compound into the bile than the dog. The data provide evidence that the pharmacokinetic behavior of 2,4,5-HCB in the monkey is similar to that observed in other species. However, the dog is unique from other species in that it can readily eliminate 2,4,5-HCB.     

Disposition of sucrose octa-isobutyrate in rats, dogs and monkeys

The disposition of 200 mg/kg of ¹⁴C-labelled sucrose octa-isobutyrate (¹⁴C-SOIB), a component of sucrose acetate isobutyrate (SAIB), a beverage emulsion stabilizer, was studied in rats, dogs and monkeys. After oral administration of ¹⁴C-SOIB to three rats, 3–15% of the dose was excreted as volatile products, 1–2% appeared in urine and 78–93% was recovered in faeces. In dogs, recoveries of radiolabel in CO₂, urine and faeces were approximately 1%, less than 2% and 77–94%, respectively. Monkeys excreted the majority of the dose in faeces; less than 2% of the administered radioactivity was eliminated in either CO₂ or urine. The biliary excretion of radiolabel from ¹⁴C-SOIB was negligible in rats and monkeys; however, in dogs, 3–10% of the dose was excreted into bile. It was demonstrated by chromatographic analyses of faeces that ¹⁴C-SOIB was more extensively hydrolysed in the gastro-intestinal tract of rats and dogs than in monkeys. The results indicate that after oral administration, rats and dogs absorb SOIB following hydrolysis of the sugar ester in the gut. The proportion of the dose that is absorbed by the rat is oxidized to CO₂. In the dog, little of the absorbed product is oxidized; rather, it is circulated through an enterohepatic pathway. In contrast, in the monkey, SOIB is not detectably hydrolysed in the gut or absorbed. These findings show that there is a species difference in the disposition of SOIB; the most salient findings relate to a difference in the disposition of SOIB in the dog compared with the rat.     

Pharmacokinetic properties of TDP4815 after single intravenous and oral administrations to rat, rabbit, monkey, dog and in vitro drug metabolism

The pharmacokinetics of TDP4815 was evaluated in rats, rabbits, dogs and monkeys. After intravenous administration, TDP4815 achieved C(O) of 3255 ng/ml in rats at 5 mg/kg, 9066 ng/ml in rabbits and 7858 ng/ml in monkeys at 6 mg/kg, and 4457 ng/ml in dogs at 3 mg/kg. The clearance (C(L)) was 3105, 1692, 835 and 640 ml/h/kg in rats, rabbits, monkeys and dogs, respectively. The volume of distribution (V(Z)) was more than 3861 ml/kg in all species, except 1915 ml/kg in monkeys. The oral bioavailability was rabbit >rat> monkey compared at 100 mg/kg, but it was much higher in dogs (>64%) after oral administrations. The calculated intrinsic clearance data suggested that the clearance of dog and human was restricted by binding to the plasma protein, and the clearance of rat and monkey was dependent on both the free fraction of plasma protein binding and the liver blood flow rate. The unbound hepatic intrinsic clearance of monkey was close to its C(L) suggesting that the hepatic clearance was an important excretion in monkeys. The poor oral bioavailability in the monkey may be related to the extensive glucuronidation. The V(Z).kg and C(L).kg in test species showed good correlation with the animal body weights (R(2)=0.87 and 0.96).     

The absorption,distribution and excretion of [14C]lormetazepam in dogs,rabbits, rats and rhesus monkeys

1. Oral doses of [¹⁴C]lormetazepam (0.05–0.25mg/kg) were rapidly and almost completely absorbed by female dogs, rabbits, rats and rhesus monkeys. Elimination of ¹⁴C was rapid and similar after oral or i.v. doses.

2. Rats excreted most of the dose in the faeces (76%), whereas dogs, rabbits and monkeys excreted it in the urine (60, 85 and 80% respectively. The urinary excretion half-lives of ¹⁴C from monkeys (c. 10?h), rabbits (c. 12?h), dogs (c. 14?h) and rats (c. 8?h) paralleled the rate of decline of plasma concn. of ¹⁴C.

3. Biliary excretion of lormetazepam and/or its metabolites occurred in rats (83%), dogs (48%) and possibly to a lesser extent in the other two species. Enterohepatic circulation of ¹⁴C in rat was extensive (47%), but not of long duration, and probably occurred in dog and rabbit.

4. Mean peak plasma concn. of ¹⁴C in dogs, rabbits, rats and monkeys of 190, 29, 42 and 280 ng equiv./ml respectively were reached at 1.5, 1, 0.5 and 1?h. A.U.C. values after oral and i.v. doses were similar in dogs, rats and monkeys. In these species, plasma concn. declined biphasically with t_1/2 values of about 15, 14 and 11?h respectively.

5. Concn. of ¹⁴C in rat tissues, particularly in blood cells, liver, kidneys and gut, were several times greater than those in plasma after single or multiple oral doses. Some accumulation in tissues occurred after multiple doses, presumably partly because of accumulation of ¹⁴C in blood cells.

6. Transplacental transfer of ¹⁴C into foetuses of rats or rabbits was low. In rabbits, maternal: foetal concn. ratios ranged between 9 and 26 : 1 after oral or i.v. doses.

7. The excretion (rats and dogs), or plasma ¹⁴C concn.-time profiles (dogs), were not altered during multiple oral doses for 21 days.     

Metabolic disposition of enciprazine, a non-benzodiazepine anxiolytic drug, in rat, dog and man.

1. The excretion and metabolism of enciprazine, an anxiolytic drug, was examined in rat, dog and man. 2. In rats and dogs that received 14C-enciprazine dihydrochloride orally and by i.v. injection, the drug was well absorbed. Radioactivity was excreted predominantly in the faeces of rats, equally in urine and faeces of dogs, and to a major extent in human urine. 3. Metabolic profiles, which were evaluated in urine and in rat bile, were similar following oral and i.v. dosing to rats and dogs. 4. Unchanged drug was not detected in rat, dog or human excreta. Glucuronide conjugates of 4-hydroxyenciprazine, m-desmethylenciprazine, p-desmethylenciprazine and enciprazine were detected in the excreta of all three species. A glycol metabolite was present only in rat bile and human urine. A metabolite desmethylated in the phenyl ring of the phenylpiperazine moiety also appeared to be present only in human urine. 5. Structural confirmation of the major metabolites in human urine and rat bile was accomplished by h.p.l.c.-mass spectrometry.     

Restoration of shock-suppressed behavior by treatment with (+)-5-methyl-10,11-dihydro-5H-dibenzo[a,d]cyclohepten-5, 10-imine (MK-801), a substance with potent anticonvulsant,central sympathomimetic,and apparent anxiolytic properties

MK-801 was evaluated in rats for “antipunishment” and “anticonflict” activity in two procedures: (1) A conditioned emotional response (CER) test involving the suppression of lever-pressing by unaviodable shock and (2) a simple conflict test in water-deprived animals that were shocked for licking water. The effect of MK-801 in both procedures was qualitatively similar to the benzodiazepines. Lever-pressing in the CER test was increased by MK-801 at doses ranging from 50–400 μg/kg administered orally (p.o.) at either 0.5 or 2 hours prior to testing. The number of shocks received in the “thirsty rat” conflict procedure was increased by MK-801 at doses from 110–1,000 μg/kg p.o., providing the compound was given 2 or more hours before test. MK-801 was without anticonflict activity when administered 1 hour prior to study. In squirrel monkeys trained in a response-contingent conflict paradigm, a specific anticonflict effect for MK-801 (50–400 μ/kg p.o.) was not demonstrable. As assessed by observing the overt behavior of squirrel monkeys, MK-801 at doses greater than 100 μg/kg p.o. caused apparent “taming” or “tranquilization.” Chlordizepoxide and diazepam given, respectively, at doses above 1 and 2 mg/kg p.o. had a similar “taming” action. The benzodiazepines possessed a greater separation between doses producing “taming” and those causing ataxia than did MK-801. The mode of action for the antipunishment effect of MK-801 in rats is not known, but it was found that naloxone (2 or 5 mg/kg SC) antagonized the anticonflict actions of both MK-801 and chlordiazepoxide. In vitro, MK-801 was inactive (IC₅₀ > 2 μM) with respect to competing for binding to rat brain tissue by various radioligands (diazepam, muscimol, apomorphine, spiroperidol, serotonin, LSD, WB-4101, dihydroalprenolol, QNB, and 2-chloroadenosine). An increase in ³H-diazepam binding in vitro in rat brain tissue was detected following acute, but not chronic, treatment in vivo with MK-801.     

Felbamate pharmacokinetics in the rat, rabbit, and dog.

Rats, rabbits, and dogs were given single iv or single and multiple oral doses of felbamate ranging from 1.6-1000 mg/kg. Absorption of oral drug was complete in all species. The mean Cmax increased with dose from 13.9 to 185.9 micrograms/ml in rats, from 19.1 to 161.9 micrograms/ml in rabbits, and from 12.6 to 168.4 micrograms/ml in dogs. The tmax also increased with dose from 1-8 hr in rats, 8-24 hr in rabbits, and 3-7 hr in dogs. The plasma elimination half-life for the drug increased with dose from 2-16.7 hr in rats, 7.2-17.8 hr in rabbits, and 4.1-4.5 hr in dogs. A proportional increase in Cmax with dose was observed in all species up to 300-400 mg/kg doses. A biexponential equation fitted the drug plasma concentration vs. time data well. For multiple oral doses of 50 mg/kg or less, projected and observed steady-state concentrations agreed well. Animals dosed with [14C]felbamate eliminated most of the radioactivity in urine (58-87.7%), less in feces (7-23.7%), with considerable amounts in the bile. In rats, radioactivity was readily distributed into tissues and crossed the placenta and blood-brain barrier, but no accumulation in any tissue was observed. The volume of distribution was 131, 54, and 72% of body weight for rats, rabbits, and dogs, respectively. Binding of drug to rat, rabbit, and dog plasma proteins ranged from 22.4-35.9%. The overall plasma clearance of the drug for rats, rabbits, and dogs was 327, 52, and 108 ml.h-1.kg-1, respectively. Renal clearance of unchanged drug accounted for an estimated 20-35% and hepatic clearance due to metabolism for 65-80% of the overall clearance.     

Metabolism of 14C-estazolam in dogs and humans

14C-Estazolam (2 mg) administered orally to dogs and human subjects was rapidly and completely absorbed with peak plasma levels occurring within one hour. In humans, plasma levels peaked at 103 +/- 18 ng/ml and declined monoexponentially with a half-life of 14 h. The mean concn. of estazolam in dog plasma at 0.5 h was 186 ng/ml. Six metabolites were found in dog plasma at 0.5 and 8 h, whereas only two metabolites were detected in human plasma up to 18 h. Metabolites common to both species were 1-oxo-estazolam (I) and 4-hydroxy-estazolam (IV). Major metabolites in dog and human plasma were free and conjugated 4-hydroxy-estazolam; the concn. were higher in dogs. After five days, 79% and 87% of the administered radioactivity was excreted in dog and human urine, respectively. Faecal excretion accounted for 19% of the dose in dog and 4% in man. Eleven metabolites were found in the 0-72 h urine of dogs and humans; less than 4% dose was excreted unchanged. Four metabolites were identified as: 1-oxo-estazolam (I), 4'-hydroxy-estazolam (II), 4-hydroxy-estazolam (IV) and the benzophenone (VII), as free metabolites and glucuronides. The major metabolite in dog urine was 4-hydroxy-estazolam (20% of the dose), while the predominant metabolite in human urine (17%) has not been identified, but is likely to be a metabolite of 4-hydroxy-estazolam. The metabolism of estazolam is similar in dog and man.     

The uptake and secretion of 2-acetylaminofluorene by the rat and dog prostate

In unanesthetized rats examined 4–140 hr after the ip administration of 1.8 mg/kg of [9-¹⁴C]2-acetylaminofluorene ([¹⁴C]2-AAF), detectable amounts of radioactivity were found in the plasma and in the ventral and dorsolateral lobes of the prostate. Radioactivity was also found in the prostatic fluid collected from anesthetized rats between 25 and 29 hr after doses of 2 mg/kg. When three unanesthetized dogs with surgically prepared fistulas allowing the collection of prostatic fluid were given intraperitoneal doses of 0.16–0.25 mg/kg of [¹⁴C]2-AAF and followed for 6 hr (two dogs) or 166 hr (one dog), there was a relatively rapid rise in the amount of radioactivity in plasma followed by a slow decline and an appearance of radioactivity in the prostatic fluid. Radioactivity was also present in the prostate glands of each of two dogs examined 6 hr after treatment. Thus 2-AAF and/or metabolites were found to enter both the prostate gland and the prostatic secretion of both the rat and dog.     

Disposition of radiolabeled ifetroban in rats, dogs, monkeys, and humans.

Ifetroban is a potent and selective thromboxane receptor antagonist. This study was conducted to characterize the pharmacokinetics, absolute bioavailability, and disposition of ifetroban after i.v. and oral administrations of [14C]ifetroban or [3H]ifetroban in rats (3 mg/kg), dogs (1 mg/kg), monkeys (1 mg/kg), and humans (50 mg). The drug was rapidly absorbed after oral administration, with peak plasma concentrations occurring between 5 and 20 min across species. Plasma terminal elimination half-life was approximately 8 h in rats, approximately 20 h in dogs, approximately 27 h in monkeys, and approximately 22 h in humans. Based on the steady-state volume of distribution, the drug was extensively distributed in tissues. Absolute bioavailability was 25, 35, 23, and 48% in rats, dogs, monkeys, and humans, respectively. Renal excretion was a minor route of elimination in all species, with the majority of the dose being excreted into the feces. After a single oral dose, urinary excretion accounted for 3% of the administered dose in rats and dogs, 14% in monkeys, and 27% in humans, with the remainder excreted in the feces. Extensive biliary excretion was observed in rats with the hydroxylated metabolite at the C-14 position being the major metabolite observed in rat bile. Ifetroban was extensively metabolized after oral administration. Approximately 40 to 50% of the radioactivity in rat and dog plasma was accounted for by parent drug whereas, in humans, approximately 60% of the plasma radioactivity was accounted for by ifetroban acylglucuronide.     

The pharmacokinetics of indecainide in mice, rats, dogs, and monkeys

The pharmacokinetics of indecainide, a new antiarrhythmic agent, were studied in mice, rats, dogs, and monkeys. The drug was well absorbed in all species tested resulting in peak plasma levels of drug within 2 hr. The plasma half-life of indecainide after acute oral administration was 3-5 hr in rats, dogs, and monkeys but considerably shorter in mice. The plasma half-life of indecainide was dose-dependent in dogs and increased slightly with chronic dosing. Peak plasma levels of drug were also dose-dependent in dogs and monkeys. Fecal elimination was the primary route of excretion of the drug in rats and mice after oral dosing. Fifty per cent of the dose was excreted in the bile of rats which was then subject to enterohepatic circulation. Urinary elimination was the predominant excretory route in the dog. Tissue distribution of radioactivity in rats showed that tissues which first encounter the drug have the highest levels of radioactivity. The highest concentrations were found in the stomach, intestine, liver, and kidney, whereas very low levels were observed in the fat and brain. Except for liver and kidney, only very low levels were present after 24 hr.