Absorption and bioavailability of captopril in mice and rats after administration by gavage and in the diet.

The absorption of captopril (I), a new antihypertensive agent, was studied in mice and rats at doses (50 and 1350 mg/kg) administered in the diet in chronic toxicological studies. 3H- or 35S-Labeled I was administered by gavage and in the diet to male and female animals in a two-way crossover study. Animals received daily doses of nonradiolabeled I in the diet for 25 days, except on Days 15 and 22 when radiolabeled I was administered either by gavage or in the diet. Absorption of the total radioactivity in 2-month-old mice averaged 49 and 48%, respectively, of the 50- and 1350-mg/kg doses given in the diet and 57 and 65%, respectively, of the doses given by gavage. The bioavailability of I in 2-month-old mice averaged 48 and 39% (diet) and 44 and 59% (gavage) of the 50- and 1350-mg/kg doses, respectively. In 2-month-old rats, absorption of the total radioactivity averaged 41% of the 50-mg/kg dose given in the diet. In 2- and 15-month-old rats, minimum absorption of the 1350-mg/kg dose averaged 36 and 45% (diet) and 51 and 71% (gavage), respectively; the minimum bioavailability averaged 20 and 29% (diet) and 39 and 44% (gavage), respectively. These studies demonstrate adequate absorption and bioavailability of I over a wide range of doses from the drug-diet mixtures and by young and old animals and also illustrate a useful experimental design for the estimation of relative oral absorption of a drug administered continuously in the diet over several days.

Metabolism of captopril-L-cysteine, a captopril metabolite, in rats and dogs.

The metabolism of [14C]captopril-L-cysteine was studied in spontaneously hypertensive rats and pure-bred beagles after a single i.v. dose (4 mg/kg). During the first 24 h, concn. of total radioactivity in blood were similar in both species. Captopril was found in small amounts in the blood of both species. In rats, captopril, bound covalently but reversibly to plasma proteins (CP-PR), was the major component in blood (70%), whereas captopril-L-cysteine was a minor component (23%) of the total radioactivity. In dog blood, CP-PR constituted a smaller fraction (45%) of the total radioactivity than in the rat and captopril-L-cysteine was the major component (53%). In 72 h, 89-91% of the dose was excreted in the urine of rats and dogs. Captopril-L-cysteine accounted for 7% (rat) and 68% (dog) of the radioactivity in urine; captopril accounted for 75% (rat) and 7% (dog). Other metabolites were present in the urine of both species. The greater net conversion of captopril-L-cysteine to CP-PR and to captopril in rats helps explain why captopril-L-cysteine is excreted in urine as a major metabolite of captopril in dogs but only a minor one in rats.

Alteration of Acrylonitrile-Methylacrylate-Butadiene Terpolymer by Nocardia rhodochrous and Penicillium notatum.

[C]Barex-210, a terpolymer of acrylonitrile, methylacrylate, and butadiene, was tested for bioconversion. Powdered samples of polymer, each specifically C labeled at different carbon atoms of the polymer, were incubated with either Nocardia rhodochrous or Penicillium notatum in an enriched growth medium for various periods of time. After 6 months of incubation, the C-labeled polymer was transformed from a high-molecular-weight material completely soluble in dimethyl formamide (DMF) into both a lower-molecular-weight form still soluble in DMF and a second form that was no longer soluble in DMF. The amount of C-labeled carbon atoms converted into DMF-insoluble material was 8% of the backbone carbon-carbon atoms and 12% of the side-chain nitrile and acrylate atoms from the acrylonitrile-methylacrylate copolymer and 60% of the elastomer (acrylonitrile-butadiene copolymer) atoms. Metabolism of the polymer was not established from measurements of metabolic CO(2). Evolution of CO(2) amounted to only 0.3, 0.6, 1.8, and 3.3% of these four fractions, respectively. Although the transformation of high-molecular-weight polymer into DMF-insoluble material was rapid in the early stages of microbial growth, the accompanying CO(2) evolution was much slower. Further evidence of polymer alteration was indicated by the infrared spectrum of the insoluble material, which showed a disappearance of the nitrile and methylacrylate peaks.

Metabolism of alpha-methylfluorene-2-acetic acid (cicloprofen): isolation and identification of metabolites from rat urine.

1. Four metabolites of alpha-methylfluorene-2-acetic acid (cicloprofen) have been isolated from rat urine and identified as the 7-hydroxy, 9-hydroxy, 7,9-dihydroxy and 9-hydroxy-9-methoxy derivatives of cicloprofen. 2. 7-Hydroxy cicloprofen was the major metabolite, contributing 47% of the total radioactivity excreted in rat urine. The other three metabolites each contributed approx. 10% of the radioactivity in urine. There was little unchanged drug excreted in urine (2-6%); at least three other minor metabolites have not been identified. 3. A metabolic pathway for the formation of the 9-hydroxy-9-methoxy metabolite of cicloprofen is proposed.

Metabolism of p-(cyclopropylcarbonyl)phenylacetic acid (SQ 20,650). Species Differences.

The metabolism of p-(cyclopropylcarbonyl)phenyl[14C]acetic acid (I-14C), a nonsteroidal anti-inflammatory agent, has been studied in rats, dogs, and monkeys. Animals were given single intravenous or oral doses of 5 and 50 mg of I-14C/kg. In all cases, 72-88% of the administered dose was excreted in urine, with most of the radioactivity appearing within 24 hr after dosing; less than 11% was found in feces. The half-life (t1/2) of radioactivity in monkey or dog plasma was 1 and 5 hr. respectively, after the oral or intravenous administration of a 5-mg dose of I-14C per kg. At 50 mg/kg, these half-lives increased to 3.5 and 7.7 hr. respectively. More than 90% of the radioactivity in plasma of both species was associated with unchanged drug. Species differences exist in the biotransformation of I. Rat urine contained 93-97% I; 2-6% (alpha-cyclopropyl-alpha-hydroxy-p-tolyl)acetic acid (II); and approximately 1% as conjugates. Monkey urine contained I-glucuronide (88%) and unconjugated II (7-10%). In the dog, I-taurine accounted for 27% of the radioactivity found in urine; II and its taurine conjugate accounted for 20 and 30%, respectively; a small quantity of II-glycine (3%) was also detected. There are three minor metabolites that have not been identified. Metabolite II isolated from dog urine was shown to be dextrorotatory.

Stereospecific inversion of l-alpha-methylfluorene-2-acetic acid to its d-enantiomer in the dog.

1. After administration of dl-alpha-methylfluorene-2-acetic acid to dogs, the optical rotation of the drug in blood increased with time. Of the total drug in blood, the d-enantiomer increased from 61 to 80% between 3 and 24 h after administration; by 384 h it was 100%. 2. Both l- and d-enantiomers had plasma half-lives and excretion characteristics similar to those of the dl-racemic mixture, indicating that the increase in the proportion of the d-enantiomer was not due to more rapid excretion of the l-enantiomer. 3. Studies of optical rotation and circular dichroism demonstrated that the l-enantiomer was converted to the d-enantiomer in the blood of the dog, but the d-enantiomer remained unchanged. After administration of the l-enantiomer, the d-enantiomer increased from 26 to 71% of the total drug in blood between 0-3 and 2 days after administration; 14 days after dosing, almost all of the drug was present as the d-enantiomer. 4. Isomerization of l-alpha-methylfluorene-2-acetic acid to its d-enantiomer also occurs in rat, monkey and man.

Metabolism of a benzothiazine compound (SQ 11,579) by the intact rat, isolated perfused rat liver, and rat-liver microsomes.

1. The metabolic dispositions of a benzothiazine compound (SQ 11,579) by the intact rat, isolated perfused rat liver, and rat-liver microsomes have been investigated, and the results compared. 2. The drug was well absorbed after oral administration to rats and was widely distributed in all tissues, which, with the exception of brain, had higher concentrations of the drug, its metabolites, or both, than did plasma. 3. Metabolism by rat-liver microsomes included N-oxidation, N-demethylation, S-oxidation and aryl hydroxylation. Metabolites hydroxylated in the aromatic ring were excreted only in bile, both by the isolated perfused rat livers and by anaesthetized bile-duct-cannulated rats. 4. Liver perfusion of the benzothiazine or its monodesmethyl analogue (V) resulted in temporary cessation of the flow of perfusate through the organ. The benzothiazine sulphoxide (IV) had only a slight effect on the flow of liver perfusate, but IV followed by I caused the flow of perfusate to cease.

Inversion of optical configuration of alpha-methylfluorene-2-acetic acid (cicloprofen) in rats and monkeys.

A simple and sensitive radiometric method to determine the individual enantiomers of cicloprofen has been developed. 14C-Cicloprofen was converted to its L-leucine diastereoisomers, which were separated by thin-layer chromatography and quantified by measuring the radioactivity in the area corresponding to each individual diastereoisomer. This technique has also been used to measure the enantiomers of unlabeled cicloprofen by condensing with 14C-labeled L-leucine. By using the radiometric method, a unique biotransformation process, the inversion of the (-)-enantiomer of alpha-methylfluorene-2-acetic acid to its (+)-enantiomer, has been demonstrated in the rat and monkey. The rate of (-)- to (+)-inversion was found to be faster in the rat than in the monkey. After single or repeated oral adminstration of the racemic modification or the (-)-enantiomer of cicloprofen to both species, the ratio of (+)- to (-)-enantiomers of cicloprofen in plasma, urine, or bile increased with time. At 5, 22, and 48 hr after oral administration of a single 50-mg/kg dose of the (-)-enantiomer, 14C-cicloprofen in rat plasma contained 20, 50, and 79%, respectively, of the (+)-enantiomer. After receiving the same dose of (-)-enantiomer, monkey plasma contained 16.5% and 32% of (+)-enantiomer at 8 and 24 hr, respectively. After oral administration of a single 50-mg/kg dose of the (+)-enantiomer of 14C-cicloprofen to rats and monkeys, the percentage of (-)-enantiomer in plasma varied from 2 to 15%. Since the administered (+)-enantiomer contained 4% of (-)-enantiomer and the (+)-enantiomer was excreted at a faster rate than its (-)-antipode by rats or monkeys, it is not known whether an occasional small percentage increase of (-)-enantiomer in plasma resulted from the (+)-to-(-) inversion, or from faster elimination of the (+)-enantiomer. Nevertheless, if (+)-to-(-) inversion does occur in these two species, the rate is much slower than for the (-)-to-(+) inversion.

Metabolism of the (+)-, (+/-)-, and (-)-enantiomers of alpha-methylfluorene-2-acetic acid (cicloprofen) in rats.

1. After oral or intraperitoneal administration of (+/-)-[14C]cicloprofen to rats, the peak plasma concentrations of radioactivity and the areas under the plasma concentration/time curves did not increase proportionally with dose; total urinary and faecal excretions of radioactivity did increase with dose, suggesting saturation of plasma protein binding of drug and faster elimination of unbound drug at higher doses. 2. [14C]Cicloprofen and its metabolites were eliminated mainly via biliary excretion. Ratios of faecal to urinary excretion ranged from 2 to 3 and depended on dose administered. 3. Rats with cannulated bile ducts excreted the drug almost exclusively in bile, whereas intact rats excreted up to 32% of the dose in urine in 6 days, suggesting that [14C]cicloprofen or its metabolites or both undergo extensive enterohepatic recirculation in the rats. 4. The major metabolites of [14C]cicloprofen excreted in urine or bile were the 7-hydroxy, 9-hydroxy-, 7,9-dihydroxy-, and 9-hydroxy-9-methoxy-derivatives and their glucuronide or sulphate conjugates. 5. The (+)-enantiomer of [14C]cicloprofen was hydroxylated and excreted by rats at a faster rate than its (-)-antipode; no qualitative stereoselective metabolism of the individual enantiomers of [14C]cicloprofen was observed.

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.

Intestinal absorption of captopril and two thioester analogs in rats and dogs.

The objectives of this study were (i) to determine whether the reduced absorption of captopril from the colon of humans also occurs in rats and (ii), after confirmation of the relevance of a new rat model, to evaluate the intestinal absorption of captopril and several of its analogs. A model was developed and validated in which specific sites within the GI tract of rats were surgically implanted with a cannula such that animals could be dosed while conscious and unrestrained. The absorption of captopril after administration into the lower GI tract of rats was significantly reduced relative to the upper GI tract, which was consistent with results reported previously in humans. In rats, the absorption of the S-benzoyl thioester prodrug of captopril (SQ-25868) from the lower GI tract was substantially greater than that of captopril. However, the absorption of the S-benzoyl thioester prodrug of 4-phenyl thio-captopril (SQ-26991) from the lower GI tract was only marginally better than that of captopril. In additional studies in dogs, a 12h controlled-release formulation of SQ-25868 provided sustained blood levels of captopril while maintaining acceptable bioavailability (> 80%). Two approaches were tried, without success, to stabilize captopril in vivo: (i) complexation with zinc (SQ-26284) and (ii) use of ascorbic-acid-buffered (pH 3.5) vehicle. The zinc complex might have failed because it has very low solubility, whereas the pH-3.5-buffered vehicle was quickly neutralized within the colonic lumen in rats, and did not stabilize captopril against oxidation. Rapid neutralization might explain why the colonic bioavailability of captopril was not substantially increased when this pH-3.5-buffered vehicle was tried in humans.