Studies on absorption, distribution and excretion of 14C labeled pivaloyloxymethyl (+)-(6R,7R)- 7-[(Z)-2-(2-amino-4-thiazolyl)-2-methoxyiminoacetamido]- 3-[(5-methyl-2H-tetrazol-2-yl)methyl]-8-oxo-5-thia- 1-azabicyclo[4.2.0]oct-2-ene-2-carboxylate (14C-T-2588) in rats and mice

Absorption, distribution and excretion of T-2588 were studied in rats and mice using (aminothiazole-2-14C) T-2588 and (pivaloyloxymethyl-14C) T-2588. Results are summarized below. The binding rate of 14C-T-2525, an activated form of 14C-T-2588 in vivo, to serum protein was 90 approximately 100% in rats and mice after an oral administration of (aminothiazole-2-14C) T-2588. Blood levels of radioactivity reached to the highest concentration at 1 hour after an oral administration of (aminothiazole-2-14C) T-2588 to rats, and then gradually diminished. After an oral administration of (aminothiazole-2-14C) T-2588 to rats and mice, the highest radioactivity distribution was found in kidney among all the organs except stomach, intestine and bladder. Radioactivity was widely distributed into other organs such as adrenal, lung, liver, heart and pancreas. But little radioactivity was found in the brain. In new born rats, tissue levels of radioactivity were lower and diminished slower than those of adult rats. After an oral administration of (aminothiazole-2-14C) T-2588 to rats and mice, urinary excretion of radioactivity was about 26% and 35% of the dosed radioactivity in rats and mice, respectively, and fecal excretion was about 76% and 63% of the dosed radioactivity in rats and mice, respectively. Urinary and fecal excretion patterns of radioactivity after multiple oral administration of (aminothiazole-2-14C) T-2588 for 7 days to mice were similar to those after a single administration. This result suggests that T-2588 did not accumulate in the body. After an oral administration of (pivaloyloxymethyl-14C) T-2588 to rats and mice, urinary excretion was both about 8% of the dosed radioactivity, and fecal excretion was both about 6%. Then excretion of 14CO2 into respiratory air was about 55% and 66% of the dosed radioactivity in rats and mice, respectively. Biliary excretion was about 6.5% of the dosed radioactivity after an oral administration of (aminothiazole-2-14C) T-2588 to rats. Small amount of radioactivity was secreted to the milk after intravenous administration of (aminothiazole-2-14C) T-2525 to nursing rats. After an administration of (aminothiazole-2-14C) T-2588 to pregnant mice, radioactivity hardly transferred into the fetus.     

A study on the distribution of T-3262 (tosufloxacin tosilate) in salivary glands of rats using microautoradiography

The distribution of T-3262 (tosufloxacin tosilate) in salivary glands of rats was investigated with frozen-microautoradiography. One and 4 hours after oral administration of 14C-T-3262 at 100 mg/kg to rats submandibular glands, parotid glands and sublingual glands were removed, and a microautoradiogram of each was made. In the submandibular gland and the parotid gland 14C-T-3262 was distributed at high levels throughout the glands taken at 1 and 4 hours after administration, but lower levels than the other glands were found in the sublingual gland at 1 hour. The results of this study suggested that T-3262 penetrates effectively into the saliva, because 14C-T-3262 is distributed well into glandular acinus, striated duct and excretory duct. The microautoradiography was a useful and reliable method for investigating the distribution of antimicrobial agents in salivary glands.     

Study on metabolism of pyridonecarboxylic acid II. Determination of metabolites of (+-)-7-(3-amino-1-pyrrolidinyl)-6-fluoro-1-(2,4-difluorophenyl)- 1,4-dihydro-4-oxo-1,8-naphthyridine-3-carboxylic acid p-toluenesulfonate hydrate (T-3262) in blood, urine, bile, and feces

The fate of (+-)-7-(3-amino-1-pyrrolidinyl)-6-fluoro-1-(2,4-difluorophenyl-1,4- dihyro-4-oxo-1,8-naphthyridine-3-carboxylic acid p-toluenesulfonate hydrate (T-3262) was studied using T-3262 and 14C-T-3262 in various animals. 1. Metabolites in serum and urine were assayed for mouse, rat, rabbit, dog and monkey following oral administration of T-3262. In serum, besides unchanged T-3262 base, T-3262A (N-acetylated) was detected in rat, rabbit and monkey; T-3262B (deamino-hydroxylated) was detected in monkey. In urine, unchanged T-3262 base was excreted mainly. But a few of metabolites (T-3262A, T-3262B, T-3262 glucuronide, T-3262A glucuronide, T-3262B glucuronide, and unknown compound M-1) were detected, and species difference existed in types of metabolites. 2. Metabolites in bile and feces were assayed for mouse and rat following oral administration of T-3262 and 14C-T-3262. Metabolites in bile were similar to the urine, but the volume of T-3262A and T-3262A glucuronide was larger than in urine. In feces, the excreted compounds mainly consisted of unchanged T-3262 base. 3. p-Toluenesulfonic acid, which is the counter acid for T-3262 base, was absorbed following the oral administration of T-3262, and excreted in urine in the unchanged form.     

Absorption, distribution and excretion of 3-(sulfamoyl[14C]methyl)-1,2-benziosoxazole (AD-810) in Rats, Dogs and Monkeys and of AD-810 in Men

Disposition of 3 - (sulfamoyl[14C]methyl) - 1,2-benzisoxazole ( [14C]AD-810) in rats, dogs and monkeys after oral administration in 20 mg/kg was studied. In preliminary human studies, healthy subjects ingested 200 mg of AD-810. [14C]AD-810 was found to be completely absorbed from digestive tracts in animals, since urinary and biliary excretion accounted for virtually total recovery of dosed radioactivity. Plasma levels reached maxima at several hours after administration in all species examined and decreased exponentially. In rats, tissue levels were virtually similar to plasma levels indicating rather even distribution in the body, and tissue radioactivity disappeared with the similar rate to plasma. Autoradiographic findings on the distribution were consistent with radiometric results. Radioactivity was evenly distributed in fetus in the pregnant rat with the similar level to maternal tissue levels. Like other sulfonamide derivatives, AD-810 was markedly taken up by erythrocytes in all species. [14C]AD-810 radioactivity was mostly excreted within 48 to 72 h after administration and its major route was urine in animals. In men, excretion of unchanged AD-810 and its metabolite in urine was found to be rather slow. No significant differences were found in absorption, distribution and excretion of radioactivity after 7 consecutive daily oral dosings of [14C]AD-810 in rats.     

The autoradiographic studies on the distribution of 14C-labeled pivaloyloxymethyl (+)-(6R,7R)- 7-[(Z)-2-(2-amino-4-thiazolyl)-2-methoxyiminoacetamido]- 3-[(5-methyl-2H-tetrazol-2-yl)methyl]-8-o xo-5-thia- 1-azabicyclo [4.2.0]oct-2-ene-2-carboxylate (14C-T-2588) in mice

The distribution of T-2588 was studied with whole body autoradiography in normal male mice and pregnant mice using two radioactive T-2588 labeled at the aminothiazole or pivaloyloxymethyl moieties. When (aminothiazole-2-14C) T-2588 was orally administered, the radioactivity was distributed widely to whole tissues except central nervous systems such as brain and spinal cord. In pregnant mice, no detectable radioactivity was present in the fetus. These results suggested that T-2588 was well absorbed and hardly crossed the blood-brain barrier and placenta. At 4 hours after administration, radioactivity was only observed in gastrointestinal tract implying rapid excretion of T-2588. When (pivaloyloxymethyl-14C) T-2588 was orally administered, radioactivity was accumulated to all tissues and fetus. From these results we speculated that formaldehyde formed by hydrolysis at the pivaloyloxymethyl ester and entered the C1-metabolic pathway.     

Studies on the pharmacokinetics of BMY-28100 (II)

Studies were done in rats on placental transfer and excretion into milk of 14C-BMY-28100 upon single oral administration. Studies on absorption, distribution and excretion of 14C-BMY-28100 were also done upon multiple dosing. 1. Fetal tissue concentration of the drug reached a maximum at 6 hours after dosing on day 18 of gestation. The highest concentration observed was only 0.56 microgram equiv./g in fetal kidney; The transfer of radioactivity into the fetus was low. Similar results were obtained from whole body autoradiograms performed in rats on day 12 and day 18 of gestation. 2. Concentrations of radioactivity in milk reached a maximum of 0.60 microgram equiv./ml at 1 hour after administration, and gradually decreased thereafter. The maximum concentration in milk was 10% of the plasma concentration measured at the same time. 3. In the multiple oral administration study, 24 hours blood levels of radioactivity rose progressively with each dose, and reached a level 3.8 times higher than that observed with single dosing by the final (21st) administration. Tissue concentrations were relatively high in aorta, kidney and large intestine as were found upon single administration. However, the ratios of these levels between multiple and single dosing were lower than those observed in blood; 1.7, 3.6 and 2.9 for aorta, kidney and large intestine, respectively. Urinary and fecal excretion were constant after the 2nd administration.     

Disposition of 3-chloro-4-(dichloromethyl)-5-hydroxy-2(5h)-furanone (mx) in b6c3f1 mice and f344 rats

3-Chloro-4-(dichloromethyl)-5-hydroxy-2(5H)-furanone (MX) is a mutagenic by-product of chlorination of drinking water, particularly where the water contains humic matter. MX has been estimated to account for 50% of the mutagenic activity in some drinking water. A bioassay in rats demonstrated an increased tumor incidence, primarily in liver and thyroid glands. This study was designed to provide disposition/metabolism information in mice to evaluate the necessity of a National Toxicology Program chronic bioassay and to provide data for female rats. Radioactivity was rapidly absorbed and excreted near equally in urine (42-54%) and feces (40-51%) 72 h following oral administration of (14)C-labeled MX at single doses from 0.2 to 20 mg/kg to male and female mice and female rats. A larger percentage (71-73%) of MX-derived radioactivity was excreted in urine after an iv dose (0.2 mg/kg) in both female rats and male mice. Most MX-derived radioactivity was excreted within the first 24 h postdosing. MX was transformed to urinary and biliary metabolites. A major extremely polar urinary metabolite was tentatively identified as 1-hydroxy-1,2,2-ethanetricarboxylic acid. This metabolite is likely transformed from the MX degradation product 2-hydroxy-3-formyl-4-oxo-2-butenoic acid. Oral administration produced highest tissue/blood ratios in the following order: forestomach (>100), glandular stomach, intestine, and kidney. Intravenous administration resulted in high, prolonged levels of radioactivity in blood compared to oral dosing. Therefore, MX disposition appears to be dominated by its chemical reactivity with highest concentrations of radioactivity being found at the site of administration.     

DISPOSITION OF 3-CHLORO-4-(DICHLOROMETHYL)-5-HYDROXY-2(5 H )-FURANONE (MX) IN B6C3F1 MICE AND F344 RATS

3-Chloro-4-(dichloromethyl)-5-hydroxy-2(5 H )-furanone (MX) is a mutagenic by-product of chlorination of drinking water, particularly where the water contains humic matter. MX has been estimated to account for 50% of the mutagenic activity in some drinking water. A bioassay in rats demonstrated an increased tumor incidence, primarily in liver and thyroid glands. This study was designed to provide disposition/metabolism information in mice to evaluate the necessity of a National Toxicology Program chronic bioassay and to provide data for female rats. Radioactivity was rapidly absorbed and excreted near equally in urine (42-54%) and feces (40-51%) 72 h following oral administration of 14 C-labeled MX at single doses from 0.2 to 20 mg/kg to male and female mice and female rats. A larger percentage (71-73%) of MX-derived radioactivity was excreted in urine after an iv dose (0.2 mg/kg) in both female rats and male mice. Most MX-derived radioactivity was excreted within the first 24 h postdosing. MX was transformed to urinary and biliary metabolites. A major extremely polar urinary metabolite was tentatively identified as 1-hydroxy-1,2,2-ethanetricarboxylic acid. This metabolite is likely transformed from the MX degradation product 2-hydroxy-3-formyl-4-oxo-2-butenoic acid. Oral administration produced highest tissue/blood ratios in the following order: forestomach (>100), glandular stomach, intestine, and kidney. Intravenous administration resulted in high, prolonged levels of radioactivity in blood compared to oral dosing. Therefore, MX disposition appears to be dominated by its chemical reactivity with highest concentrations of radioactivity being found at the site of administration.     

Absorption, distribution and excretion of 2,4-diamino-6-(2,5-dichlorophenyl)-s-triazine maleate in rats, dogs and monkeys

Absorption, distribution and excretion of 2,4-diamino-6-(2,5-dichlorophenyl)-s-triazine maleate (MN-1695) were studied in rats, dogs and monkeys after administration of [14C]-MN-1695. MN-1695 was found to be well absorbed from the small intestine after oral administration in all species examined. Plasma level of unchanged MN-1695 reached a maximum at 1 to 4 h after oral administration of [14C]-MN-1695 in rats, dogs and monkeys. The mean elimination half-life of unchanged MN-1695 from plasma was about 3, 4 and 50 h in rats, dogs and monkeys, respectively. Tissue levels of radioactivity after oral administration of [14C]-MN-1695 in rats indicated that [14C]-MN-1695 was distributed throughout the body and the radioactivity in tissues disappeared with a rate similar to that in plasma. A stomach autoradiogram after intravenous administration of [14C]-MN-1695 in the rat revealed the radioactivity localized in the gastric mucosa where MN-1695 was assumed to exert its pharmacological activity. In pregnant rats, [14C]-MN-1695 was distributed to the fetus with levels similar to maternal blood levels. After oral administration of [14C]-MN-1695 in rats, 39 to 46% of the dose was excreted into the urine and 50 to 63% of the dose into the feces, within 96 h. In dogs, about 40% of the dose was excreted into the urine and about 50% of the dose into the feces, within 6 days after oral administration. In monkeys, within 14 days after oral administration, about 60 and 30% of the dose were excreted into the urine and feces, respectively, and the main excretion route was the urine.(ABSTRACT TRUNCATED AT 250 WORDS)     

The fate of (-)1-(benzofuran-2-yl)-2-propylaminopentane . HCl, (-)-BPAP, in rats, a potent enhancer of the impulse-evoked release of catecholamines and serotonin in the brain.

Our aim was to study the fate of (-)-1-(benzofuran-2-yl)-2-propylaminopentane .HCl [(-)-BPAP] in rats, using radio-labelled compound [(-)-BPAP-14C]. Radioactivity was measured by liquid scintillation technique and the tissue concentrations of radioactivity were calculated on the basis of the specific activity of (-)-BPAP-14C and the values are given in ngeq./g. Radioactivity was well absorbed after i.p., s.c. and oral treatment and Cmax has been reached at 30 to 60 min following drug administration. A second peak, detected at 4 hours, indicated enterohepatic circulation of the substance. The highest tissue levels of radioactivity were reached at 30 min following s.c. treatment. The time-related changes of radioactivity were measured in nine selected brain regions after s.c. administration of (-)-BPAP-14C. A similar distribution profile was observed in the brain regions with a peak level at 30 min. Radioactivity is preferentially eliminated through the urine, the secondary route of excretion was the stool. More than 90% of the substance was recovered in the excreta during 72 hours. The t1/2 beta was found to be 5.5 to 5.8 hours. (-)-BPAP was well absorbed and penetrated the brain. Its elimination was fast and enterohepatic circulation was observed in rats.     

Metabolic fate of the new anti-ulcer drug enprostil in animals. 1st communication: absorption, distribution and excretion in the mouse, rat and rabbit

Absorption, distribution and excretion of [3H]-enprostil ((+-)-11a,15a-dihydroxy-9-oxo-16-phenoxy-17,18,19,20-tetranorpr osta -4,5,13(t)-trienoic acid methyl ester, TA-84135), a new anti-ulcer prostaglandin, were studied in mice, rats and rabbits. Radioactivity associated with enprostil was rapidly absorbed from the gastrointestinal tract with Tmax values of 15 or 30 min. Absorption was also efficient inasmuch as approximately 80% of an oral dose was recovered in bile and urine in 24 h in bile duct-cannulated rats. Experiments in pylorus-ligated, bile duct-cannulated rats demonstrated that enprostil was mainly absorbed from the intestine, rather than from the stomach. In mice given oral doses of 2, 8 and 32 micrograms/kg, Cmax and AUC values of enprostil radioequivalents increased proportionately to the increase in dose, indicating linear kinetics over this dose range. Distribution of enprostil-associated radioactivity was investigated in rats by quantitating tritium in various tissues after the oral administration of [3H]-enprostil. Radioactivity in tissues was highest at 15 or 30 min after dosing. Highest levels of radioactivity were found in the stomach and intestines, the organs which came into direct contact with the dose, and the liver and kidney, the organs involved in excretion of enprostil. The rate of elimination of enprostil-associated radioactivity from all tissues and from plasma was similar. Enprostil-associated radioactivity did not accumulate in any tissue. Radioactivity was found in fetuses following oral administration of [3H]-enprostil to rats on the 12th or 19th day of gestation.(ABSTRACT TRUNCATED AT 250 WORDS)     

Tissue dosimetry, metabolism and excretion of pentavalent and trivalent dimethylated arsenic in mice after oral administration

Dimethylarsinic acid (DMA(V)) is a rat bladder carcinogen and the major urinary metabolite of administered inorganic arsenic in most mammals. This study examined the disposition of pentavalent and trivalent dimethylated arsenic in mice after acute oral administration. Adult female mice were administered [(14)C]-DMA(V) (0.6 or 60 mg As/kg) and sacrificed serially over 24 h. Tissues and excreta were collected for analysis of radioactivity. Other mice were administered unlabeled DMA(V) (0.6 or 60 mg As/kg) or dimethylarsinous acid (DMA(III)) (0.6 mg As/kg) and sacrificed at 2 or 24 h. Tissues (2 h) and urine (24 h) were collected and analyzed for arsenicals. Absorption, distribution and excretion of [(14)C]-DMA(V) were rapid, as radioactivity was detected in tissues and urine at 0.25 h. For low dose DMA(V) mice, there was a greater fractional absorption of DMA(V) and significantly greater tissue concentrations of radioactivity at several time points. Radioactivity distributed greatest to the liver (1-2% of dose) and declined to less than 0.05% in all tissues examined at 24 h. Urinary excretion of radioactivity was significantly greater in the 0.6 mg As/kg DMA(V) group. Conversely, fecal excretion of radioactivity was significantly greater in the high dose group. Urinary metabolites of DMA(V) included DMA(III), trimethylarsine oxide (TMAO), dimethylthioarsinic acid and trimethylarsine sulfide. Urinary metabolites of DMA(III) included TMAO, dimethylthioarsinic acid and trimethylarsine sulfide. DMA(V) was also excreted by DMA(III)-treated mice, showing its sensitivity to oxidation. TMAO was detected in tissues of the high dose DMA(V) group. The low acute toxicity of DMA(V) in the mouse appears to be due in part to its minimal retention and rapid elimination.     

Pharmacokinetic study of maleate acid of 2-(N,N-dimethylaminoethanol-14C1)-cyclohexylpropionate (cyprodenate) and of N,N-dimethylaminoethanol-14C1 in animals.

The localization, distribution, and elimination of maleate acid 2-(N,N-dimethylaminoethanol-14C1)-cyclohexylpropionate (14C-cyprodenate, Actebral) was studied in rats and pigs. Beside this, dimethylaminoethanol-14C (DMAE) was also administered to rats enabling a comparison of the pharmacokinetics of the two 14C-labelled molecules to be made. The study of the localization by autoradiography and the study of the quantitative distribution of the radioactivity showed that cyprodenate, a psychotonic drug, diffused more rapidly than DMAE through the hemo-encephalic barrier. However, it was also observed that the radioactivity found in the brain rises continually as a function of time, regardless of the product administered. The two labelled products were primarily excreted in the urine (30-35 per cent of the dose in 72 h in rats and 6 per cent of the dose in 48 h in pigs) following oral administration of cyprodenate. Radioactivity found in the feces was practically nil and in rats the biliary elimination of the drug was very weak. Thus, whichever animal is used, it was found that 14C-cyprodenate is totally absorbed. Radioactivity expired as 14CO2 was negligible (around 1 per cent of the administered dose in 8 h), however, this value increases as a function of time, becoming 4 per cent in 24 h. In rats the maximum radioactivity in the blood was found at 45 min to 1 h after oral administration of 14C-cyprodenate. These values decrease slowly until 3 h when they begin to increase again. The rising of the blood level values is practically the same for pigs, the maximum being attained at 1 h. Therefore, whatever route of administration, whichever dose or animal, we always found a progressive elevation of the protein binding to the plasma proteins for these two labelled products in vivo.     

Studies on the pharmacokinetics of BMY-28100 (I)

The pharmacokinetics of BMY-28100 have been studied in rats and monkeys upon oral administration of 14C-BMY-28100. 1. In rats administered with BMY-28100 at a single oral dose of 20 mg/kg, the peak blood level of the drug was 6.30 micrograms equiv./ml at 1 hour after administration. Blood levels declined biphasically, thereafter. The AUC value was 37.0 micrograms equiv..hr/ml, and was 97% of that observed after intravenous administration. This suggests that BMY-28100 is absorbed at a high absorption rate from the gastro-intestinal tract. 2. In monkeys administered with a single oral dose of 20 mg/kg, the peak blood level was 4.26 micrograms equiv./ml at 3 hours after administration. Thereafter, blood levels declined biphasically as did in rats. The AUC was 38.9 micrograms equiv..hr/ml, which is similar to that observed in rats. 3. Urinary and fecal excretion after 20 mg/kg oral administration were 60.9% and 38.1%, respectively, in rats, and 40.3% and 51.2%, respectively, in monkeys. 4. Although absorption from gastro-intestinal tract was delayed by food intake, this did not affect the total amount absorbed in rats. 5. The absorption rates were similar in rats administered with 20 and 60 mg/kg, while a lower rate was obtained with 200 mg/kg. 6. In rats, biliary excretion was 28.5% of dose administered. Thirty-nine percent of the biliary radioactivity was reabsorbed from the intestinal tract. 7. No differences between sexes were observed in absorption and excretion in rats administered with the drug at 20 mg/kg orally. 8. In rats administered with 20 mg/kg, the radioactivity distributed rapidly to the whole body. High levels of radioactivity were found in gastro-intestinal tract, kidney, urinary bladder, aorta and liver. The radioactivity was removed rapidly from the tissues. Autoradiograms of the whole body were consistent with the measured tissue distribution. Relatively high levels of radioactivity were found in aorta, fascia, and ligament at 0.5, 1, 6, and 24 hours. 9. In vivo protein binding, which increased with time after administration, was 56.8 to 73.5% in rat and 36.3 to 58.6% in monkey. The in vitro protein binding at 0.4 to 50 micrograms/ml of drug concentration was 50.0 to 54.7% in rat, 32.3 to 35.0% in monkey, and 33.4 to 36.3% in human. 10. A stability test of 14C-BMY-28100 in plasma solution showed that the drug decomposed gradually into relatively polar compound(s). At 8 and 24 hours, the proportions of unchanged 14C-BMY-28100 were 53.2% and 5.9%, respectively.     

Absorption, distribution, excretion and metabolism of a basic ether compound (R97) with antispasmodic activity]

The absorption, distribution, excretion and metabolism of 14C labelled 2-chlorophenyl-1-phenyl-3-(2 methyl-piperidino) propyl ether methyl iodide (14C-R97) were studied by means of direct measurement of radioactivity and autoradiographic technique in rats. 1) With intravenous administration, radioactivity was found in all the tissues and organs immediately after dosing, with particularly high levels in the liver, kidney, heart and lung. Five minutes after administration, the level of radioactivity in blood decreased to about 6% of the initial level, indicating the rapid absorption of radioactive material by other tissues and organs. Radioactivity was not detected in the brain and eye. Thirty minutes after administration, the concentration of radioactivity in the gastrointestinal contents was very high and a certain amount of radioactivity uptake was noted both in gastric and intestinal mucosa. Approximately 12% and 40% of radioactivity administered was excreted in the urine and feces respectively during the first 24 hours, however, the excretion of radioactivity by expiration was not determined. 2) With oral administration, radioactivity was restricted to the gastrointestinal tract. Activities in other tissues and organs were not detectable. Approximately 94% of the radioactivity administered was recovered in feces during the first 24 hours. 3) Radioactivity was not observed in either the foetus or placenta after both intravenous and oral administrations. 4) The results from autoradiographic study were in good accord with those described above.     

Distribution and elimination of [14C] hexachlorobenzene after single oral exposure in the rainbow trout (Salmo gairdneri)

Distribution and elimination of hexachlorobenzene (HCB) after administration to rainbow trout (Salmo gairdneri) of a single oral dose of 5 microCi [14C] HCB/100 g body weight were studied by whole-body autoradiography and liquid scintillation counting. To obtain some information on the physicochemical properties of the radiolabelled compounds, whole-body autoradiography was performed exposing parallel sagittal sections, treated at -20 degrees C, evaporated at 50 degrees C, and extracted separately with polar and nonpolar solvents. At d 1, radioactivity was distributed throughout the body. The highest concentration of radioactivity was found in adipose tissue. In the abdominal fat, the peak level of radioactivity was measured at d 30. No part of the radioactivity in the bile was evaporable. Radioactivity in the intestinal content, the skin, and the uveal tract was partly evaporable, while only traces of radioactivity remained in adipose tissue after evaporation. Radioactivity in the bile was extractable with water only. No radioactivity remained in any tissue after extraction with polar and nonpolar solvents. The rate of elimination was slow, and substantial amounts of radioactivity remained in the body 120 d after administration. In addition to bile excretion of nonevaporable, water-soluble radiolabeled compounds, a possible excretion over the intestinal mucosa was suggested.     

Metabolism and Disposition of the HIV-1 Protease Inhibitor Lopinavir (ABT-378) Given in Combination with Ritonavir in Rats, Dogs, and Humans

PURPOSE: The objective of this study was to examine the metabolism and disposition of the HIV protease inhibitor lopinavir in humans and animal models. METHODS: The plasma protein binding of [14C]lopinavir was examined in vitro via equilibrium dialysis technique. The tissue distribution of radioactivity was examined in rats dosed with [14C]lopinavir in combination with ritonavir. The metabolism and disposition of [14C]lopinavir was examined in rats, dogs, and humans given alone (in rats only) or in combination with ritonavir. RESULTS: The plasma protein binding of lopinavir was high in all species (97.4-99.7% in human plasma), with a concentration-dependent decrease in binding. Radioactivity was extensively distributed into tissues, except brain, in rats. On oral dosing to rats, ritonavir was found to increase the exposure of lopinavir-derived radioactivity 13-fold. Radioactivity was primarily cleared via the hepato-biliary route in all species (>82% of radioactive dose excreted via fecal route), with urinary route of elimination being significant only in humans (10.4% of radioactive dose). Oxidative metabolites were the predominant components of excreted radioactivity. The predominant site of metabolism was found to be the carbon-4 of the cyclic urea moiety, with subsequent secondary metabolism occurring on the diphenyl core moiety. In all the three species examined, the primary component of plasma radioactivity was unchanged lopinavir (>88%) with small amounts of oxidative metabolites. CONCLUSIONS: Lopinavir was subject to extensive metabolism in vivo. Co-administered ritonavir markedly enhanced the pharmacokinetics of lopinavir-derived radioactivity in rats, probably due to inhibition of presystemic and systemic metabolism, leading to an increased exposure to this potent HIV protease inhibitor.     

Study on the metabolic fate of catena-(S)-[mu-[N alpha-(3- aminopropionyl)histidinato(2-)-N1,N2,O:N tau]-zinc]. 1st communication: absorption, distribution, metabolism and excretion after single administration to rats.

Studies on the absorption, distribution, metabolism and excretion of 14C-Z-103 and 65Zn-Z-103 (catena-(S)-[mu-[N alpha-(3- aminopropionyl)histidinato(2-)-N1,N2,O:N tau]-zinc], CAS 107667-60-7) were performed after oral administration to rats. After oral administration of 14C-Z-103 and 65Zn-Z-103, the blood concentrations of 14C-radioactivity were 30- to 40-fold higher than those of 65Zn-radioactivity. The 14C-radioactivity showed a dose-dependent increase of Cmax and AUC values in the dose range from 13.1 mg/kg to 100 mg/kg, and remained longer in the blood. In contrast, no dose-dependent increase of AUC was observed with 65Zn-radioactivity, suggesting saturation of absorption at doses more than 30 mg/kg of 65Zn-Z-103. The major route of excretion of 14C-radioactivity was by excretion into the expired air, amounting to 38.8% of the administered dose, while the urinary and fecal excretions were low values at 4.1% and 13.3%, respectively. The radioactivity remaining in the carcass accounted for 39.3% of the dose. On the other hand, in the case of 65Zn-radioactivity, 85.0% of the administered dose was excreted into the feces and 10.5% of the dose remained in the carcass. Both 14C- and 65Zn-radioactivities were distributed to the whole body, while 14C-radioactivity showed higher concentrations in the body, and was retained longer than the 65Zn-radioactivity. When the plasma and the liver and kidney homogenates, from rats received 14C-Z-103, were treated with trichloroacetic acid (TCA), the radioactivities in the TCA-insoluble fraction increased as a function of time. Following the treatment of the homogenates with protease, the radioactivities in the TCA-insoluble fraction decreased. In vitro study was showed that L-carnosine of 14C-Z-103 added to the homogenates of liver and small intestine was metabolized to L-histidine. The results suggest that the remaining radioactivities in tissues and organs caused the incorporation of the metabolites of 14C-Z-103 into endogenous high molecular substances.     

Pharmacokinetics of NS-49, a phenethylamine class alpha 1A-adrenoceptor agonist. 1st communication: absorption and excretion in rats after a single administration of 14C-NS-49.

The absorption and excretion of NS-49 ((R)-(-)-3'-(2-amino-1-hydroxyethyl)-4'-fluoromethanesulfonanilide hydrochloride, CAS 137431-04-0), a phenethylamine class alpha 1A-adrenoceptor agonist, were studied in rats after a single administration of 14C-NS-49. In addition, the protein binding of this drug was investigated in vivo and in vitro. After oral administration of 14C-NS-49 (1 mg/kg) to male rats, the radioactivity concentrations in the blood and plasma reached maximums within 1 h, then decreased biexponentially with respective elimination half-lives of 25.4 and 11.9 h. Most of the plasma radioactivity was due to unchanged NS-49, indicating of the poor metabolism of this drug in rats. The results of the in situ absorption study using the intestinal loop method showed that 14C-NS-49 was well absorbed from the small intestine. Systemic availability was high (86%), as determined by a comparison of the areas under the plasma concentration-time curves of unchanged NS-49 for oral and intravenous administrations. Food affected the absorption of NS-49. There were no significant sex-related differences in the plasma concentration profiles after the intravenous administration of 14C-NS-49 (p > 0.05). NS-49 was primarily eliminated by renal excretion, 76% and 62% of the dose being excreted unchanged in the urine after intravenous and oral administrations, respectively. The absorption rate, determined on the basis of the urinary excretion of radioactivity, was 83%, being almost the same as the systemic availability. First-pass metabolism of NS-49, therefore, is considered to be very limited in rats. The excretion of radioactivity in the bile within 48 h after the oral administration of 14C-NS-49 (1 mg/kg) was 5.9% of the dose, and the excretion of radioactivity in the exhaled air after the intravenous administration (0.2 mg/kg) was negligible. The percentage of 14C-NS-49 bound to serum proteins in vitro was less than 15% in all the animal species tested. The percentage of radioactivity bound to rat serum proteins after the oral administration of 14C-NS-49 (1 mg/kg) was 16-21%.     

Disposition of tetrachloro(14C)ethylene following oral and inhalation exposure in rats

Tetrachloro[¹⁴C]ethylene (Perc) was administered to adult, male Sprague-Dawley rats by gavage (1 or 500 mg/kg) or by inhalation (10 or 600 ppm, 6 hr duration). Within 72 hr following oral administration of 1 mg/kg or inhalation of 10 ppm [¹⁴C]Perc, approximately 70% of the body burden of radioactivity was excreted in expired air as Perc, 26% as ¹⁴CO₂ and nonvolatile metabolites in urine and feces, and 3 to 4% remained in the carcass. After oral administration of 500 mg/kg or inhalation of 600 ppm [¹⁴C]Perc, 89% of the radioactivity was recovered in expired air as Perc, 9% as ¹⁴CO₂ and urinary and fecal metabolites, and 1 to 2% remained in the carcass. The major urinary metabolite of Perc was identified as oxalic acid. Pulmonary elimination of Perc was monophasic with a half life ($\text{t}\text{1}\text{2}$) of approximately 7 hr independent of dose or route of administration. Radioactivity remaining in the carcass 72 hr after exposure by either route was primarily distributed within liver, kidney and fat tissue. In liver, 85 to 90% of the total radioactivity was cleared within 72 hr following inhalation exposure to 10 or 600 ppm. Nonextractable radioactivity, either bound or incorporated into hepatic macromolecular material, was cleared at a slower rate. The tissue concentration of nonextractable radioactivity was dependent upon body burden and metabolic capacity but apparently not upon route of administration. Thus, the data indicate that disposition of Perc is a saturable, primarily dose-dependent process in rats.