Disposition and tissue distribution of angiopeptin in the rat.

The disposition and tissue distribution of angiopeptin, a long-acting octapeptide analogue of somatostatin, were studied in rats following single iv and sc administration of the drug. Similar plasma levels and excretion values of angiopeptin were observed by using radioimmunoassay and radiolabeling techniques. Angiopeptin was absorbed fairly rapidly, with a mean peak plasma level of 25 +/- 4.1 ng/ml at 10-15 min after administration. The kinetics of angiopeptin following sc administration closely resembled those following iv administration due to rapid absorption. The pharmacokinetics of angiopeptin can be described by a two-compartment model. The plasma half-life of the drug ranged from 2.6-2.9 hr when administered sc and 1.98-2.5 hr when given iv. Distribution of angiopeptin was rapid, with the highest concentration appearing in the liver. Half-lives in the liver and bile were short. Most of the drug was excreted in the feces via the bile, while approximately 10% was excreted in the urine. Angiopeptin was also found to be secreted in the saliva. TLC and HPLC of blood, urine, feces, and bile samples did not reveal the presence of any metabolites. In conclusion, the in vivo fate of angiopeptin is characterized by little or no hepatic metabolism and rapid biliary excretion.     

Pharmacokinetics of the mycotoxin penicillic acid in male mice: absorption, distribution, excretion, and kinetics

The pharmacokinetics of penicillic acid (PA), a carcinogenic mycotoxin, was investigated in male mice. Absorption of PA after po administration of [14C]PA was rapid. Only a small percentage of the radioactivity in the plasma was unchanged PA. After ip or iv administration of [14C]PA (90 mg/kg), blood, liver, kidneys, intestine, lungs, heart, and spleen contained the largest amounts of radioactivity while brain tissue accumulated the least. Over 90% and approximately 60% of the administered radioactivity was excreted in the urine after iv and ip injection, respectively, but essentially no unchanged PA was detected in the urine. Over 25% of the administered radioactivity following an iv dose of [14C]PA (90 mg/kg) was excreted in the bile in 60 min; no unchanged PA was detected in the bile. The excretion of radioactivity in the bile was decreased in diethyl maleate-pretreated mice. Only a small amount of the administered radioactivity was recovered in the feces and as expired CO2. The unchanged PA concentration-time curve in plasma was best fit by three, two, and one compartment open models after iv, ip, and po administration, respectively. Based on these results, it was concluded that metabolism and not excretion of unchanged parent penicillic acid is the major process of elimination of PA from the blood. There are extensive route-dependent differences in the kinetic behavior of PA.     

Effect of sodium salicylate on the fate of warfarin in the rat

Salicylate (88.9 mg/kg, po) decreased the blood level of radioactivity emanating from [¹⁴C]warfarin (1 mg/kg, iv and po) during the 24 hr following drug administration, reduced the area under the blood radioactivity vs time curve, and shortened the half-life for elimination of radioactivity from the blood. During the first 6 hr after drug administration, salicylate increased the biliary excretion of radioactivity, which resulted in enhanced fecal excretion of warfarin and its metabolites. Salicylate administration initially increased and later decreased the amount of radioactivity in the liver, and increased the proportion of warfarin metabolites to unchanged warfarin in this organ. It did not affect the proportion of unchanged warfarin to metabolites in the blood, bile and urine, or the total amount of radioactivity excreted during 48 hr in the urine and feces. In vitro, salicylate decreased the binding of [¹⁴C]warfarin to rat serum proteins in a linear manner. It is concluded that, in the rat, salicylate competes with warfarin for serum protein binding sites, thereby facilitating its uptake by the liver. Second, through a combination of its choleretic action and effect on membrane transport, salicylate enhances the biliary excretion of warfarin and its metabolites, thus accounting for the decreased concentration in the blood and lowered antiboagulant action.     

Observations on the absorption, distribution, metabolism, and excretion of the dopamine (D2) agonist, quinelorane, in rats, mice, dogs, and monkeys.

Following the oral administration of [14C]quinelorane, a potent and highly specific dopamine (D2) agonist, to rats, mice, and monkeys, the compound was well absorbed, with 50% or more of the radioactivity appearing in the urine within 24 hr. Dogs were pretreated with 22 consecutive daily doses of quinelorane by the oral route (in order to induce tachyphylaxis to the emetic effect) before receiving an iv dose of [14C]quinelorane; just over 80% of the radioactivity was excreted into the urine. A tissue-distribution study in rats receiving a single oral dose of 0.1 mg/kg [14C]quinelorane indicated a widespread distribution of radioactivity, with levels being notably low in the blood and plasma and high in the salivary gland, adrenals, pancreas, and spleen; levels were highest in the stomach and kidneys. The Tmax of radiocarbon in the 22 tissues varied between 0.5 and 6 hr, with some tissues showing a plateau of radioactivity between these time-points. After 8 hr, levels of radioactivity were clearly decreasing, and by 48 hr, background levels were attained. Following the oral and iv administration of quinelorane to rats, the systemic bioavailability was calculated to be 16% and the volume of distribution was found to approximate that of total extracellular water, i.e. approximately 300 ml/kg. Since absorption was satisfactory and the tissue distribution study indicated widespread radioactivity, the low bioavailability may be due to first-pass metabolism. Rats excreted marginally more of the N-despropyl metabolite than unchanged drug into the urine, and dogs excreted principally unchanged quinelorane into their urine, followed by the N-despropyl metabolite.(ABSTRACT TRUNCATED AT 250 WORDS)     

The metabolic disposition of C-labelled carmoisine in the rat after oral and intravenous administration

The absorption, distribution and excretion of the red azo dye carmoisine (Ext. D & C No. 10) was studied in male rats. [14C]Carmoisine was administered in a dose of 200 mg/kg (25 microCi) by gavage or in the same dose (200 mg/kg; 3 microCi) by intravenous injection, and radioactivity was measured in blood, tissue, faeces and urine at different times after dosing. After oral administration of the dye, no radioactivity was detected in the brain, adipose tissue, muscle, testes, spleen or lung, and recovery of the administered activity in faeces and urine was almost complete by 32 hr. The radioactivity profile of the blood indicated rapid but poor absorption of [14C]carmoisine, a maximum radioactivity content corresponding to 0.01% of the dose per ml of blood being reached within 10 min. The decay curve for 14C radioactivity in the blood after iv injection of [14C]carmoisine indicated rapid distribution to the tissues and could be described in terms of a two-compartment mathematical model. The highest levels of radioactivity occurred in the gastro-intestinal tract and liver after the injection but after 24 hr no radioactivity was detectable in these or other tissues. All the radioactivity was recovered in the faeces and urine in the 24 hr following iv injection, the 79% of the dose present in faeces indicating active excretion of the dye and its metabolites in the bile and poor reabsorption from the intestine. The bioavailability of [14C]carmoisine, calculated from the blood-radioactivity curves after oral and iv administration, was less than 10%.     

Tissue distribution, disposition, and metabolism of cyclosporine in rats

Tissue distribution, disposition, and metabolism of 3H-cyclosporine were studied in rats after single and repeated oral doses of 10 and 30 mg/kg and after an iv dose of 3 mg/kg. The oral doses of 10 and 30 mg/kg were dissolved in polyethylene glycol 200/ethanol or in olive oil/Labrafil/ethanol. Absorption from both formulations was slow and incomplete, with peak 3H blood levels at 3-4 hr. Approximately 30% of the radioactive dose was absorbed, which is consistent with oral bioavailability data for cyclosporine. More than 70% of the radioactivity was excreted in feces and up to 15% in urine. Elimination via the bile accounted for 10 and 60% of the oral and iv doses, respectively. Since unchanged cyclosporine predominated in both blood and tissues at early time points, the half-lives of the distribution phases (t 1/2 alpha) of parent drug and of total radioactivity were similar. In blood, kidney, liver, and lymph nodes, t 1/2 alpha of cyclosporine ranged from 6-10 hr. Elimination of radioactivity from the systemic circulation was multiphasic, with a terminal half-life of 20-30 hr. 3H-Cyclosporine was extensively distributed throughout the body, with highest concentrations in liver, kidney, endocrine glands, and adipose tissue. The concentrations of both total radioactivity and parent drug were greater in tissues than in blood, which is consistent with the high lipid solubility of cyclosporine and some of its metabolites. Skin and adipose tissue were the main storage sites for unchanged cyclosporine. Elimination half-lives were slower for most tissues than for blood and increased with multiple dosing. The amount of unchanged drug was negligible in urine and bile.(ABSTRACT TRUNCATED AT 250 WORDS)     

Metabolic studies on metiazinic acid I. Absorption, distribution, excretion and metabolism in rats and rabbits.

Absorption, distribution, excretion and metabolism after oral administration of 3-H-labelled metiazinic acid were studied. The administered radioactivity was excreted through both the urinary and fecal routes. The maximum levels of concentration in blood and most tissues were shown with 3 hr after dosing. The highest radioactivity was found in the kidney throughout all experiments. Relatively high radioactivity was observed in inflammatory-treated parts in rats. Unchanged compound, metiazinic acid S-oxide and these conjugates were found in urine and feces. Approximately 60% of the unchanged form was observed in plasma after 6 hr.     

The metabolism and kinetics of tiflorex in the rat

14C-Tiflorex given either orally or intravenously to male rats (10 mg/kg; 250 microCi) was well absorbed orally; greater than 70% of the dose was excreted in the urine in the first 48 hr after dosing by either route of administration. Inasmuch as part of the dose (10%) was excreted in the feces after iv administration, it is probable that biliary excretion is a route of elimination. This was shown to be so by cannulation of the bile duct. The major route of metabolism was S-oxidation to give the sulfoxides and sulfones of tiflorex (7% each) and nortiflorex (10 and 20%, respectively) which were excreted together with the unchanged drug (1%) in the 0- to 48-hr urine. Examination of the plasma for the unchanged drug and its metabolites showed the drug to be rapidly absorbed orally, maximum levels being attained within 30 min. The plasma half-life for the elimination phase of the unchanged drug was relatively long (7.5 hr) compared with the metabolites (2.5 hr) with the exception of nortiflorex sulfone (9.8 hr) and two as yet unidentified metabolites which had half-lives in excess of 24 hr. The latter three compounds were responsible for the relatively long plasma half-life of total radioactivity (ca. 13 hr). The ratio of the areas under the plasma curve for unchanged drug indicated a low bioavailability (30%). It appears that the predominant route of metabolism of this group of compounds in the rat, p-hydroxyltation had been blocked by the trifluoromethylthio group, with consequent emphasis on S-oxidation.     

雷公藤甲素在大鼠体内过程的研究

雷公藤甲素具有抗肿瘤、抗炎和免疫抑制作用,能迅速由胃肠道吸收,但并不完全。本实验研究了该药口服和静注给药途径的分布和排泄,结果表明:口服和静注后,药物在体内的分布和消除速率大体相似,均以肝中浓度为最高,依次为脾、肺、肾、肠、心和脑,体内消除较缓慢。血浆蛋白结合率为64.7%。24d内,口服后尿粪总排泄量为给药量的67.5% ,其中粪占52.4%;静注后为61.9%,粪占25%。24h内胆汁排泄为6.73%。提取尿、粪和胆汁经TLC、放射性测定及放射自显影分析,表明以原药排泄为主和部分代谢物。     

Pharmacokinetics and fate of [3H]trospectomycin sulfate, a novel aminocyclitol antibiotic, in male and female dogs and rabbits. Allometric scaling with human.

The pharmacokinetics and fate of [3H]trospectomycin sulfate, a novel aminocyclitol antibiotic, were examined in male and female dogs and rabbits. Total radioactivity levels in plasma were associated with unchanged trospectomycin in both dog and rabbit. No unchanged drug was found in rabbit urine. Two radioactive components were found in dog urine; one was indistinguishable from trospectomycin and the other was probably a degradation product. The disappearance of drug from plasma followed a biphasic pattern and was well described by a bi-exponential function with half-lives of 0.4-0.8 and 30-70 hr in the dog and 0.4 and 90-120 hr in the rabbit. There was a large distribution volume (Vss), which indicated some retention of drug by tissues. The clearance (CL) for both animals was within the normal range for glomerular filtration rate. CL and Vss were not different between the sexes in the dog or rabbit. Excretion in both animals was initially rapid (greater than 40% by 4 hr) and mainly by the urinary route (fecal excretion less than 10%). Urinary excretion was not significantly different between the sexes. Over the dose range of 25-100 mg/kg, the plasma pharmacokinetics in the dog were linear. However, the recovery of radioactivity in the urine was significantly reduced at the highest dose. Trospectomycin CL in rat, human (obtained from previous studies), dog, and rabbit was described by the allometric equation, CL (ml/hr) = 132 x M0.91 where M is the body mass in kg.     

~3H-小檗碱在家兔及小鼠体内的药代动力学研究

~3H—小檗碱家兔ig、iv后,血药时程曲线符合二室模型。动力学参数:T1/2β为35.3±1.3h(ig)和35.8±2h(iv),Vd为20±3L/kg(ig)和22.1±1.7L/kg。该药吸收快,分布广泛。肺中浓度最高,其次为肝、脾、肾、心。血浆蛋白结合率为38±3％。大鼠6d内从尿和粪中排泄分别为73％和10.9％。尿液排泄中以原形药物为主,并有代谢产物。     

Metabolism, plasma or serum levels, and elimination of phenformin in guinea pigs, rats, and dogs.

14C-Phenformin hydrochloride was used for investigating the metabolism, plasma or serum levels, and elimination of the drug following 1.5-mg/kg po or iv doses to guinea pigs, rats, and dogs. The amounts of individual metabolites and unchanged drug were assessed in urine as well as in plasma or serum. The glucuronide of 1-(p-hydroxyphenethyl)biguanide was a major metabolite in the blood and urine of all three species. Guinea pig serum and urine contained a sizable quantity of unchanged drug. Dog plasma and urine had significant amounts of nonconjugated 1-(p-hydroxyphenethyl)biguanide and of an unidentified major metabolite. In all three species following intravenous drug administration, unchanged drug contributed significantly to the radioactivity found in blood and urine. The apparent half-lives of phenformin eliminateion were 0.3-0.8 day for guinea pigs and rats and 1-1.5 days for dogs. Urinary excretion data indicate apparent half-lives of approximately 1.3-1.5 days for the elimination of each of the three major metabolites in dogs.     

Disposition, metabolism, and excretion of U-71038, a novel renin inhibitor peptide, in the rat

The in vivo fate of U-71038 (Boc-Pro-Phe-N-MeHis-Leu psi [CHOHCH2] Val-Ile-(aminomethyl)pyridine), a potent renin inhibitor, was investigated in rats by single iv administration of tritium-labeled drug at a dose level of 5 mg/kg. The plasma concentrations of drug-related radioactivity diminished very rapidly during the first hour after dosing, with the initial concentrations measured at 2 min falling by more than 95% during the first 30 min. Estimates of the approximate half-life of this earliest phase of the plasma concentration-time curve gave an average value of 4 min. The residual amount of radioactivity after 30 min was cleared from the plasma more slowly, with trace levels still detected 48 hr after dosing. The radioactivity was recovered chiefly (91% of the dose) in feces, indicating biliary clearance as the primary route of elimination from systemic circulation. Urinary recoveries averaged 4% of the dose. Radio-HPLC profiling of plasma, urine, and bile extracts detected only a single radioactive drug-related component in these samples. Preparative HPLC was used to isolate this component from bile; mass spectral comparison to U-71038 confirmed its identity as the unchanged drug. Therefore, U-71038 does not undergo significant systemic metabolism in this species and is eliminated in bile and urine in intact form. Distribution of drug-related radioactivity was very rapid to most of the organs and tissues that were sampled, with the exception of very limited penetration into the central nervous system. Highest tissue levels of tritium were generally found in organs associated with elimination (liver, intestine, kidney) and in thyroid.     

Studies on the metabolic fate of 14C-rokitamycin. Absorption, distribution, metabolism and excretion in infant rats

14C-Rokitamycin (RKM) at the dose of 200 mg/kg was administered orally to fasted infant rats to study the absorption, distribution, metabolism and excretion in infant animals. The mean blood level of 14C-RKM reached its peak of 20.25 micrograms/ml in 30 minutes. The mean area under the curve was 93.23 micrograms.hr/ml. In vivo plasma protein binding rates of 14C-RKM were about 30% in both infant and adult rats. 14C-RKM was distributed at high concentrations into liver, kidney, lung, spleen, pancreas, bone marrow, submaxillary gland and some other tissues. Major metabolites detected in plasma, urine and bile were 10"-OH-RKM, leucomycin A7, leucomycin V and 14-OH-leucomycin V. In excretion studies, about 97% of the administered radioactivity was recovered in urine and feces within 144 hours. After intraduodenal administration to rats with cannulated bile ducts, 7.42% and 25.66% of the radioactivity were excreted within 24 hours in the urine and bile, respectively.     

The pharmacokinetics and metabolism of pentachlorophenol in rats

The pharmacokinetic profile of pentachlorophenol (PCP) was determined in male and female rats to assist in the assessment of its toxic hazard. Metabolism, excretion, and blood plasma concentrations as a function of time were determined for rats given 10 or 100 mg of [¹⁴C]PCP/kg. Elimination of PCP from the body was by catabolism to tetrachlorohydroquinone, by excretion of unchanged PCP and its glucuronide conjugate in the urine, and by excretion of PCP or its metabolites into the bile. The metabolites of PCP were rapidly excreted via the urine and were not retained in the body. The dynamics for the overall elimination of radioactivity from the body was biphasic in males and females given 10 mg/kg and in males given 100 mg/kg. For females given 100 mg/kg, it was monophasic, suggesting a dose-dependent fate. The rapid phase of elimination had half-lives of 17 and 13 hr for males and females given 10 mg/kg and 13 hr for males given 100 mg/kg. Over 90% of the dose was eliminated during the rapid phase. For females given 100 mg/kg, the monophasic elimination had a half-life of 27 hr. Analysis of the radioactivity in selected tissues from males and females given 10 mg/kg revealed the highest concentrations in the liver and kidneys and the lowest in the brain and fat. In females plasma concentrations of PCP were consistently higher than in males. About 99% of the PCP in plasma was bound to protein, which probably was responsible for low tissue-to-plasma ratios and a low renal clearance rate.     

The excretion of 3H-papaverine in the rat

The excretion of ³H-papaverine has been studied in the rat. After per oral as well as parenteral administration about 85 per cent of the administered radioactivity is excreted in faeces and urine in 4 days, and only negligible amounts of this radioactivity consist of unchanged ³H-papaverine; most of the radioactivity is recovered in the faeces in the first 24 hr.After an intravenous dose of ³H-papaverine, about 70 per cent of the tritium is excreted in the bile in 6 hr. All this radioactivity is due to conjugated metabolites, which after hydrolysis with glusulase, give five peaks on thin layer chromatograms. After intraduodenal administration of these conjugated metabolites, a very small absorption occurs, while after administration of the hydrolysed metabolites about 60 per cent of the dose is excreted in the bile. After intramuscular injection of ³H-papaverine radioactivity in the intestine follows quite good the time pattern of excretion of tritium in the bile. No significant difference was observed between control and bile cannulated rats with regard to the blood levels of radioactivity and ³H-papaverine. These results suggest that the bile is the main route of excretion of papaverine metabolites and that enterohepatic circulation of these metabolites is not important.     

Biliary excretion of arsenic in rats,rabbits, and dogs

The disappearance of ⁷⁴As from blood and plasma of rats and its excretion into bile was measured for 2 hr after the iv administration of 0.01, 0.46, 1.0, 2.1, and 4.6 mg/kg of arsenic given as the trichloride. Arsenic disappearance from plasma was biphasic; the half-life during the late phase was greater than 2 hr. Even though the arsenic was injected iv, the concentration in the blood increased through the first 2 hr. Arsenic was rapidly excreted into the bile, reaching its highest rate of excretion 6 min after administration, after which it rapidly decreased. This rapid decrease in excretion is due to redistribution of arsenic from the liver to the blood. Arsenic enters bile against an apparent bile/plasma concentration gradient of 630, 8 min after 1 mg/kg of arsenic. At this time the liver/plasma gradient is 17 and the liver/bile gradient is 37. Twenty-five percent of the arsenic administered to bile duct-cannulated rats is excreted into the bile within 2 hr. However, less than 10% of the administered dose is excreted into the feces of intact rats over a 7-day period. In the rabbit and dog, arsenic is excreted into the bile at a much slower rate. These data demonstrate that arsenic is excreted into the bile, and this occurs against a large bile/plasma concentration gradient in rats, suggesting excretion by an active transport mechanism. However, the overall importance of bile as a route of elimination for arsenic is minimized due to enterohepatic circulation and species variations in its biliary excretion rate.     

Disposition of the radioprotector ethiofos in the rhesus monkey. Influence of route of administration

Plasma concentrations of ethiofos [S-2-(3-aminopropylamino)ethyl phosphorothioic acid, WR-2721] were compared following iv, ip, intraduodenal, and portal administration to the rhesus monkey. Plasma samples were analyzed for ethiofos, free WR-1065, [2-(3-aminopropylamino)ethanethiol], and total material convertible to WR-1065 (total WR-1065). In separate experiments, total radioactivity in plasma was compared following iv, ip, and intraduodenal administration of [14C]ethiofos; excretion of the radiolabel was measured in urine and in feces. Intraduodenal administration of unlabeled ethiofos rarely gave measurable levels of unchanged drug in plasma. In contrast, intraduodenal administration of [14C]ethiofos produced an average AUC for total radioactivity that was 62% of that for a 10-min iv infusion of [14C]ethiofos. Urinary excretion of radioactivity following iv and intraduodenal administration of [14C]ethiofos was 78.9 +/- 14.0% and 43.8 +/- 12.4%, respectively, whereas 1.9 +/- 0.5% and 9.7 +/- 6.3% was excreted in feces. After an ip dose of either labeled or unlabeled ethiofos, absorption of the dose was prolonged, but AUC values for total radioactivity or ethiofos and total WR-1065 were similar to those observed after the corresponding 10-min iv experiments. For either iv or portal routes, increases in ethiofos AUC values were observed for the same total dose when the infusion rate was increased from 1.25 to 15 mg/kg/min.(ABSTRACT TRUNCATED AT 250 WORDS)     

Metabolic disposition and irreversible binding of 1-phenylcyclohexene in rats

The metabolic disposition of l-[¹⁴C]phenylcyclohexene ([¹⁴C]PC) was examined in rats after ip or iv drug administration. Radioactivity, which was accumulated by various organs, peaked within 30 min after ip administration of [¹⁴C]PC (0.21 mg/kg). A significant amount of this radioactivity was not extractable by repeated methanol extractions, indicating irreversible binding of [¹⁴C]PC metabolite(s) to tissue proteins. Following iv administration of [¹⁴C]PC (0.42 mg/kg), [¹⁴C]PC concentrations in blood declined biphasically with time; the blood elimination half-life of [¹⁴C]PC is 77 min. About 83% of the dose given was excreted in urine and feces within 54 hr of administration. About 35% of the dose was excreted in the bile in 1 hr. At least four [¹⁴C]PC metabolites were detected in the urine or bile. The bulk of the urinary radioactivity was composed of metabolites since less than 6% of [¹⁴C]PC given was excreted unchanged in the urine.     

Absorption and excretion of suprofen in rats

DL-2-(4-(2-Thienylcarbonyl)phenyl)propionic acid (suprofen, S) was rapidly absorbed in rats after oral administration. Blood levels after a single oral dose of 2, 10, 50, or 100 mg/kg of 3H-S reached maxima within 30 min and were dose-dependent. The major portion of the drug was shown to be absorbed from the upper part of the small intestine and a portion from the stomach. The radioactivity in rat plasma was extensively bound to the plasma protein in vivo; this was found to be unchanged S and four metabolites. Elimination of S and its metabolites from blood was rapid; 3H was mostly excreted in the urine and feces within 24 hr after oral administration of 3H-S. No significant amounts of 14CO2 were excreted in expired air after administration of 14C-S. Rat urine contained S and four metabolites found in rat plasma, accounting for about 60% of the urinary radioactivity. After rats with biliary fistulas were given an oral dose of 2 mg/kg of 3H-S, 41% of the dose was excreted in the bile during 48 hr; there was significant enterohepatic circulation. When single or 21 consecutive daily doses of 3H-S were administered to rats, the blood levels after the multiple doses were higher than those after a single dose but no significant difference was found in excretion of 3H.