Metabolism of N tau-methylhistidine by mice.

Mice and rats were injected with tracer doses of radioactive N tau-[Me-14C]methylhistidine in order to determine the recovery of the injected radioactivity and the extent of the metabolism of N tau-methylhistidine. In the first 27 h after injection, 96.3, 78.0 and 97.5% of radioactivity was excreted by female mice, male mice and male rats respectively. Recovery after 5 days of collection was 98.4 and 92.8% for female and male mice respectively. However, radioactivity associated with N tau-methylhistidine or its acetylated derivative accounted for 44, 86.5 and 96.0% of the excreted radioactivity for female mice, male mice and rats respectively. In female mice the remaining excreted radioactivity was associated with four major peaks of activity when the metabolites were separated by cation-exchange chromatography. In male mice there were only three of these metabolites present. After chromatographic purification, one metabolite was identified by mass spectroscopy to be 1-methylimidazole-4-acetic acid. Examination of the possible sources of this metabolite indicates that, in mice, N tau-methylhistidine is decarboxylated and enters the chain of reactions common to histamine metabolism. Such extensive metabolism precludes the use of N tau-methylhistidine excretion as an index of myofibrillar protein breakdown in mice.     

The biotransformation and urinary excretion of dexamethasone in equine male castrates

The pro-drugs of dexamethasone, a potent glucocorticoid, are frequently used as anti-inflammatory steroids in equine veterinary practice. In the present study the biotransformation and urinary excretion of tritium labelled dexamethasone were investigated in cross-bred castrated male horses after therapeutic doses. Between 40-50% of the administered radioactivity was excreted in the urine within 24 h; a further 10% being excreted over the next 3 days. The urinary radioactivity was largely excreted in the unconjugated steroid fraction. In the first 24 h urine sample, 26-36% of the total dose was recovered in the unconjugated fraction, 8-13% in the conjugated fraction and about 5% was unextractable from the urine. The metabolites identified by microchemical transformations and thin-layer chromatography were unchanged dexamethasone, 17-oxodexamethasone, 11-dehydrodexamethasone, 20-dihydrodexamethasone, 6-hydroxydexamethasone and 6-hydroxy-17-oxodexamethasone together accounting for approx 60% of the urinary activity. About 25% of the urinary radioactivity associated with polar metabolites still remains unidentified.     

The metabolic fate of chlormadinone acetate in the baboon.

The metabolic fate of chlormadinone acetate (17alpha-acetoxy-6-chloro-4, 6-pregnadiene-3, 20-dione; CAP) was studied in intact and biliary fistula baboons. The steroid was labeled with 3H at position 1 and with 14C at the carboxyl moiety of the 17alpha-acetate, thus affording the opportunity to ascertain the loss of the 17alpha-acetoxy group and the fate of both labels. The averages of the radioactivity excreted, given as percentages of the amounts injected, and the standard deviations were as follows: In the urine of intact animals after 6 hours, 5.7 +/- 0.2% and 5.5 +/- 0.7% of the 3H and 14C were recovered, respectively. After 6 days, there was 17.5% of the 3H and 16.2% of the 14C in the urine plus 15.3% of the 3H and 16.4% of the 14C in the feces. In baboons with biliary fistulas, the total radioactivity excreted was 7.8 +/- 0.7% of the 3H and 11.6% of the 14C in the urine, and 30.9 +/- 4.4% of the 3H and 30.7% of the 14C in the bile after 6 hours. Glucosiduronates were the predominant conjugates in the urine and bile. The similarity in the urinary excretion of radioactivity in the first 6 hours in intact and biliary fistula animals, the relatively low excretion of radioactivity in the bile and after 6 days in the urine, and the low fecal excretion suggest that the metabolites of CAP are not involved in an extensive enterohepatic circulation in the baboon. Deacetylation of the 17alpha-acetate in CAP was detected in the early collection periods of the urine and bile and constituted a very small percentage of the injected compound. No significant oxygenation of CAP at position 1 was detected. The metabolism of CAP is discussed and compared to our previously reported data on the metabolism of progesterone, ethynodiol diacetate and medroxyprogesterone acetate and the data on other progestogens reported in the literature. It appears that the excretion of CAP is significantly slower in the baboon than that of the other progestogens. The amounts of glucosiduronates of CAP and/or its metabolites formed in vivo are less than those formed with the other progestogens. Also, the extent of deacetylation of the 17alpha-acetate of CAP is much less than that of the 3beta-acetate of ethynodiol diacetate.     

Studies on flavonoid metabolism. Biliary and urinary excretion of metabolites of (+)-[U-14C]catechin

1. The biliary and urinary excretion of (+)-[U-(14)C]catechin was studied in normal male rats after a single injection of the flavonoid. 2. In rats large amounts of radioactivity (33.6-44.3% of the dose in 24h) were excreted in the bile as two glucuronide conjugates [one of which was a (+)-catechin conjugate] and three other unconjugated metabolites. 3. Excretion of radioactivity in the urine when the bile duct was not cannulated amounted to 44.5% of the dose. 4. In both the urine and bile the new metabolites showed maximum excretion in the (1/2)-1(1/2)h after intravenous injection of [(14)C]catechin. 5. The metabolites m-hydroxyphenylpropionic acid, p-hydroxyphenylpropionic acid, delta-(3-hydroxyphenyl)-gamma-valerolactone and delta-(3,4-dihydroxyphenyl)-gamma-valerolactione originate from the action of the intestinal micro-organisms on the biliary-excreted metabolites of (+)-catechin. These phenolic acid and lactone metabolites are then reabsorped and excreted in the urine. 6. It is proposed that, depending on the route of administration of (+)-catechin, there exists an alternative pathway, involving biliary excretion, for the metabolism of (+)-catechin.     

Metabolism of intravenously administered 7 alpha-hydroxycholesterol-3 beta-stearate in the hamster.

In order to investigate the metabolic fate of serum esterified 7 alpha-hydroxycholesterol, [4-14C]7 alpha-hydroxycholesterol-3 beta-stearate was synthesized from labeled cholesterol and administered to bile fistula hamsters intravenously. Bile samples were collected at every 20 min for 7 h. Radioactivity was detected in bile 40 min after the beginning of the infusion of the labeled compound and 56.5 +/- 5.7% (48.7-66.0%) of the administered radioactivity was recovered in bile during 7 h. The liver contained appreciable radioactivity (19.5 +/- 7.6% of the administered dose) at the time of sacrifice. Only a trace amount of radioactivity was detected in urine and blood. Cumulative recovery of the radioactivity was 76.3 +/- 8.6% (63.3-90.4%). Major radioactive metabolites in the bile samples were identified to be taurine- and glycine-conjugated cholic acid and chenodeoxycholic acid by radioactive thin-layer chromatographic analysis of the bile samples before and after enzymatic hydrolysis and 3 alpha-hydroxysteroid dehydrogenase treatment. The conversion was nearly complete and we could not detect neutral metabolites, such as the mother compound, free 7 alpha-hydroxycholesterol and bile alcohols, as well as glucuronidated or sulfated bile acids. It is concluded that serum esterified 7 alpha-hydroxycholesterol could be effectively taken up by the liver, hydrolyzed by cholesterol esterase and metabolized via the normal biosynthetic pathway to taurine- or glycine-conjugated primary bile acids to be excreted into bile.     

Kinetics of phenazepam-14C excretion from the body of white rats in the single and prolonged administration of the preparation]

During 5 days after intraperitoneal injection of 14C-phenazepam into albino rats, about 77% of the total radioactivity was excreted with urine and feces in both intact animals and in those premedicated with phenazepam for 15 days. The excretory processes are described by the first order equations. The rates of phenazepam total excretion are identical in single and repeated injections. At the same time, phenazepam injected into the animals at a single dose is predominantly excreted with urine, while in multiple administration it is excreted with feces. Excretion of phenazepam with urine acquires the biexponential features, provided it is injected in multiple doses.     

Excretion of cholate glucuronide

[3-3H]Cholic acid glucuronide [7 alpha,12 alpha-dihydroxy-3 alpha-O-(beta-D-glucopyranosyluronate)-5 beta- cholan-24-oate] was synthesized and administered to rats prepared with either an external biliary fistula or a ligated bile duct. When bile fistula animals were given either microgram or milligram amounts of the glucuronide, biliary secretion of label was rapid and efficient: greater than 90% of the administered label was secreted within 60 min and total recovery of label in bile was 98.6 +/- 1.2%. Studies in which [14C]taurocholate was included in the dose indicated that this bile acid was secreted into bile significantly more rapidly than was the glucuronide. In animals with ligated bile ducts, urinary excretion was the major route of elimination: after 20 hr, 83.4 +/- 9.3% of the administered dose had been excreted in urine. Urinary excretion of cholate glucuronide was significantly more rapid than that of taurocholate. Gas-liquid chromatographic analysis of the methyl ester acetate derivatives of labeled compounds isolated from bile and urine by chromatography established that the bulk (greater than 70%) of the administered material was secreted in bile or excreted in urine as the intact cholate glucuronide. From these results, we conclude that the glucuronidation of cholic acid produces a derivative which is rapidly and effectively cleared from the circulation and excreted.     

Steroid metabolism in the rabbit: Biliary and urinary excretion of metabolites of [4-14C]testosterone

1. [4-(14)C]Testosterone was administered to anaesthetized male and female New Zealand White rabbits as a single injection or as a 45-60min. infusion. 2. After a single dose a total of approx. 56-80% of the radioactivity was excreted in bile and urine. After infusion total recovery of radioactivity was approx. 63-75%. 3. The mean ratio of metabolites in urine to those in bile was 0.77+/-0.41 (range 0.3-1.5). 4. Bile and urine samples were hydrolysed successively by beta-glucuronidase, cold acid and hot acid. In both bile and urine neutral metabolites extracted by ethyl acetate-ether were found mainly after beta-glucuronidase hydrolysis, but a considerable proportion of the dose was converted into substances not extractable from alkaline aqueous solution after all forms of hydrolysis used.     

Studies on the metabolism of testosterone trans-4-n-butylcyclohexanoic acid in the cynomolgus monkey, Macaca fascicularis

Metabolism of intravenously administered testosterone trans-4-n-butylcyclohexanoate (T bucyclate), a potent, long-acting androgen, was studied in cynomolgus monkeys (Macaca fascicularis). About 5% of the radioactivity of a dose of doubly labeled ester (¹⁴C, ³H) was excreted via the gastrointestinal tract. Most of the administered radioactivity was excreted in the urine within 120 h. No intact T bucyclate was recovered from either compartment. Tritium attributed to bucyclic acid and its metabolites was excreted rapidly (peak excretion was at 6 h after injection), while ¹⁴C excretion, attributed to testosterone and its metabolites, extended over 4 days. Testosterone metabolites were excreted predominantly as sulfate esters. Analysis of urinary products derived from the bucyclic acid moiety of T bucyclate showed no products susceptible to glucuronidase treatment, and showed a mixture of unidentified solvolyzable and unconjugated products. No unmetabolized trans-4-n-butylcyclohexanoic acid was detected in urine or feces. It is concluded that metabolism of testosterone bucyclate is initiated in vivo in cynomolgus monkeys by hydrolysis of ester to testosterone and bucyclic acid. The bucyclate side chain is rapidly cleared, and the testosterone is retained in the circulation.     

On the enterohepatic cycle of triiodothyronine in rats; importance of the intestinal microflora

Until 70 h after a single iv injection of 10 uCi [125I]triiodothyronine (T3), normal rats excreted 15.8 +/- 2.8% of the radioactivity with the feces and 17.5 +/- 2.7% with the urine, while in intestine-decontaminated rats fecal and urinary excretion over this period amounted to 25.1 +/- 7.2% and 23.6 +/- 4.0% of administered radioactivity, respectively (mean +/- SD, n = 4). In fecal extracts of decontaminated rats 11.5 +/- 6.8% of the excreted radioactivity consisted of T3 glucuronide (T3G) and 10.9 +/- 2.8% of T3 sulfate (T3S), whereas no conjugates were detected in feces from normal rats. Until 26 h after ig administration of 10 uCi [125I]T3, integrated radioactivity in blood of decontaminated rats was 1.5 times higher than that in normal rats. However, after ig administration of 10 uCi [125I]T3G or [125I]T3S, radioactivity in blood of decontaminated rats was 4.9- and 2.8-fold lower, respectively, than in normal rats. The radioactivity in the serum of control animals was composed of T3 and iodide in proportions independent of the tracer injected, while T3 conjugates represented less than 10% of serum radioactivity. These results suggest an important role of the intestinal microflora in the enterohepatic circulation of T3 in rats.     

Metabolism of sialic acids from exogenously administered sialyllactose and mucin in mouse and rat

A mixture of N-acetyl-[4,5,6,7,8,9-14C]neuraminosyl-alpha (2-3(6]-galactosyl-beta (1-4-glucose[( 14C]sialyl-lactose) and N-acetylneuraminosyl-alpha (2-3(6]-galactosyl-beta(1-4)-glucit-1-[3H]ol(sialyl-[3H]lactitol) as well as porcine submandibular gland mucin labeled with N-acetyl- and N-glycoloyl-[9-(3)H]neuraminic acid were administered orally to mice. The distribution of the different isotopes was followed in blood, tissues and excretion products of the animals. One half of the [14C]sialyl-lactose/sialyl-[3H]lactitol mixture given orally was excreted unchanged in the urine. The other half was hydrolysed by sialidase and partly metabolized further, followed by the excretion of 30% of the 14C-radioactivity as free N-acetyl-[4,5,6,7,8,9-14C]neuraminic acid and 60% of this radioactivity in the form of non-anionic compounds including expired 14CO2 within 24 h. The 14C-radioactivity derived from the [14C]sialyl-lactose/sialyl-[3H]lactitol mixture which remained in the bodies of fasted mice after 24 h was less than 1%. In the case of well-fed mice, a higher amount of the sialic acid residues was metabolized. The bulk of radioactivity of the mucin was resorbed within 24 h. About 40% of the radioactivity administered was excreted by the urine within 48 h; 30% of this radioactivity represented sialic acid and 70% other anionic and non-anionic metabolic products. 60% of the radioactivity administered remained in the body, and bound 3H-labeled sialic acids were isolated from liver. Sialyl-alpha (2-3)-[3H]lactitol was injected intravenously into rats; the substance was rapidly excreted in the urine without decomposition. These studies show that part of the sialic acids bound to oligosaccharides and glycoproteins can be hydrolysed in intestine by sialidase and be resorbed. This is followed either by excretion as free sialic acid or by metabolization at variable degrees, which apparently depends on the compound fed and on the retention time in the digestive tract.     

Quantitation of urinary 3-methylhistidine excretion in growing dogs as an index of in vivo skeletal muscle catabolism

Purpose: To quantitate urinary 3-methylhistidine (3-mh) excretion as an index of in vivo muscle catabolism in dogs fed diets containing either normal or high protein levels.Methods: Twelve male, 5-month-old Beagle dogs were housed individually in metabolism cages and fed a non-meat, purified diet. They were divided into two diet groups of six dogs each, receiving 22.6% (NP) or 41.1% (HP) DM crude protein, respectively. Three dogs from each group received an intravenous injection of 385 +/- 29 kBq [14C] 3-mh. HCl. Urine and feces were collected daily until radioactivity returned to background levels (17 days). Urinary 3-mh was measured using an amino acid analyzer and percentage of bound 3-mh was estimated via acid hydrolysis.Results: Results are reported as means +/- SEM. 3-mh recovery in urine and feces of dogs were 263 +/- 28 kBq and 50.7 +/- 2.2 kBq and 327 +/- 45 kBq and 25.9 +/- 25.9 kBq for the NP and HP groups, respectively. The total cumulative 3-mh recoveries for the NP and HP groups were 81.8% +/- 2.8 and 91.4% +/- 2.7, respectively. Bound 3-mh accounted for 2.1 to 4.8% of urinary 14C-3-mh.Conclusions: Growing Beagle dogs excrete a higher percentage of 3-mh in feces (13.5% vs. 6.7%) when consuming the NP versus the HP diet. It appears that some of the 14C was lost in CO(2) and/or re-circulated in the body, as reported for sheep and pigs. We conclude that urinary 3-mh does not appear to be a quantitative index of in vivo muscle catabolism in growing dogs.     

The synthesis of [14C]streptozotocin and its distribution and excretion in the rat

[(14)C]Streptozotocin was synthesized specifically labelled at three positions in the molecule. The biological activity of synthetic streptozotocin was characterised by studies in vivo of its diabetogenic activity and its dose-response curves. After this characterization the excretion pattern of all three labelled forms of streptozotocin was studied. With [1-(14)C]streptozotocin and [2'-(14)C]streptozotocin the injected radioactivity was excreted (approx. 70% and 80% respectively) mainly in the urine, the greater part of the excretion occurring in the first 6h period; small amounts (approx. 9% and 8% respectively) were found in the faeces. In contrast, with [3'-methyl-(14)C]streptozotocin a much smaller proportion (approx. 42%) of the injected radioactivity was excreted in the urine, the major proportion appearing in the first 6h, whereas approx. 53% of the injected radioactivity was retained in the carcasses. In whole-body radioautographic studies very rapid renal clearance and hepatic accumulation of the injected radioactivity was observed with all three labelled forms of the drug. There was some evidence for biliary and intestinal excretion. Major differences were apparent in the tissue-distribution studies, with each of the three labelled forms, particularly with [3'-methyl-(14)C]streptozotocin. There was no accumulation of [1-(14)C]streptozotocin in the pancreas for the 6h period after administration. However, with [3'-methyl-(14)C]streptozotocin (and also [2'-(14)C]streptozotocin) there was evidence of some pancreatic accumulation after 2h. The results indicate that streptozotocin is subjected to considerable metabolic transformation and to rapid renal clearance. The implication of these suggestions is evaluated with particular reference to the diabetogenic action of streptozotocin.     

Assessment of urine and fecal testosterone metabolite excretion in Chinchilla lanigera males

Endemic chinchilla (Chinchilla spp.) populations are nearly extinct in the wild (South America). In captive animals (Chinchilla lanigera and C. brevicaudata), reproduction is characterized by poor fertility and limited by seasonal breeding patterns. Techniques applied for studying male reproductive physiology in these species are often invasive and stressful (i.e. repeated blood sampling for sexual steroids analysis). To evaluate endocrine testicular function, the present experiments were designed to (a) determine the main route of testosterone excretion (14C-testosterone infusion in four males); (b) validate urine and fecal testosterone metabolite measurements (HPLC was used to separate metabolites and immunoreactivity was assessed in all metabolites using a commercial testosterone radioimmunoassay, and parallelism, accuracy and precision tests were conducted to validate the immunoassay); and (c) investigate the biological relevance of the techniques applied (quantification of testosterone metabolite excretion into urine and feces from five males injected with hCG and comparison between 10 males and 10 females). Radiolabelled metabolites of 14C-testosterone were excreted, 84.7+/-4.2 % in urine and 15.2+/-3.9 % in feces. A total of 82.7+/-4.2% of urinary and 45.7+/-13.6% of fecal radioactivity was excreted over the first 24 h period post-infusion (metabolite concentration peaked at 8.2+/-2.5 h and 22.0+/-7.0 h, respectively). Several urinary and fecal androgen metabolites were separated by HPLC but only fecal metabolites were associated with native testosterone; however, there was immunoreactivity in more than one metabolite derived from 14C-testosterone. After hCG administration, an increase in androgen metabolite excretion was observed (p<0.05). Males excreted greater amounts daily of urinary androgen metabolites as compared with females (p<0.05); this difference was not evident in feces. Results of the present study indicate that the procedure used is a reliable and non-invasive method to repeatedly monitor variations in testicular endocrine activity in this species. It can be a useful tool that would help ensure the survival of the wild populations as well as to provide the basis for a more efficient use by the fur industry.     

The tissue distribution and the pattern of excretion of [14C]-13-labeled 12, 13-epoxytrichothec-9-ene in mice and rats

The distribution in the mouse tissues of 13-[14C]-12,13-epoxtrichothec-9-ene administered intravenously was determined by whole-body autoradiography and by tracing the radioactivity of the tissues oxidized in an Auto Sample Oxidizer. The appearance of the label in urine and feces was also followed by the tracer technique. The distributions of radioactivity in tissues as determined by the two methods were almost identical. On the autoradiograms of mice killed 10 min after the injection, marked blackening of the film was observed at the sites corresponding to the liver, kidney, and bladder with urine, and much less darkening at other sites. The radioactivities contained in the liver, kidney, urine and small intestine were 13.3, 2.3, 2.6 and 10.2% of the dose, respectively. The labeled toxin was rapidly excreted into urine and feces, 56.0 and 4.9% in 6 hr and 66.7 and 28.0% in 24 hr after injection, respectively. Oral administration of the labeled toxin to mother mice resulted in the appearance of radioactivity in the stomach contents of 7-day suckling mice, thus demonstrating indirectly the secretion of the toxin into the milk. An attempt to show a respiratory route of excretion in rats given the radioactive compound orally or intravenously failed to detect any radioactivity in the expired CO2 collected for 6 hr, suggesting that the 14C in the epoxy ring was intact.     

Species variations in the threshold molecular-weight factor for the biliary excretion of organic anions

1. The excretion in the bile and urine after intravenous injection of 16 organic anions having molecular weights between 355 and 752 was studied in female rats, guinea pigs and rabbits. 2. These compounds were mostly excreted unchanged, except for three of them, which were metabolized to a slight extent (<7% of dose). 3. The rat excreted all the compounds extensively (22-90% of dose) in the bile. 4. In guinea pigs four of the compounds with mol.wt. 355-403 were excreted in the bile to the extent of 7-16% of the dose, four with mol.wt. 407-465 to the extent of 25-44% and eight compounds with mol.wt. 479-752 to the extent of 44-100%. 5. In rabbits four compounds with mol.wt. 355-465 were excreted in the bile to the extent of 1-8% of the dose, two compounds with mol.wt. 479 and 495 to the extent of 24 and 22%, and six compounds with mol.wt. 505-752 to the extent of 31-94%. 6. These results, together with those of other investigations from this laboratory, are discussed and the conclusion is reached that there is a threshold molecular weight for appreciable biliary excretion (i.e. more than 10% of dose) of anions, which varies with species: about 325+/-50 for the rat, 400+/-50 for the guinea pig and 475+/-50 for the rabbit. 7. Anions with molecular weights greater than about 500 are extensively excreted in the bile of all three species. 8. That proportion of the dose of these compounds which is not excreted in the bile is excreted in the urine, and in the three species, bile and urine are complementary excretory pathways, urinary excretion being greatest for the compounds of lowest molecular weight and tending to decrease with increasing molecular weight. 9. Some implications of this interspecies variation in the molecular-weight requirement for extensive biliary excretion are discussed.     

Studies of the metabolism of alpha-tocopherol stereoisomers in rats using [5-methyl-(14)C]SRR- and RRR-alpha-tocopherol

We investigated the distribution and metabolism of SRR-alpha-tocopherol (SRR-alpha-Toc), synthetic alpha-Toc compared with RRR-alpha-Toc, in rats after a single oral administration of 2 mg (20 microCi) SRR- and RRR-alpha-[5-methyl-(14)C]Toc. In the liver, there was no difference in the recovery of radioactivity until 12 h after administration, and it reached a maximum of 4.4% of the dose after 12 h, but in other tissues, radioactivity derived from RRR-alpha-Toc was clearly higher than that derived from SRR-alpha-Toc after 12 h. For 96 h after administration, urinary excretions of SRR-alpha-Toc were 7.8% of the dose and significantly greater than that of RRR-alpha-Toc, which was 1.3% of the dose. On the other hand, total fecal excretions of SRR- and RRR-alpha-Toc were 87.6% and 83.0%, respectively. Therefore, radioactivity in the urine was assumed to have transferred out of the liver. Furthermore, the urine samples were hydrolyzed with 3 N methanolic HCl and analyzed by high performance liquid chromatography (HPLC) and liquid chromatography/mass spectrometry. The results showed that about 73% of the total radioactivity injected into HPLC was found to be 2,5,7, 8-tetramethyl-2-(2'-carboxyethyl)-6-hydroxy chroman (alpha-CEHC), as well as RRR-alpha-Toc. Thus, there is no difference between SRR-alpha-Toc and RRR-alpha-Toc in metabolic pathways, and it is suggested that SRR-alpha-Toc discriminated in the liver is rapidly metabolized by the liver and excreted as the conjugate of alpha-CEHC in the urine.     

Metabolic Fate of Sarcosyl-14C-glycine in Normal Young Rats

The metabolic fate of the non-physiological synthetic dipeptide, sarcosyl-[2-¹⁴C]glycine, was investigated in normal young rats in vivo and in vitro compared to that of seryl-[2-¹⁴C]glycine as a typical example of common physiological dipeptides. The radioactive dipeptides were synthesized from sarcosine or L-serine and [2-¹⁴C]glycine in our laboratory. When radioactive sarcosylglycine was given intraperitoneally, about 30% of the dose was excreted in the urine, and more than 90% of the urinary radioactivity was present in the sarcosylglycine fraction. The recovery of radioactivity in the the expired carbon dioxide and body protein was 8 and 50% of the dose, respectively, during a 24-h period. When the labeled serylglycine was given, the recovery of radioactivity in the urine was 8% of the dose, and 15% in the expired carbon dioxide. In slices of the kidney, liver and small intestine from normal rats, serylglycine was rapidly and almost completely hydrolyzed, and a large amount of free glycine was released. However, sarcosylglycine was hardly hydrolyzed to the corresponding amino acids in the liver and small intestine, and only slightly in the kidney. These results suggest that a considerable amount of sarcosylglycine given intraperitoneally was rapidly excreted into the urine of normal young rats, reflecting less sensitivity to hydrolysis by tissue peptidase(s) when compared to serylglycine.     

The kinetics of papillotoxic doses of 3H-N-phenylanthranilic acid in rats

N-phenylanthranilic acid (N-PAA; 4 mmol/kg/day p.o.) causes a diffuse renal papillary necrosis and a polyuria in 7 days. A single dose of 3H-N-PAA was widely distributed with second-order elimination kinetics, t1/2 +/- 50 h for stomach, heart, kidney, and bladder and t1/2 greater than or equal to 90 h for liver, spleen, muscle and lung. The estimated plasma t1/2 = 10.2 h, and over 75% was excreted via urine in 36 h and 13% via faeces in 72 h. In chronically cannulated animals 29% of N-PAA-derived material was in bile and 24% in urine at 36 h, which suggests enterohepatic circulation. Bile and urine contained several metabolites but no parent compound. Multiple doses for 8 and 16 days increased urinary N-PAA excretion to 90% in 36 h, but faecal contents decreased to 6-8% in 72 h and plasma t1/2 to less than or equal to 7.5 h.     

Steroid metabolism in the cat. Biliary and urinary excretion of metabolites of [4-14C]cortisone

1. [4-(14)C]Cortisone was administered to anaesthetized male cats as a single injection or as a 45-60min. infusion. 2. After the single dose a total of 69.6-89.6% of the radioactivity was excreted in bile, and 0.5-7.1% in urine. After infusion total recovery in bile was 73.4-92.1%, and 1.2-1.7% in urine. 3. When bile and urine samples were hydrolysed successively by beta-glucuronidase, cold acid and hot acid, most of the radioactivity was converted into substances not extractable from neutral aqueous solution by ethyl acetate-ether. 4. In bile, metabolites hydrolysable by beta-glucuronidase were found in only small proportions (3-4%) of the dose.