Absorption,distribution, metabolism and excretion of molidustat in healthy participants

The absorption, distribution, metabolism and excretion of molidustat were investigated in healthy male participants. In study 1, a mass balance study, radiolabelled molidustat 25 mg (3.57 MBq) was administered as an oral solution (n = 4). Following rapid absorption, molidustat‐related radioactivity was predominantly distributed in plasma rather than in red blood cells. The total recovery of the administered radioactivity was 97.0%, which was mainly excreted renally (90.7%). Metabolite M‐1, produced by N‐glucuronidation, was the dominant component in plasma (80.2% of the area under the concentration‐time curve for total radioactivity) and was primarily excreted via urine (~85% of dose). Only minor amounts of unchanged molidustat were excreted in urine (~4%) and faeces (~6%). Study 2 investigated the absolute bioavailability and pharmacodynamics of molidustat (part 1, n = 12; part 2, n = 16). Orally administered molidustat immediate release tablets had an absolute bioavailability of 59%. Following intravenous administration (1, 5 and 25 mg), total body clearance of molidustat was 28.7‐34.5 L/h and volume of distribution at steady state was 39.3‐50.0 L. All doses of molidustat transiently elevated endogenous erythropoietin levels, irrespective of the route of administration. Molidustat was considered safe and well tolerated at the administered doses.     

Disposition of the hypolipidaemic agent, 2,3-dihydrophthalazine-1,4-dione, in Sprague Dawley rats

The disposition of [14C]2,3-dihydrophthalazine-1,4-dione, a potent hypolipidaemic agent, has been determined after both intravenous and oral administration. Both the routes of administration afforded multi-exponential disposition with an estimated t1/2 of approximately 75 h. After oral administration, the drug was observed to be absorbed rapidly from the intestine and distributed quickly to all tissues of the body. A large quantity of the 14C-radioactivity was found in the skin and carcass. Approximately 35% of the administered radioactivity was excreted in urine after oral administration and 11% in the faeces. Approximately 66% of the radioactivity excreted in urine was the parent drug. There was evidence of an additional metabolite which accounted for 28% of the urinary radioactive excretion. The parent drug has little serum protein binding, is highly water soluble, and is probably taken up by cells by passive diffusion.     

Absorption,metabolism and excretion after oral administration of a new Ca antagonist, 14C-benidipine hydrochloride to man

1. In healthy male volunteers, the absorption, metabolite profiles and excretion of Cbenidipine hydrochloride, a new Ca antagonist, were investigated after oral administration at a dose of 8?mg. 2. C-benidipine hydrochloride was rapidly absorbed, and the plasma concentration of radioactivity and unchanged drug reached a maximum of 71 2 ng eq. ml at 1 1?h and 2 56 ng ml at 0 6?h respectively, and then declined bi-exponentially. The half-life in the elimination phase was 14 7 and 5 3?h respectively. AUC of unchanged drug was low, about 1% of that of radioactivity. 3. Five days after administration,36 4% of the administered radioactivity was excreted in urine and 58 9% in faeces. 4. The metabolite profiles in plasma, urine and faeces were analysed by hplc. At 1?h after administration the predominant metabolites in plasma were M9 and M2, which accounted for 13 8 and 8 2% of the radioactivity respectively, whereas unchanged drug represented 1 2%. Predominant metabolites in urine 12?h after administration were M3 andM8,whichaccountedfor2 22and2 21%oftheadministeredradioactivityrespectively. Metabolites excreted in faeces 120?h after administration were very complex and poorly separated by hplc and could not be characterized: unchanged drug was not detected in the faeces.     

The disposition and metabolism of zibotentan (ZD4054): an oral-specific endothelin A receptor antagonist in mice, rats and dogs

Zibotentan (ZD4054) is an oral-specific endothelin A receptor antagonist in development for the treatment of castration-resistant prostate cancer. In a number of preclinical studies, the disposition and metabolism of zibotentan were investigated in mice, rats and dogs. Following oral and intravenous administration, zibotentan was slowly absorbed (maximal concentration at approximately 4 h) and rapidly excreted, with the majority being eliminated by 48 h. The main route of elimination was via the urine in dogs and female rats, but via the faeces in male rats and mice of both sexes. Zibotentan was moderately bound to plasma proteins of all species examined (55-95%), and widely distributed throughout all tissues with the highest concentrations seen in the organs of excretion. Zibotentan was moderately metabolised. Zibotentan was well absorbed, moderately bound to plasma proteins, widely distributed and excreted predominantly via the urine.     

Absorption, distribution and excretion of the new thienopyridine agent prasugrel in rats

Prasugrel is converted to the pharmacologically active metabolite after oral dosing in vivo. In this study, (14)C-prasugrel or prasugrel was administered to rats at a dose of 5 mg kg(-1). After oral and intravenous dosing, the values of AUC(0-infinity) of total radioactivity were 36.2 and 47.1 microg eqx h ml(-1), respectively. Oral dosing of unlabeled prasugrel showed the second highest AUC(0-8) of the active metabolite of six metabolites analyzed. Quantitative whole body autoradiography showed high radioactivity concentrations in tissues for absorption and excretion at 1 h after oral administration, and were low at 72 h. The excretion of radioactivity in the urine and feces were 20.2% and 78.7%, respectively, after oral dosing. Most radioactivity after oral dosing was excreted in bile (90.1%), which was reabsorbed moderately (62.4%). The results showed that orally administered prasugrel was rapidly and fully absorbed and efficiently converted to the active metabolite with no marked distribution in a particular tissue.     

Pharmacokinetics and metabolism of the anti-oestrogen droloxifene in female human subjects

1. Single oral doses of a solution formulation of 14 C-droloxifene citrate (141?mg) appeared to be rapidly and well absorbed in four post-menopausal female subjects. Peak plasma concentrations (C max) of total 14 C (1260 ng eq. ml -1), droloxifene (196 ng ml -1) and the major metabolite droloxifene glucuronide (851ng eq. ml -1) occurred at 0.9-1.1h (T max) and declined bi-exponentially with terminal half-lives of 45.0, 31.6 and 32.0h respectively. The mean AUCs of droloxifene and the major metabolite were 21 and 37% respectively that of total 14 C. 2. Total 14 C was excreted slowly, mainly in the faeces. Mean totals of 6.6 and 90.3% of the dose were excreted in the urine and faeces respectively during 11 days. The data were consistent with biliary excretion and enterohepatic circulation of the major metabolite, droloxifene glucuronide. 3. GC-MS showed that the major 14 C-components in 0-24-h urine were droloxifene (mean 0.4% dose) and its glucuronide (2.3% dose), and in faeces were droloxifene (60.2% dose) and N- desmethyldroloxifene (4.2% dose). Other components in faeces corresponded chromatographically to reference standards, droloxifene N -oxide (1.9% dose), side-chain hydroxylated droloxifene (dimethylamine moiety of droloxifene side-chain replaced by hydroxyl, 1.3% dose) and droloxifene glucuronide (10.7% dose). The latter was resistant to enzymic hydrolysis by the β -glucuronidase used. 4. Intersubject variability in the pharmacokinetics of droloxifene in this study was relatively low (CV < 20% for AUC and half-life).     

Metabolism and disposition of 2,2',4,4',5-pentabromodiphenyl ether (BDE99) following a single or repeated administration to rats or mice

The metabolism and disposition of 14C-labelled 2,2',4,4',5-pentabromodiphenyl ether (BDE99) were studied in F344 rats and B6C3F1 mice. Approximately 85% of a 1 micromol kg-1 oral dose was absorbed by male rats and mice. Within 24 h following oral doses ranging from 0.1 to 1000 micromol kg-1 to rats, 39-47% of the dose was excreted in the faeces (including 16% unabsorbed), up to 2% was excreted in the urine, and 34-38% remained in the tissues, mostly in adipose tissue. Mice excreted more in the urine and less in the faeces than rats. Tissue accumulation was observed following repeated dosing to rats. Two dihydrohydroxy-S-glutathionyl and two S-glutathionyl conjugates of BDE99, 2,4,5-tribromophenol glucuronide, two mono-hydroxylated BDE99 glucuronides, and three mono-hydroxylated tetrabromodiphenyl ether glucuronides were identified in male rat bile. 2,4,5-Tribromophenol and its glucuronide and sulfate conjugates, were identified in male rat urine. 2,4,5-Tribromophenol, one mono-hydroxylated tetrabromodiphenyl ether, and two mono-hydroxylated BDE99 were characterized in male rat faeces. BDE99 undergoes more extensive metabolism than does BDE47. Half of the absorbed oral dose in male rats was excreted in 10 days mostly as metabolites derived from arene oxide intermediates.     

Biotransformation of BOF-4272, a sulfoxide-containing drug, in the cynomolgus monkey.

BOF-4272, (+/-)-8-(3-methoxy-4-phenylsulfinylphenyl) pyrazolo[1,5-a]-1,3,5-triazine-4(1H)-one), is a new drug intended for the treatment of hyperuricemia. This report describes the pharmacokinetics and detailed metabolic pathways of BOF-4272 in the cynomolgus monkey, which were investigated using the metabolites found in plasma, urine, and faeces after intravenous and oral administration. M-4 was the main metabolite in plasma after intravenous administration. M-3 and M-4 were the main metabolites in plasma after oral administration. The Cmax and AUC(0-t) of M-4 were the highest of all the metabolites after intravenous administration. The Cmax and AUC(0-t) of M-3 were the highest of all the metabolites, and those of M-4 were the second highest, after oral administration. M-4 and M-3 were the main metabolites detected in urine and faeces, respectively, after intravenous administration, with M-4 and M-3 at 47.2% in urine and 19.1% in faeces, respectively, within 120 h after administration. M-4 was the only metabolite detected in urine after oral administration, at about 5% within 120 h after administration. M-3 was detected in faeces at 17.0% within 120 h after oral administration. These results suggest that, in the cynomolgus monkey, BOF-4272 is rapidly biotransformed to a main metabolite (M-4, a sulphoxide-containing metabolite of BOF-4272) and that M-4 is mainly excreted in urine and possibly also in bile, with subsequent conversion to M-3 by the intestinal flora. It is expected that the biotransformation of BOF-4272 would be similar in healthy human volunteers.     

Absorption,metabolism and excretion of darexaban (YM150), a new direct factor Xa inhibitor in humans

1.?The absorption, metabolism and excretion of darexaban (YM150), a novel oral direct factor Xa inhibitor, were investigated after a single oral administration of [¹⁴C]darexaban maleate at a dose of 60?mg in healthy male human subjects.

2.?[¹⁴C]Darexaban was rapidly absorbed, with both blood and plasma concentrations peaking at approximately 0.75?h post-dose. Plasma concentrations of darexaban glucuronide (M1), the pharmacological activity of which is equipotent to darexaban in vitro, also peaked at approximately 0.75?h.

3.?Similar amounts of dosed radioactivity were excreted via faeces (51.9%) and urine (46.4%) by 168?h post-dose, suggesting that at least approximately half of the administered dose is absorbed from the gastrointestinal tract.

4.?M1 was the major drug-related component in plasma and urine, accounting for up to 95.8% of radioactivity in plasma. The N-oxides of M1, a mixture of two diastereomers designated as M2 and M3, were also present in plasma and urine, accounting for up to 13.2% of radioactivity in plasma. In faeces, darexaban was the major drug-related component, and N-demethyl darexaban (M5) was detected as a minor metabolite.

5.?These findings suggested that, following oral administration of darexaban in humans, M1 is quickly formed during first-pass metabolism via UDP-glucuronosyltransferases, exerting its pharmacological activity in blood before being excreted into urine and faeces.     

Absorption,distribution, metabolism and excretion of telmesteine,a mucolitic agent,in rat

1. The metabolism and disposition of telmesteine, a muco-active agent, have been investigated following single oral or intravenous administration of (14)C-telmesteine in the Sprague-Dawley rat. 2. (14)C-telmesteine was rapidly absorbed after oral dosing (20 and 50 mg kg(-1)) with an oral bioavailability of >90% both in male and female rats. The C(max) and area under the curve of the radioactivity in plasma increased proportionally to the administered dose and those values in female rats were 30% higher than in male rats. 3. Telmesteine was distributed over all organs except for brain and the tissue/plasma ratio of the radioactivity 30 min after dosing was relatively low with a range of 0.1-0.8 except for excretory organs. 4. Excretion of the radioactivity was 86% of the dose in the urine and 0.6% in the faeces up to 7 days after oral administration. Biliary excretion of the radioactivity in bile duct-cannulated rats was about 3% for the first 24 h. The unchanged compound mainly accounted for the radioactivity in the urine and plasma. 5. Telmesteine was hardly metabolized in microsomal incubations. A glucuronide conjugate was detected in the urine and bile, but the amount of glucuronide was less than 6% of excreted radioactivity.     

Systemic exposure to parabens: Pharmacokinetics,tissue distribution,excretion balance and plasma metabolites of [14C]-methyl-, propyl- and butylparaben in rats after oral,topical or subcutaneous administration

Parabens (PB) are preservatives used in food, drugs and personal care products preventing microbial and fungal contamination. We investigated ADME profiles of [¹⁴C]-methyl-, propyl- or butylparaben (MP, PP, BP) following single oral, dermal or subcutaneous (BP) doses at 100 mg/kg to Sprague–Dawley rats. Plasma C_max and AUC values after oral or subcutaneous doses were 4- to 10-fold higher relative to respective values after dermal administration. t_max ranged from 0.5, 2 or 8 h after oral, subcutaneous or dermal administration, respectively. MP produced higher blood C_max and AUC levels relative to those after PP or BP. Following oral or subcutaneous administration, urinary excretion was predominant (>70%, mainly during the first 24 h), less than 4% were eliminated in the feces, 2% were retained in the tissues and carcasses. Following dermal application, >50% of the dose was unabsorbed, 14–27% or <2% were respectively excreted in the urine or feces, respectively. Overall, parabens were well absorbed after oral and subcutaneous, and partially absorbed after dermal administration. All administration routes produced a single peak in the plasma, corresponding to that of para-hydroxybenzoic acid (PHBA) suggesting that PB produce no significant systemic exposure of mammalian organisms after oral, topical or subcutaneous administration.     

The Disposition and Metabolism of Amodiaquine in Small Mammals

1. 7-Chloro-4-(3′-diethylamino-4′-hydroxyanilino)quinoline (amodiaquine) labelled with ¹⁴C has been synthesized and administered in single doses to rats including bile-duct-cannulated rats, to guinea-pigs and to mice, by oral or parenteral routes.

2. Amodiaquine was extensively and rapidly absorbed from the rat intestinal tract. Excretion of total radioactivity from rats and guinea pigs was slow and prolonged and was <50% dose in 9 days. Excretion of ¹⁴C was predominantly in faeces of rats after oral and i.p. dosage, and guinea-pigs after i.p. dosage. Radioactivity in rat and guinea-pig urine was <11% dose.

3. Biliary excretion of ¹⁴C following oral or i.v. dosage to rats was 21% dose in 24?h.

4. Amodiaquine was extensively metabolized and conjugated with <10% dose excreted unchanged in urine or bile. Two major basic metabolites in rat urine were tentatively identified as the mono- and bis-desethyl amines.

5. 7-Chloro-4-(4′-diethyl-1′-methylbutylamino)quinoline (chloroquine) was excreted largely unchanged in urine of rats after oral or parenteral administration of single doses, with <5% dose excreted in rat bile in 24?h.     

Absorption,distribution, metabolism and excretion of telmesteine,amucolitic agent,in rat

1. The metabolism and disposition of telmesteine, a muco-active agent, have been investigated following single oral or intravenous administration of ¹⁴C-telmesteine in the Sprague–Dawley rat.

2. ¹⁴C-telmesteine was rapidly absorbed after oral dosing (20 and 50mg kg^-1) with an oral bioavailability of > 90% both in male and female rats. The C_max and area under the curve of the radioactivity in plasma increased proportionally to the administered dose and those values in female rats were 30% higher than in male rats.

3. Telmesteine was distributed over all organs except for brain and the tissue/plasma ratio of the radioactivity 30min after dosing was relatively low with a range of 0.1–0.8 except for excretory organs.

4. Excretion of the radioactivity was 86% of the dose in the urine and 0.6% in the faeces up to 7 days after oral administration. Biliary excretion of the radioactivity in bile duct-cannulated rats was about 3% for the first 24 h. The unchanged compound mainly accounted for the radioactivity in the urine and plasma.

5. Telmesteine was hardly metabolized in microsomal incubations. A glucuronide conjugate was detected in the urine and bile, but the amount of glucuronide was less than 6% of excreted radioactivity.     

Pharmacokinetics and metabolism of the anti-oestrogen droloxifene in female human subjects

1. Single oral doses of a solution formulation of (14)C-droloxifene citrate (141 mg) appeared to be rapidly and well absorbed in four post-menopausal female subjects. Peak plasma concentrations (C(max)) of total (14)C (1260 ng eq. ml(-1)), droloxifene (196 ng ml(-1)) and the major metabolite droloxifene glucuronide (851 ng eq. ml(-1)) occurred at 0.9-1.1 h (T(max)) and declined bi-exponentially with terminal half-lives of 45.0, 31.6 and 32.0 h respectively. The mean AUCs of droloxifene and the major metabolite were 21 and 37% respectively that of total (14)C. 2. Total (14)C was excreted slowly, mainly in the faeces. Mean totals of 6.6 and 90.3% of the dose were excreted in the urine and faeces respectively during 11 days. The data were consistent with biliary excretion and enterohepatic circulation of the major metabolite, droloxifene glucuronide. 3. GC-MS showed that the major (14)C-components in 0-24-h urine were droloxifene (mean 0.4% dose) and its glucuronide (2.3% dose), and in faeces were droloxifene (60.2% dose) and N- desmethyldroloxifene (4.2% dose). Other components in faeces corresponded chromatographically to reference standards, droloxifene N-oxide (1.9% dose), side-chain hydroxylated droloxifene (dimethylamine moiety of droloxifene side-chain replaced by hydroxyl, 1.3% dose) and droloxifene glucuronide (10.7% dose). The latter was resistant to enzymic hydrolysis by the beta-glucuronidase used. 4. Intersubject variability in the pharmacokinetics of droloxifene in this study was relatively low (CV < 20% for AUC and half-life).     

Pharmacokinetics, metabolism and excretion of an inhibitor of inducible nitric oxide synthase, L-NIL-TA, in dog

1. The pharmacokinetics, metabolism and excretion of L-NIL-TA, an inducible nitric oxide synthase inhibitor, were investigated in dog. 2. The dose of [14C]L-NIL-TA was rapidly absorbed and distributed after oral and intravenous administration (5 mg kg-1), with Cmax of radioactivity of 6.45-7.07 microg equivalents g-1 occurring at 0.33-0.39-h after dosing. After oral and intravenous administration, radioactivity levels in plasma then declined with a half-life of 63.1 and 80.6-h, respectively. 3. Seven days after oral and intravenous administrations, 46.4 and 51.5% of the radioactive dose were recovered in urine, 4.59 and 2.75% were recovered in faeces, and 22.4 and 22.4% were recovered in expired air, respectively. The large percentages of radioactive dose recovered in urine and expired air indicate that [14C]L-NIL-TA was well absorbed in dogs and the radioactive dose was cleared mainly through renal elimination. The mean total recovery of radioactivity over 7 days was approximately 80%. 4. Biotransformation of L-NIL-TA occurred primarily by hydrolysis of the 5-aminotetrazole group to form the active drug L-N6-(1-iminoethyl)lysine (NIL or M3), which was further oxidized to the 2-keto acid (M5), the 2-hydroxyl acid (M1), an unidentified metabolite (M2) and carbon dioxide. The major excreted products in urine were M1 and M2, representing 22.2 and 21.2% of the dose, respectively.     

Absorption, metabolism and excretion of a single oral dose of 14C-repaglinide during repaglinide multiple dosing

Objective: The present study was designed to assess the disposition of ¹⁴C-repaglinide in whole blood, plasma, urine and faeces, and to measure the total recovery of drug-related material in urine and faeces after a single 2-mg oral dose of ¹⁴C-repaglinide during multiple dosing. Methods: In this single-centre, open-label, phase-I trial, six healthy male volunteers received 2 mg of the prandial glucose regulator, repaglinide, four times daily for 13 days, 15 min before meals. On the morning of day 7, breakfast was omitted and the dose was given as an oral solution containing 2 mg of ¹⁴C-repaglinide. Results: After oral dosing, a mean peak plasma concentration of repaglinide of 27.74 ng · ml⁻¹ (range: 16.84–36.65 ng · ml⁻¹) was observed with a time to peak concentration of 0.5 h. Approximately 20% of repaglinide and its associated metabolites were distributed into red blood cells. No measurable ¹⁴C-radioactivity was present in whole blood samples 6 h after dosing. Within 96 h of dosing with ¹⁴C-repaglinide, 90% of the administered dose appeared in the faeces and 8% was excreted in urine. In the plasma, the major compound was repaglinide (61%). In the urine, the major metabolites were unidentified polar compounds, the aromatic amine (M₁) (24%), and the dicarboxylic acid (M₂) (22%). In the faeces, the major metabolite was M₂ (66% of administered dose). Therefore, repaglinide was excreted predominantly as metabolites and the major in vivo metabolite of repaglinide in humans was M₂. During regular dosing for 6 days, the morning plasma trough levels of repaglinide were, with very few exceptions, almost always too low to measure, indicating the absence of accumulation at this dose of 2 mg four times daily. Repaglinide was well tolerated, and there were no episodes of hypoglycaemia. Conclusion: After oral dosing with repaglinide, the mean peak plasma concentration was rapidly attained and, thereafter, plasma concentrations decreased promptly. The major route of excretion was via the faeces. These properties make repaglinide a suitable insulin secretagogue for all patients with type-2 diabetes who retain sufficient β-cell function. Received: 13 January 1999 / Accepted in revised form: 15 June 1999     

Pharmacokinetic characterization of hydroxylpropyl-beta-cyclodextrin-included complex of cryptotanshinone, an investigational cardiovascular drug purified from Danshen (Salvia miltiorrhiza)

1. The study aimed to investigate the pharmacokinetics of cryptotanshinone in a hydroxylpropyl-beta-cyclodextrin-included complex in dogs and rats. 2. Animals were administrated the inclusion complex of cryptotanshinone and the concentrations of cryptotanshinone and its major metabolite tanshinone IIA were determined by a liquid chromatography-tandem mass spectrometry (LC-MS/MS) method. 3. Cryptotanshinone in inclusion complex was absorbed slowly after an oral dose, and the C(max) and AUC(0-)(t) were dose-proportional. The bioavailability of cryptotanshinone in rats was (6.9% +/- 1.9%) at 60 mg kg(-1) and (11.1% +/- 1.8%) in dogs at 53.4 mg kg(-1). The t(1/2) of the compound in rats and dogs was 5.3-7.4 and 6.0-10.0 h, respectively. Cryptotanshinone showed a high accumulation in the intestine, lung and liver after oral administration, while the lung, liver and heart had the highest level following intravenous dose. Excretion data in rats showed that cryptotanshinone and its metabolites were mainly eliminated from faeces and bile, and the dose recovery rate was 0.02, 2.2, and 14.9% in urine, bile, and faeces, respectively. 4. The disposition of cryptotanshinone in an inclusion complex was dose-independent and the bioavailability was increased compared with that without cyclodextrin used to formulate the drug. Cryptotanshinone was distributed extensively into different organs. Excretion of cryptotanshinone and its metabolites into urine was extremely low, and they were mainly excreted into faeces and bile.     

N-[C14]甲酰溶肉瘤素在肿瘤病人的吸收和排泄

精原细胞瘤病人口服N[C¹⁴]-甲酰溶肉瘤素15毫克(约30微居里)后72小时内,C¹⁴自尿及大便的总排出量为剂量的68.0-77.4%;其中由尿及大便所排出的放射性各约半量.尿中的放射性绝大部分为给药后前5小时内排出的,大便中的放射性则主要在给药后48小时(两次大便,便秘患者除外)内排出.在服药后24小时内,血液(全血、血浆及血球)、唾液及呼出的二氧化碳仅有痕迹量放射性存在.口服N-甲C¹⁴的同时,口服大量非标记的N-甲,并未显著地影响C¹⁴的排泄.     

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

1. The excretion and metabolism of enciprazine, an anxiolytic drug, was examined in rat, dog and man.

2. In rats and dogs that received ¹⁴C-enciprazine dihydrochloride orally and by i.v. injection, the drug was well absorbed. Radioactivity was excreted predominantly in the faeces of rats, equally in urine and faeces of dogs, and to a major extent in human urine.

3. Metabolic profiles, which were evaluated in urine and in rat bile, were similar following oral and i.v. dosing to rats and dogs.

4. Unchanged drug was not detected in rat, dog or human excreta. Glucuronide conjugates of 4-hydroxyenciprazine, m-desmethylenciprazine, p-desmethylenciprazine and enciprazine were detected in the excreta of all three species. A glycol metabolite was present only in rat bile and human urine. A metabolite desmethylated in the phenyl ring of the phenylpiperazine moiety also appeared to be present only in human urine.

5. Structural confirmation of the major metabolites in human urine and rat bile was accomplished by?h.p.l.c.-mass spectrometry.     

Pharmacokinetics,metabolism and excretion of an inhibitor of inducible nitric oxide synthase,L-NIL-TA,in dog

1.?The pharmacokinetics, metabolism and excretion of L-NIL-TA, an inducible nitric oxide synthase inhibitor, were investigated in dog.

2.?The dose of [¹⁴C]L-NIL-TA was rapidly absorbed and distributed after oral and intravenous administration (5?mg?kg^?1), with C_max of radioactivity of 6.45–7.07?μg equivalents?g^?1 occurring at 0.33–0.39-h after dosing. After oral and intravenous administration, radioactivity levels in plasma then declined with a half-life of 63.1 and 80.6-h, respectively.

3.?Seven days after oral and intravenous administrations, 46.4 and 51.5% of the radioactive dose were recovered in urine, 4.59 and 2.75% were recovered in faeces, and 22.4 and 22.4% were recovered in expired air, respectively. The large percentages of radioactive dose recovered in urine and expired air indicate that [¹⁴C]L-NIL-TA was well absorbed in dogs and the radioactive dose was cleared mainly through renal elimination. The mean total recovery of radioactivity over 7 days was approximately 80%.

4.?Biotransformation of L-NIL-TA occurred primarily by hydrolysis of the 5-aminotetrazole group to form the active drug L-N6-(1-iminoethyl)lysine (NIL or M3), which was further oxidized to the 2-keto acid (M5), the 2-hydroxyl acid (M1), an unidentified metabolite (M2) and carbon dioxide. The major excreted products in urine were M1 and M2, representing 22.2 and 21.2% of the dose, respectively.