Disposition and metabolism of TAK-438 (vonoprazan fumarate), a novel potassium-competitive acid blocker,in rats and dogs

1.?Following oral administration of [¹⁴C]TAK-438, the radioactivity was rapidly absorbed in rats and dogs. The apparent absorption of the radioactivity was high in both species.

2.?After oral administration of [¹⁴C]TAK-438 to rats, the radioactivity in most tissues reached the maximum at 1-hour post-dose. By 168-hour post-dose, the concentrations of the radioactivity were at very low levels in nearly all the tissues. In addition, TAK-438F was the major component in the stomach, whereas TAK-438F was the minor component in the plasma and other tissues. High accumulation of TAK-438F in the stomach was observed after oral and intravenous administration.

3.?TAK-438F was a minor component in the plasma and excreta in both species. Its oxidative metabolite (M-I) and the glucuronide of a secondary metabolite formed by non-oxidative metabolism of M-I (M-II-G) were the major components in the rat and dog plasma, respectively. The glucuronide of M-I (M-I-G) and M-II-G were the major components in the rat bile and dog urine, respectively, and most components in feces were other unidentified metabolites.

4.?The administered radioactive dose was almost completely recovered. The major route of excretion of the drug-derived radioactivity was via the feces in rats and urine in dogs.     

Pharmacokinetics of the selective prostacyclin receptor agonist selexipag in rats,dogs and monkeys

1.?This study examined the pharmacokinetics, distribution, metabolism and excretion of the selective prostacyclin receptor agonist selexipag (NS-304; ACT-293987) and its active metabolite MRE-269 (ACT-33679). The compounds were investigated following oral and/or intravenous administration to intact rats, dogs and monkeys, and bile-duct-cannulated rats and dogs.

2.?After oral administration of [¹⁴C]selexipag, selexipag was well absorbed in rats and dogs with total recoveries of over 90% of the dose, mainly in the faeces. Biliary excretion was the major elimination pathway for [¹⁴C]MRE-269 as well as [¹⁴C]selexipag, while renal elimination was of little importance. [¹⁴C]Selexipag-related radioactivity was secreted into the milk in lactating rats.

3.?Plasma was analysed for total radioactivity, selexipag and MRE-269 in rats and monkeys. Selexipag was negligible in rat plasma due to extensive metabolism, and MRE-269 was present in rat and monkey plasma. A species difference was clearly evident when selexipag was incubated in rat, dog and monkey plasma.

4.?Total radioactivity was rapidly distributed to tissues. The highest concentrations were found in the bile duct and liver without significant accumulation or persistence, while there was limited melanin-associated binding, penetration of the blood–brain barrier and placental transfer of drug-related materials.     

Disposition and metabolism of a new benzothiophene antiestrogen in rats,dogs and monkeys

1. A new benzothiophene-derived antiestrogen (LY156758) when orally administered was well absorbed in rats and monkeys while approx. 20% was absorbed in dogs.

2. In the rat the compound was subject to first-pass hepatic metabolism which led to low levels of parent drug in the systematic circulation together with a small amount as the glucuronide conjugate.

3. In monkeys the compound occurred primarily as the glucuronide conjugate of parent drug with very little circulating free drug.

4. The systemic bioavailability of free parent drug in plasma was 39% in rats, 17% in dogs and 5% in monkeys.

5. Excretion of the drug in rats and dogs was primarily via the bile. Approx. 1% of the dose was excreted in the urine of rats and dogs after oral dosing. In rats, at least 50% of an oral dose was excreted in bile as the glucuronide conjugate of parent drug.     

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.     

Formation of a disulfide protein conjugate of the SH-group-containing metabolite (M-I) of esonarimod (KE-298) and its elimination in rats

The reactivity of the thiol moiety of the active main metabolite (M-I) of esonarimod (KE-298), a novel anti-rheumatic agent, was investigated in rats. After repeated oral administration of 14C-KE-298, the radioactivity decreased rapidly and no tendency towards accumulation was found, in marked contrast to other common SH-group-containing drugs. At 30 min after intravenous administration of 14C-M-I to rats, the concentration of the 14C-M-I plasma protein conjugate in plasma was extremely low at 0.143 nmol mL(-1) (0.66% of total plasma radioactivity). The 14C-M-I plasma protein conjugate that formed in rat plasma was mixed disulfide with plasma protein. After intravenous administration of synthetic 14C-M-I plasma protein conjugate to rats, the radioactivity in plasma decreased rapidly, with the terminal half-life at 6.90 h. In-vitro, the 14C-M-I plasma protein conjugate was readily dissociated by the endogenous thiol compounds, cysteine and glutathione. These results suggest that the reactivity of the thiol moiety of M-I is extremely low. Furthermore, the 14C-M-I plasma protein conjugate decreased rapidly in-vivo, which would be related to interaction with endogenous thiol compounds. These properties of M-I are principally responsible for the zero accumulation in rat tissues. KE-298 could therefore be expected to have reduced adverse effects compared with other SH-group-containing anti-rheumatic drugs.     

Disposition and metabolism of amosulalol hydrochloride,a new combined α- and β-adrenoceptor blocking agent,in rats,dogs and monkeys

1. The disposition and metabolism of amosulalol hydrochloride, a combined α- and β-adrenoceptor blocking agent, were studied in rats, dogs and monkeys.

2. After oral administration of [¹⁴C]amosulalol hydrochloride, the plasma concentration of radioactivity reached a maximum at 05 to 1 h in all species and declined with half-lives of about 2 h in both rats and monkeys, and of about 4 h in dogs. The ratios of unchanged drug to total radioactivity in the rat and dog plasma were 8 and 43% at 05 h after administration, respectively. The radioactivity in the rat tissues was high in the liver, kidney, blood and pancreas after oral administration.

3. Following oral dosage, the urinary excretion of radioactivity was 26-34% of the dose in rats, 45% in dogs and 46% in monkeys in 48 h. The biliary excretion after oral dosage amounted to 66% and 41% in rats and dogs, respectively.

4. Six metabolites were isolated and identified from the urine of rats and dogs. They were derived from one or two of the following pathways: I, hydroxylation of the 2-methyl group of the methylbenzenesulphonamide ring; II, demethylation of the o-methoxy group of the methoxyphenoxy ring; III, hydroxylation at the 4 or 5 position of the methoxy-phenoxy ring; IV, oxidative cleavage of the C—N bond yielding o-methoxyphenoxy acetic acid. Moreover, some metabolites were metabolized to glucuronide or sulphate.     

Pharmacokinetics,distribution, and disposition of esaxerenone,a novel,highly potent and selective non-steroidal mineralocorticoid receptor antagonist,in rats and monkeys

1.?Esaxerenone (CS-3150) is a novel non-steroidal mineralocorticoid receptor antagonist. The pharmacokinetics, tissue distribution, excretion, and metabolism of esaxerenone were evaluated in rats and monkeys.

2.?Following intravenous dosing of esaxerenone at 0.1–3?mg/kg, the total body clearance and the volume of distribution were 3.53–6.69?mL/min/kg and 1.47–2.49?L/kg, respectively, in rats, and 2.79–3.69?mL/min/kg and 1.34–1.54?L/kg, respectively, in monkeys. The absolute oral bioavailability was 61.0–127% in rats and 63.7–73.8% in monkeys.

3.?After oral administration of [¹⁴C]esaxerenone, the radioactivity was distributed widely to tissues, with the exception of a low distribution to the central nervous system. Both in rats and in monkeys, following oral administration of [¹⁴C]esaxerenone the main excretion route of the radioactivity was feces.

4.?Five initial metabolic pathways in rats and monkeys were proposed to be N-dealkylation, carboxylation, hydroxymethylation, O-glucuronidation, and O-sulfation. The oxidized metabolism was predominant in rats, while both oxidation and glucuronidation were predominant in monkeys.     

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.     

The comparative disposition and metabolism of dolutegravir,a potent HIV-1 integrase inhibitor,in mice,rats, and monkeys

Abstract

1.?Plasma clearance of dolutegravir, an unboosted HIV-1 integrase inhibitor, was low in rat and monkey (0.23 and 2.12?mL/min/kg, respectively) as was the volume of distribution (0.1 and 0.28?L/kg, respectively) with terminal elimination half-life approximately 6?h. Dolutegravir was rapidly absorbed from oral solution with a high bioavailability in rat and monkey (75.6 and 87.0% respectively), but solubility or dissolution rate limited when administered as suspension.

2.?Dolutegravir was highly bound (>99%) to serum proteins in rat and monkey, similar to binding to plasma and serum proteins in human. Radioactivity was associated with the plasma versus cellular components of blood across all species.

3.?Following oral administration to rats, [¹⁴C]dolutegravir-related radioactivity was distributed to most tissues, due in part to high permeability; however, because of high plasma protein binding, tissue to blood ratios were low. In mouse, rat and monkey, the absorbed dose was extensively metabolized and secreted into bile, with the majority of the administered radioactivity eliminated in feces within 24?h.

4.?The primary route of metabolism of dolutegravir was through the formation of an ether glucuronide. Additional biotransformation pathways: benzylic oxidation followed by hydrolysis to an N-dealkylated product, glucose conjugation, oxidative defluorination, and glutathione conjugation.     

Disposition and metabolism of [14C]lemborexant,a novel dual orexin receptor antagonist,in rats and monkeys

1. The disposition and metabolism of lemborexant, a novel dual orexin receptor antagonist currently under development as a therapeutic agent for insomnia disorder, were evaluated after a single oral administration of [¹⁴C]lemborexant in Sprague-Dawley rats (10?mg/kg) and cynomolgus monkeys (3?mg/kg).

2. In both species, [¹⁴C]lemborexant was rapidly absorbed: radioactivity concentration in blood peaked at 0.83–1.8?h, and decreased with elimination half-life of 110?h. The radioactivity administered was excreted primarily into faeces, with relatively little excreted into urine.

3. Lemborexant was not detected in bile, urine or faeces, indicating that lemborexant administered orally was completely absorbed from the gastrointestinal tract and that the main elimination pathway was metabolism in both species.

4. In rats, lemborexant was found to be minor in plasma (≤5.2% of total radioactivity), and M9 (hydroxylated form) was the major circulating metabolite. In monkeys, the major circulating components were lemborexant, M4 (N-oxide metabolite), M13 (di-oxidised form), M14 (di-oxidised form) and M16 (glucuronide of mono-oxidised form).

5. In both species, lemborexant was metabolised to various metabolites by multiple pathways, the primary of which was oxidation of the dimethylpyrimidine or fluorophenyl moiety.

     

Pharmacokinetics,metabolism and excretion of [14C]-lanicemine (AZD6765), a novel low-trapping N-methyl-d-aspartic acid receptor channel blocker,in healthy subjects

Abstract

1.?(1S)-1-phenyl-2-(pyridin-2-yl)ethanamine (lanicemine; AZD6765) is a low-trapping N-methyl-d-aspartate (NMDA) channel blocker that has been studied as an adjunctive treatment in major depressive disorder. The metabolism and disposition of lanicemine was determined in six healthy male subjects after a single intravenous infusion dose of 150?mg [¹⁴C]-lanicemine.

2.?Blood, urine and feces were collected from all subjects. The ratios of C_max and AUC_(0–∞) of lanicemine to plasma total radioactivity were 84 and 66%, respectively, indicating that lanicemine was the major circulating component with T_1/2 at 16?h. The plasma clearance of lanicemine was 8.3?L/h, revealing that lanicemine is a low-clearance compound. The mean recovery of radioactivity from urine was 93.8% of radioactive dose.

3.?In urine samples, 10 metabolites of lanicemine were identified. Among which, an O-glucuronide conjugate (M1) was the most abundant metabolite (～11% of the dose in excreta). In plasma, the circulatory metabolites were identified as a para-hydroxylated metabolite (M1), an O-glucuronide (M2), an N-carbamoyl glucuronide (M3) and an N-acetylated metabolite (M6). The average amount of each of metabolite was less than 4% of total radioactivity detected in plasma or urine.

4.?In conclusion, lanicemine is a low-clearance compound. The unchanged drug and metabolites are predominantly eliminated via urinary excretion.     

Disposition and metabolism of [14C]PTZ601 in healthy volunteers

1.?Six healthy male subjects were given a single dose of 500 mg of [14C]PTZ601 (mean radioactivity 79.2 μCi) by intravenous (IV) infusion over 1 h, and observed for 5 days post-dose during which pharmacokinetic (PK) samples were collected. Plasma PTZ601 concentrations and metabolite identification were determined using LC-MS/MS; PK parameters were estimated by non-compartmental analysis. Excretion and mass balance were determined with liquid scintillation analysis and metabolites profiling was characterized by HPLC online radiochemical detection.

2.?The disposition of PTZ601 was best described by a fast absorption, followed by a biphasic elimination phase. Peak PTZ601 plasma concentrations were reached within 0.5–1 h. The mean elimination half-life was 1.6 h and clearance was 13 L/h.

3.?Recovery of the radioactivity dose was complete (mean 92%). The main route of excretion (parent and metabolites) was the renal route, as urine accounted for 69–77%, while feces only 13–22%, of the total radioactivity.

4.?The majority of the drug was excreted in urine as multiple open ring metabolites: M17.3 (oxidative ring-opened product) and M22.2 (di-cysteine conjugate of 17.3); unchanged PTZ601 in urine contributed to 15% of radioactivity. The major metabolites detected in plasma were M17.3, M12.8 (acetylated M17.3), M22.2, and M41.4 (methylated M17.3).

5.?PTZ601 was well tolerated.     

Metabolism of the platelet-activating factor antagonist (±)-trans-2-(3′-methoxy-5′-methylsulphonyl-4′-propoxyphenyl)-5-(3″, 4″,5″-trimethoxyphenyl)tetrahydrofuran (L-659,989) in rhesus monkeys

1. The plasma concentration, main route of metabolism and excretion of ³H-L-659,989 were studied in male and female rhesus monkeys by dosing either i.v. or orally at 10 mg/kg.

2. The percentage of the AUC for the plasma radioactivity concentration-time curve of oral vs i.v. dosed monkeys was 78% for males and 90% for females, indicating that the dose was well absorbed.

3. The bioavailability of the drug was low (≤10%) for all monkeys, probably due to rapid first pass metabolism. The drug was metabolized predominantly at the C-4′-propoxy side-chain. The two major plasma metabolites were identified as the 4′-2-(hydroxy)propoxy metabolite (³H-trans-4′-HP) and the 4′-hydroxy metabolite (³H-4′-hydroxy) which was isolated as a 2:1 mixture of (±)trans:(±)cis.

4. Approx, 80% of the radiolabelied dose was excreted equally in the urine and faeces in 96h, with the largest percentage of the Initiated dose (31.4%) in the 0-24h urine.

5. The major metabolites in the excreta were the (±)trans(±)cis mixture of ³H-4′-hydroxy and the glucuronide conjugate of ^3H-trans-4′-hydroxy. The glucuronide conjugate of ³H-trans-4′-hydroxy was excreted in the urine of i.v. and orally dosed monkeys and represented an average of 21% and 5.1% of the dose, respectively. ³H-4′-Hydroxy was excreted in both the urine and faeces, accounting for. 0.1% and 7.4% of the dose in i.v. and orally dosed monkeys, respectively.     

Identification and characterization of metabolites of ASP015K,a novel oral Janus kinase inhibitor,in rats,chimeric mice with humanized liver,and humans

Abstract

1.?Here, we elucidated the structure of metabolites of novel oral Janus kinase inhibitor ASP015K in rats and humans and evaluated the predictability of human metabolites using chimeric mice with humanized liver (PXB mice).

2.?Rat biological samples collected after oral dosing of ¹⁴C-labelled ASP015K were examined using a liquid chromatography–radiometric detector and mass spectrometer (LC–RAD/MS). The molecular weight of metabolites in human and the liver chimeric mouse biological samples collected after oral dosing of non-labelled ASP015K was also investigated via LC–MS. Metabolites were also isolated from rat bile samples and analyzed using nuclear magnetic resonance.

3.?Metabolic pathways of ASP015K in rats and humans were found to be glucuronide conjugation, methyl conjugation, sulfate conjugation, glutathione conjugation, hydroxylation of the adamantane ring and N-oxidation of the 1H-pyrrolo[2,3-b]pyridine ring. The main metabolite of ASP015K in rats was the glucuronide conjugate, while the main metabolite in humans was the sulfate conjugate. Given that human metabolites were produced by human hepatocytes in chimeric mice with humanized liver, this human model mouse was believed to be useful in predicting the human metabolic profile of various drug candidates.     

Pharmacokinetics and metabolite profiling of fimasartan,a novel antihypertensive agent,in rats

Abstract

1.?The objectives of this study were to evaluate the pharmacokinetics and metabolism of fimasartan in rats.

2.?Unlabeled fimasartan or radiolabeled [¹⁴C]fimasartan was dosed by intravenous injection or oral administration to rats. Concentrations of unlabeled fimasartan in the biological samples were determined by a validated LC/MS/MS assay. Total radioactivity was quantified by liquid scintillation counting and the radioactivity associated with the metabolites was analyzed by using the radiochemical detector. Metabolite identification was conducted by product ion scanning using LC/MS/MS.

3.?After oral administration of [¹⁴C]fimasartan, total radioactivity was found primarily in feces. In bile duct cannulated rats, 58.8?±?14.4% of the radioactive dose was excreted via bile after oral dosing. Major metabolites of fimasartan including the active metabolite, desulfo-fimasartan, were identified, yet none represented more than 7.2% of the exposure of the parent drug. Fimasartan was rapidly and extensively absorbed and had an oral bioavailability of 32.7–49.6% in rats. Fimasartan plasma concentrations showed a multi-exponential decline after oral administration. Double peaks and extended terminal half-life were observed, which was likely caused by enterohepatic recirculation.

4.?These results provide better understanding on the pharmacokinetics of fimasartan and may aid further development of fimasartan analogs.     

The fate of 4-hydroxycarbazole metabolite: metabolism and carcinogenicity assessment of a β-adrenergic receptor modulator containing carbazole structure

1. LY377604 has a potential to form 4-hydroxycarbazole, which was reported in the literature as a mutagen. This safety concern led to our investigation of the metabolism and carcinogenicity of LY377604.

2. In in vitro studies with LY377604, 4-hydroxycarbazole was detected in the presence of liver microsomes prepared from different species. When incubated with liver slices, only the conjugate of 4-hydroxycarbazole was detected.

3. Subsequent in vivo radio-labelled studies were conducted to characterise the formation of 4-hydroxycarbazole from LY377604. Free 4-hydroxycarbazole was not detected in vivo, but the O-glucuronide conjugate was identified as a minor metabolite in urine samples, representing 0.2% and 0.9% of the radioactive dose in rats and monkeys. The low level of circulating 4-hydroxycarbazole glucuronide conjugate was also detected in plasma.

4. LY377604 was negative in all genetic toxicology assays and was not associated with tumour induction in a 6-month carcinogenicity study using RasH2+/? mouse model. The exposure to free 4-hydroxycarbazole was not measurable after one dose and was about 0.1%?0.2% of the parent exposure at the end of the 6-month study.

5. These data suggested that 4-hydroxycarbazole was formed as a minor metabolite in vivo, but it was primarily conjugated and excreted in urine as the glucuronide conjugate. The absence of tumours in the carcinogenicity study combined with the exposure data suggested that the low level of free 4-hydroxycarbazole did not represent a carcinogenic risk.

     

Metabolic profiles of pomalidomide in human plasma simulated with pharmacokinetic data in control and humanized-liver mice

1.?Pomalidomide has been shown to be potentially teratogenic in thalidomide-sensitive animal species such as rabbits. Screening for thalidomide analogs devoid of teratogenicity/toxicity – attributable to metabolites formed by cytochrome P450 enzymes – but having immunomodulatory properties is a strategic pathway towards development of new anticancer drugs.

2.?In this study, plasma concentrations of pomalidomide, its primary 5-hydroxylated metabolite, and its glucuronide conjugate(s) were investigated in control and humanized-liver mice. Following oral administration of pomalidomide (100?mg/kg), plasma concentrations of 7-hydroxypomalidomide and 5-hydroxypomalidomide glucuronide were slightly higher in humanized-liver mice than in control mice.

3.?Simulations of human plasma concentrations of pomalidomide were achieved with simplified physiologically-based pharmacokinetic models in both groups of mice in accordance with reported pomalidomide concentrations after low dose administration in humans.

4.?The results indicate that pharmacokinetic profiles of pomalidomide were roughly similar between control mice and humanized-liver mice and that control and humanized-liver mice mediated pomalidomide 5-hydroxylation in vivo. Introducing one aromatic amino group into thalidomide resulted in less species differences in in vivo pharmacokinetics in control and humanized-liver mice.     

Structure identification and elucidation of mosapride metabolites in human urine,feces and plasma by ultra performance liquid chromatography-tandem mass spectrometry method

Abstract

1.?Mosapride citrate (mosapride) is a potent gastroprokinetic agent. The only previous study on mosapride metabolism in human reported one phase I oxidative metabolite, des-p-fluorobenzyl mosapride, in human plasma and urine using HPLC method. Our aim was to identify mosapride phase I and phase II metabolites in human urine, feces and plasma using UPLC-ESI-MS/MS.

2.?A total of 16 metabolites were detected. To the best of our knowledge, 15 metabolites have not been reported previously in human.

3.?Two new metabolites, morpholine ring-opened mosapride (M15) and mosapride N-oxide (M16), alone with one known major metabolite, des-p-fluorobenzyl mosapride (M3), were identified by comparison with the reference standards prepared by our group. The chemical structures of seven phase I and six phase II metabolites of mosapride were elucidated based on UPLC–MS/MS analyses.

4.?There were two major phase I reactions, dealkylation and morpholine ring cleavage. Phase II reactions included glucuronide, glucose and sulfate conjugation. The comprehensive metabolic pathway of mosapride in human was proposed for the first time.

5.?The metabolites in humans were compared with those in rats reported previously. In addition to M10, the other 15 metabolites in humans were also found in rats. This result suggested that there was little qualitative species difference in the metabolism of mosapride between rats and humans.

6.?In all, 16 mosapride metabolites including 15 new metabolites were reported. These results allow a better understanding of mosapride disposition in human.     

Effects of blockage of urine and/or bile flow on diflunisal conjugation and disposition in rats

1. The effects of surgical blockage of either or both of the urinary and biliary excretion routes on the elimination of diflunisal (DF) and its conjugates were investigated in pentobarbitone-anaesthetized rats given DF at 10mg/kg i.v.

2. In control animals the acyl glucuronide and phenolic glucuronide conjugates were excreted predominantly in bile, whereas the sulphate conjugate was eliminated almost exclusively in urine.

3. Bilateral ureter ligation had little effect on DF elimination, except for accumulation of the sulphate conjugate in plasma. Compensatory biliary excretion did not occur.

4. Total plasma clearance of DF decreased from 1.01 to 0.68 ml/min per kg following bile duct ligation. Plasma concentrations and urinary excretion of the glucuronides were elevated.

5. In rats with blockage of both urinary and biliary excretion routes, total plasma clearance of DF decreased to 0.59 ml/min per kg. Both the sulphate and phenolic glucuronide conjugates accumulated in plasma, whereas the acyl glucuronide peaked at 30 min and then declined in parallel with DF. The latter result indicates systemic instability of DF acyl glucuronide with hydrolytic regeneration of DF as the likely major consequence.     

Characterisation of liver-specific distribution of a novel 1-benzyl-4-aminoindole-based thyroid hormone receptor β agonist,SKL-13784: comparison with GC-1

1.?SKL-13784, a novel series of 1-benzyl-4-aminoindole-based thyroid hormone receptor β (TRβ)-selective agonists, showed higher liver selectivity than GC-1 and was poorly distributed in the heart and brain. We aimed to clarify the mechanism of liver selectivity of SKL-13784 through a comparative study with GC-1.

2.?Media-loss assays using fresh rat hepatocytes showed that the Oatp family may have been involved in liver uptake for both compounds and that SKL-13784 was more efficiently taken up than GC-1.

3.?In addition, the media-loss assay results showed that hepatic uptake was important in eliminating both compounds in rats.

4.?The low passive permeability of SKL-13784 on the parallel artificial membrane permeability assay (PAMPA) contributed to the limited distribution of SKL-13784 into extrahepatocytes.

5.?Biliary extraction was a major route of SKL-13784 and GC-1 disposition. SKL-13784 was excreted into bile unchanged and in its glucuronide form, whereas almost all GC-1 in bile was in its glucuronide form. In bile duct-cannulated rats, a 4.3-fold decrease in t_1/2 of SKL-13784 was observed, implicating enterohepatic biliary recirculation.

6.?The selective distribution of SKL-13784 in the liver was largely due to efficient uptake via hepatic transporters.