Mechanistic Multilayer Quantitative Model for Nonlinear Pharmacokinetics, Target Occupancy and Pharmacodynamics (PK/TO/PD) Relationship of D-Amino Acid Oxidase Inhibitor, TAK-831 in Mice.

PURPOSE: TAK-831 is a highly selective and potent inhibitor of D-amino acid oxidase (DAAO) currently under clinical development for schizophrenia. In this study, a mechanistic multilayer quantitative model that parsimoniously connects pharmacokinetics (PK), target occupancy (TO) and D-serine concentrations as a pharmacodynamic (PD) readout was established in mice. METHODS: PK, TO and PD time-profiles were obtained in mice and analyzed by mechanistic binding kinetics model connected with an indirect response model in a step wise fashion. Brain distribution was investigated to elucidate a possible mechanism driving the hysteresis between PK and TO. RESULTS: The observed nonlinear PK/TO/PD relationship was well captured by mechanistic modeling framework within a wide dose range of TAK-831 in mice. Remarkably different brain distribution was observed between target and reference regions, suggesting that the target-mediated slow binding kinetics rather than slow penetration through the blood brain barrier caused the observed distinct kinetics between PK and TO. CONCLUSION: A quantitative mechanistic model for concentration- and time-dependent nonlinear PK/TO/PD relationship was established for TAK-831 in mice with accounting for possible rate-determining process. The established mechanistic modeling framework will provide a quantitative means for multilayer biomarker-assisted clinical development in multiple central nervous system indications.

Pharmacokinetic and pharmacodynamic modeling of the metastin/kisspeptin analog, TAK-448, for its anti-tumor efficacy in a rat xenograft model.

TAK-448 is the investigational metastin/kisspeptin analog, which is known to have an anti-tumor effect through suppression of androgen hormones (luteinizing hormone and testosterone) levels. This study developed pharmacokinetic-pharmacodynamic (PK/PD) models of TAK-448 and leuprorelin acetate (TAP-144) in a rat vertebral-cancer of the prostate (VCaP) androgen-sensitive prostate cancer xenograft model to quantitatively assess and compare the anti-tumor effects of both drugs. A potential contribution of the hormone-independent direct effects of TAK-448 to the tumor growth inhibition was also investigated in the in vivo rat xenograft model, because our in vitro experiments revealed that TAK-448 may also directly suppress VCaP cellular proliferation. The PK/PD model successfully described the time course of tumor growth inhibition after drug treatment as well as the development of resistance to the inhibition of androgen hormones, following drug treatment or castration. The EC50 of the hormone-dependent inhibitory effect of TAK-448 was much lower than that of TAP-144, and TAK-448 also has a faster onset of anti-tumor effect than TAP-144, demonstrating that TAK-448 has a stronger overall anti-tumor effect than TAP-144. In addition, model inference, by incorporating a hormone-independent inhibition pathway of TAK-448 into the PK-PD model, suggested that such a direct inhibition pathway for TAK-448 cannot be excluded, as also indicated by in vitro studies, but its EC50 would be approximately three orders of magnitude higher than that of the hormone-dependent pathway. This study helps to understand the potential and mechanism of TAK-448 as a prostate cancer treatment.

The Enhancement of Subcutaneous First-Pass Metabolism Causes Nonlinear Pharmacokinetics of TAK-448 after a Single Subcutaneous Administration to Rats.

2-(N-acetyl-D-tyrosyl-trans-4-hydroxy-L-prolyl-L-asparaginyl-L-threonyl-L-phenylalanyl) hydrazinocarbonyl-L-leucyl-Nω-methyl-L-arginyl-L-tryptophanamide monoacetate (TAK-448, RVT-602), a kisspeptin analog, has been developed as a therapeutic agent for prostate cancer. The purpose of the present study is to clarify the mechanism of the less than dose-proportional nonlinear pharmacokinetics of TAK-448 after subcutaneous administration to rats. The plasma pharmacokinetics of TAK-448 and radiolabeled TAK-448 ([14C]TAK-448) were examined after subcutaneous and intravenous administrations to rats. [14C]TAK-448 was also subcutaneously injected together with protease inhibitors. The effects of the protease inhibitors on the in vitro metabolism of [14C]TAK-448 were investigated using rat skin homogenates. In a dose-ascending study, less than dose-proportional nonlinear pharmacokinetics were observed after subcutaneous administration with limited absorption of TAK-448 at the highest dose level contrary to the linear pharmacokinetics following intravenous dosing, indicating enhancement of subcutaneous metabolism with dose escalation. The systemic absorption of unchanged TAK-448 recovered when protease inhibitors were subcutaneously coadministered, suggested the involvement of subcutaneous proteases in the first-pass metabolism. An in vitro metabolism study suggests that serine protease could be responsible for the subcutaneous metabolism of TAK-448. Dose-dependent enhancement of first-pass metabolism appears to contribute to the less than dose-proportional nonlinear pharmacokinetics of TAK-448 after subcutaneous administrations to rats.

Investigation of disposition for TAK-448, a synthetic peptide of kisspeptin analog, in rats and dogs using the radiolabeled TAK-448 suitable for pharmacokinetic study.

Disposition of 2-(N-acetyl-d-tyrosyl-trans-4-hydroxy-l-prolyl-l-asparaginyl-l-threonyl-l-phenylalanyl) hydrazinocarbonyl-L-leucyl-Nω-methyl-l-arginyl-l-tryptophanamide monoacetate (TAK-448, RVT-602), a synthetic kisspeptin analog, was investigated after parenteral dosing of radiolabeled TAK-448 ([d-Tyr-14C]TAK-448) to rats and dogs, and it was confirmed if the radiolabeling position at d-Tyr was eligible for assessment of in vivo disposition. Dosed radioactivity was rapidly and well absorbed after subcutaneous administration and an appreciable amount of unchanged TAK-448 (TAK-448F) and a hydrolyzed metabolite, M-I, were detected in the plasma of rats and dogs. After intravenous administration of [d-Tyr-14C]TAK-448 to rats, the radioactivity widely distributed to tissues with relatively higher concentrations in kidney and urinary bladder. The radioactivity was decreased rapidly from the tissues. After subcutaneous administration of [d-Tyr-14C]TAK-448 to rats and dogs, the dosed radioactivity was almost completely recovered by 48 and 72 h in rats and dogs, respectively, and most of the radioactivity was excreted in urine after extensive metabolism in the two species. These results suggest that TAK-448 has an acceptable pharmacokinetic profile for clinical evaluation and development, and demonstrate that the synthesized [D-Tyr-14C]TAK-448 used in this study represents a favorable labeling position to evaluate disposition properties of this compound.

Mechanism for Covalent Binding of MLN3126, an Oral Chemokine C-C Motif Receptor 9 Antagonist, to Serum Albumins.

N-{4-Chloro-2-[(1-oxidopyridin-4-yl)carbonyl]phenyl}-4-(propan-2-yloxy)benzenesulfonamide (MLN3126) is an orally available chemokine C-C motif receptor 9 selective antagonist. In nonclinical pharmacokinetic studies of MLN3126, nonextractable radioactivity was observed in plasma after oral administration of 14C-labeled MLN3126 ([14C]MLN3126) to Sprague-Dawley (SD) rats. In this study, the nonextractable radioactive component was digested with trypsin or a nonspecific protease, pronase, after chemical reduction to obtain drug-peptide adducts or drug-amino acid adducts. The chemical structure of these adducts was characterized by liquid chromatography/mass spectrometry. The results demonstrated that the major part of the nonextractable radioactivity was accounted for by covalent binding via the Schiff base formed specifically between the ε-amino group of lysine residue 199 in rat serum albumin and the carbonyl group of MLN3126. The half-life (t1/2) of the total radioactivity in plasma during and after 21 daily multiple oral administrations of [14C]MLN3126 to SD rats was approximately 5-fold shorter than the reported t1/2 of albumin in rats. The data indicated that the covalent binding was reversible under physiologic conditions. The formation of the covalent binding was also confirmed in in vitro incubations with serum albumins from rats, humans, and dogs in the same manner, indicating that there are no qualitative interspecies differences in the formation of the Schiff base.

Influence of body composition on disposition of the highly fat distributed compound as analysed by physiologically based pharmacokinetic (PBPK) modeling and simulation.

A recent study suggested that the pharmacokinetics (PK) of highly fat distributed compounds can be affected by acute changes in the volume of adipose tissue. The present study investigates possible influences of body composition on the disposition of the highly lipophilic compound TAK-357 in two rat strains. Physiologically based PK (PBPK) modeling and simulation was applied on single and multiple dose PK data of TAK-357 in obese Wistar fatty rats and Wistar lean rats having approximately 45% and 13% body fat, respectively. The observed effects of an elevated fat mass in Wistar fatty rats on the plasma concentrations appeared to be partly compensated for by other differences between the two rat strains. A decrease in the tissue to blood partition coefficients under high body fat conditions was identified as another factor contributing to the difference in PK. A higher lipid content in the plasma in high body fat animals may result in relatively lower tissue to blood partition coefficients. PBPK-based simulations indicate that the plasma concentrations of lipophilic compounds in high body fat conditions can differ by up to two-times at steady-state. This confirms that there is only a small impact of body composition change on the plasma concentration of highly lipophilic drugs and that the need for therapeutic dose adjustments may be limited.

Long-Term Stability of Cryopreserved Human Hepatocytes: Evaluation of Phase I and II Drug-Metabolizing Enzyme Activities and CYP3A4/5 Induction for More than a Decade.

We evaluated the long-term stability of hepatocytes stored in the vapor phase of liquid nitrogen for their viability, cytochrome P450 (CYP) 1A2 activity, CYP3A4/5 activity, uridine diphosphate-glucuronosyl transferase (UGT) activity, sulfotransferase (SULT) activity, and CYP3A4/5 induction during 14 years of preservation. No substantial degradation of viability, CYP1A2 activity, UGT activity, or CYP3A4/5 induction was observed. CYP3A4/5 activity showed a slight decrease after 7 years of storage, and SULT activity gradually decreased during storage, although substantial activities remained even after 14 years. These results indicate that cryopreserved human hepatocytes can be stored stably for more than a decade with little or no change in viability, activity of drug-metabolizing enzymes, or CYP3A4/5 induction, and can be widely applicable to qualitative research in drug metabolism.

Impact of acute fat mobilisation on the pharmacokinetics of the highly fat distributed compound TAK-357, investigated by physiologically based pharmacokinetic (PBPK) modeling and simulation.

In a dog toxicokinetic study, an unusual plasma concentration increase of the highly lipophilic compound TAK-357 was observed 2 weeks after termination of a 2-week repeated dosing in one dog with acute body weight loss. The present study investigates the cause of this increase. A physiologically based pharmacokinetic (PBPK) model was constructed using the rat and dog pharmacokinetic data. Using the constructed model, the TAK-357 concentration profile in the case of body weight change was simulated. The PBPK model-derived simulation suggested that redistribution from adipose tissues to plasma due to a loss of body fat caused the observed concentration increase of TAK-357 in dog plasma. The analysis demonstrates that the disposition of a highly lipophilic and fat-distributed compound can be affected by acute changes in adipose tissue mass. PBPK modeling and simulation proved to be efficient tools for the quantitative hypothesis testing of apparently atypical PK phenomena resulting from acute physiological changes.

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.

In vitro metabolism of TAK-438, vonoprazan fumarate, a novel potassium-competitive acid blocker.

1. TAK-438, vonoprazan fumarate, is a novel orally active potassium-competitive acid blocker, developed as an antisecretory drug. In this study, we investigated the in vitro metabolism of 14C-labeled TAK-438. In human hepatocytes, M-I, M-II, M-III and M-IV-Sul were mainly formed, and these were also detected in clinical studies. N-demethylated TAK-438 was also formed as an in vitro specific metabolite. Furthermore, CYP3A4 mainly contributed to the metabolism of TAK-438 to M-I, M-III, and N-demethylated TAK-438, and CYP2B6, CYP2C19 and CYP2D6 partly catalyzed the metabolism of TAK-438. The sulfate conjugation by SULT2A1 also contributed to the metabolism of TAK-438 to form TAK-438 N-sulfate, and CYP2C9 mediated the formation of M-IV-Sul from TAK-438 N-sulfate. The metabolite M-IV, which could be another possible intermediate in the formation of M-IV-Sul, was not observed as a primary metabolite of TAK-438 in any of the in vitro studies. 2. In conclusion, TAK-438 was primarily metabolized by multiple metabolizing enzymes including CYP3A4, CYP2B6, CYP2C19, CYP2D6, and a non-CYP enzyme SULT2A1, and the influence of the CYP2C19 genotype status on gastric acid suppression post TAK-438 dosing could be small. The multiple metabolic pathways could also minimize the effects of co-administrated CYP inhibitors or inducers on the pharmacokinetics of TAK-438.

The effects of the concentration-dependent erythrocyte distribution of TAK-802, a potent acetylcholinesterase inhibitor, on rat pharmacokinetics.

The purpose of this study was to investigate the effect of the concentration-dependent erythrocyte distribution of TAK-802, a potent acetylcholinesterase inhibitor, on rat pharmacokinetics. In an ascending oral dose study, the maximum plasma concentration (Cmax ) of TAK-802 increased in a dose-dependent manner. The time to reach Cmax decreased as the dose increased, whereas the total clearance was independent of the tested dose range. In this intravenous (i.v.) ascending dose study in rats, the apparent distribution volumes at steady state decreased, and the apparent terminal elimination rate constants increased with TAK-802 dose escalation. A marked concentration dependency was observed in an associated in vitro erythrocyte distribution study. The in vitro erythrocyte distribution study results and a relationship analysis between the plasma and blood concentrations of TAK-802 after i.v. dosing revealed that the characteristics of the erythrocyte distribution could be expressed by Langmuir's adsorption formula. The concentration-time profiles of TAK-802 in plasma and whole blood calculated using a nonlinear pharmacokinetic model incorporating the concentration-dependent erythrocyte distribution with optimized parameters fit well to the observed plasma and blood concentration profiles obtained from the i.v. ascending dose study. These results indicate that the concentration-dependent erythrocyte distribution plays a major role in the nonlinear pharmacokinetics of TAK-802 in rats. Copyright © 2016 John Wiley & Sons, Ltd.

A validated simultaneous quantification method for vonoprazan (TAK-438F) and its 4 metabolites in human plasma by the liquid chromatography-tandem mass spectrometry.

Vonoprazan fumarate (TAK-438) is a potassium-competitive acid blocker which was approved in Japan for a treatment of acid-related diseases. In this study a simple and validated bioanalytical method, which can simultaneously determine vonoprazan (TAK-438F) and its four metabolites (M-I, M-II, M-III and M-IV-Sul) in human plasma, was developed. The method is based on protein precipitation and subsequent ultra-high performance liquid chromatography separation followed by tandem mass spectrometry detection. The mass spectrometric parameters for detection of TAK-438F, M-I, M-III and M-IV-Sul were modified from their optimum values in order to achieve a simultaneous quantification while retaining enough sensitivity and wide dynamic ranges for all the target analytes. The validity and robustness of the method was verified through a validation study as per the regulatory guidance on bioanalytical method validation. The calibration ranges are 0.1-100 ng/mL for TAK-438F and M-III, and 1-1000 ng/mL for M-I, M-II and M-IV-Sul using the 100 µL of human plasma. The total run time per sample is 5 min. The working solution for M-III was recommended to be prepared separately, especially for the long-term use, in order to avoid the instability of M-III in the mixed working solutions, which could cause the high consumption of reference standards. The established method was applied to clinical pharmacokinetic studies and concentrations of all the analytes in human plasma were successfully determined with high reproducibility ensured by incurred sample reanalysis, indicating the suitableness of the established method.

Development, validation and application of the liquid chromatography tandem mass spectrometry method for simultaneous quantification of azilsartan medoxomil (TAK-491), azilsartan (TAK-536), and its 2 metabolites in human plasma.

Azilsartan medoxomil potassium salt (TAK-491) is an orally administered angiotensin II type 1 receptor blocker for the treatment of hypertension and is an ester-based prodrug that is rapidly hydrolyzed to the pharmacologically active moiety, azilsartan (TAK-536), during absorption. TAK-536 is biotransformed to the 2 metabolites M-I by decarboxylation and M-II by dealkylation. In this study, we developed and validated a LC/MS/MS method which can simultaneously determine 4 analytes, TAK-491, TAK-536, M-I and M-II. The bioanalytical method can be outlined as follows: two structural analogues are used as the internal standards. The analytes and the IS are extracted from human plasma using solid phase extraction. After evaporating, the residue is reconstituted and injected into a LC/MS/MS system with an ESI probe and analyzed in the positive ion mode. Separation is performed through a conventional reversed-phase column with a mobile phase of water/acetonitrile/acetic acid (40:60:0.05, v/v/v) mixture at a flow rate of 0.2mL/min. The total run time is 8.5min. The calibration range is 1-2500ng/mL in human plasma for all the analytes. Instability issues of the prodrug, TAK-491, were overcome and all the validation results met the acceptance criteria in accordance with the regulatory guideline/guidance. As a result of the clinical study, the human PK profiles of TAK-536, M-I and M-II were successfully obtained and also it was confirmed that TAK-491 was below the LLOQ (1ng/mL) in the human plasma samples.

UDP-glucuronosyltransferase 2B15 (UGT2B15) is the major enzyme responsible for sipoglitazar glucuronidation in humans: retrospective identification of the UGT isoform by in vitro analysis and the effect of UGT2B15*2 mutation.

Recently, genotyping in clinical studies has revealed that UGT2B15 genetic polymorphism has an influence on the clinical pharmacokinetics of sipoglitazar. In this study, the UGT responsible for sipoglitazar was retrospectively identified by in vitro analysis. A study using UGT-expressing supersomes revealed that sipoglitazar glucuronidation was more extensively catalyzed by UGT1A1, 1A3, 1A6, 2B4, and 2B15 than by other UGTs. Enzyme kinetic studies for sipoglitazar glucuronidation and recent findings related to mRNA expression analysis of UGTs narrowed the involved isoforms down to UGT1A1 and UGT2B15 among these five human UGTs. In a correlation study between sipoglitazar glucuronidation and UGT isoform-specific activities, the glucuronidation of S-oxazepam, a specific substrate for UGT2B15, strongly correlated with that of sipoglitazar, as compared with that of ß-estradiol, a representative UGT1A1 substrate. The analysis of the species difference strengthens the possibility of UGT2B15 rather than that of UGT1A1. These in vitro findings indicate that UGT2B15 is principally responsible for sipoglitazar glucuronidation. Moreover, the UGT2B15*2 mutation significantly increased the Km value of sipoglitazar in the kinetic analysis using recombinant His-tag UGT2B15*1- or *2-membrane fractions. These results show that sipoglitazar is a good example to elucidate the relationship between phenotype and genotype for UGT2B15 from in vitro analysis.

Highly sensitive liquid chromatography-tandem mass spectrometry method for quantification of TAK-448 in human plasma.

TAK-448 is a nonapeptide analogue and a novel metastin receptor agonist. The aim of this study was to develop a bioanalytical method for TAK-448F (the free base of TAK-448) in human plasma with LC/MS/MS that is sensitive and applicable for the clinical PK studies, and to evaluate the reliability and robustness of the developed method through a validation study in accordance with the regulatory guidance/guideline. The bioanalytical method developed in this study can be outlined as follows. The structural analogue, TAK-683, was used as the internal standard (IS). TAK-448F and the IS were extracted from human plasma using solid phase extraction (SPE) with a polymer-based weak cationic exchanger. After evaporating, the residue was reconstituted and injected into a LC-MS/MS system with ESI probe and analyzed by the selected reaction monitoring (SRM) in the positive ion mode. Separation was performed through an UPLC BEH Phenyl column with the mobile phase of water/methanol/formic acid mixture at a flow rate of 0.2 mL/min. The total run time was 10 minutes. The LLOQ was achieved to be 5 pg/mL with 0.5 mL of human plasma sample. All the validation results met the acceptance criteria in accordance with the regulatory guidance/guideline proving its reliability and robustness. As a result of the clinical study, the human PK profiles of TAK-448F were successfully obtained with this method.

Species differences of organic anion transporters involved in the renal uptake of 4-amino-3-chlorophenyl hydrogen sulfate, a metabolite of resatorvid, between rats and dogs.

Previous studies on the metabolic fate of resatorvid (TAK-242) have shown that species differences in the pharmacokinetics of 4-amino-3-chlorophenyl hydrogen sulfate (M-III), a metabolite of TAK-242, between rats and dogs are mainly attributable to the urinary excretion process. In the present study, the renal uptake mechanism of M-III was investigated using kidney slices and Xenopus laevis oocytes expressing rat organic anion transporter 1 (rOat1; Slc22a6) and rOat3 (Slc22a8). The uptake of p-aminohippuric acid (PAH), a substrate for Oats, by kidney slices from rats and dogs increased at 37 °C and M-III inhibited the uptake. The initial uptake clearance of M-III by rat kidney slices was 0.295 and 0.0114 ml/min/g at 37 °C and 4 °C, respectively. The Eadie-Hofstee plot of M-III uptake at 37 °C revealed two-component transport processes with K(m) values being 6.48 and 724 µmol/l. The uptake was inhibited by probenecid (PBC), PAH and benzylpenicillin (PCG). In contrast, in dog kidney slices, the initial uptake clearance of M-III was 8.70 × 10(-3) and 9.00 × 10(-3) ml/min/g at 37 °C and 4 °C, respectively, and the uptake was not inhibited by PBC. Furthermore, rOat1- and rOat3-expressing oocytes mediated M-III uptake and the uptake was inhibited by PAH and PCG, respectively. These results suggest that rOat1 and rOat3 are responsible for the renal uptake of M-III in rats. Moreover, it is speculated that Oat(s) is unable to transport M-III in dogs and that the difference in the substrate recognition of Oat(s) contributes to the species difference in the pharmacokinetics of M-III between rats and dogs.

Pharmacokinetic and pharmacodynamic modeling of hedgehog inhibitor TAK-441 for the inhibition of Gli1 messenger RNA expression and antitumor efficacy in xenografted tumor model mice.

6-Ethyl-N-[1-(hydroxyacetyl)piperidin-4-yl]-1-methyl-4-oxo-5-(2-oxo-2-phenylethyl)-3-(2,2,2-trifluoroethoxy)-4,5-dihydro-1H-pyrrolo[3,2-c]pyridine-2-carboxamide (TAK-441) is a potent, selective hedgehog signaling pathway inhibitor that binds to Smo and is being developed for the treatment of cancer. The objectives of these studies were to explore the possibility of establishing of a link between the pharmacokinetics of TAK-441 and the responses of Gli1 mRNA in tumor-associated stromal or skin cells and the antitumor effect of hedgehog inhibition. To this end, we built pharmacokinetic and pharmacodynamic models that describe the relationship of the concentrations of TAK-441 plasma to the responses of Gli1 mRNA in the tumor (target) and skin (surrogate) and to tumor growth inhibition in mice bearing xenografts of human pancreatic tumors (PAN-04). The responses of Gli1 mRNA and tumor growth were described by an indirect response model and an exponential tumor growth model, respectively. The IC50 values for Gli1 mRNA inhibition in the tumor and skin by TAK-441 were estimated to be 0.0457 and 0.113 µg/ml, respectively. The IC90 value for tumor growth inhibition was estimated to be 0.68 µg/ml. These results suggest that a >83% inhibition of Gli1 mRNA expression in the skin or a >94% inhibition of Gli1 mRNA expression in the tumor would be required to sufficiently inhibit (>90%) hedgehog-related tumor growth in the xenografted model mice. We conclude that Gli1 mRNA expression in the tumor and skin could be a useful biomarker for predicting the antitumor effect of hedgehog inhibitors.

Absorption of TAK-491, a new angiotensin II receptor antagonist, in animals.

The absorption process in animals of TAK-491, designed as ester-based prodrug with medoxomil moiety, was evaluated. In the plasma of rats and dogs, TAK-536, the pharmacologically active metabolite, was present as the main component with hardly detectable concentrations of TAK-491 after oral administration of TAK-491. In the rat portal plasma, TAK-536 was also present as the main component with hardly detectable concentrations of TAK-491 after jejunal loop injection of TAK-491, suggesting TAK-491 was absorbed from small intestine and hydrolyzed almost completely during absorption. Caco-2 study indicated the permeability of TAK-491 was improved by prodrug modification and the compound could be mainly transferred as TAK-491. This is well consistent with the facts that the AUC and T(max) of TAK-536 after oral administration of TAK-491 were higher and shorter than those after oral administration of TAK-536 in dogs Hydrolysis of TAK-491 is observed not only by the intestinal and hepatic S9 fraction, but also by plasma and human serum albumin. However, medoxomil alcohol wasn't detected during the hydrolysis of TAK-491. These metabolic features of TAK-491 were similar to olmesartan medoxomil, suggesting the hydrolytic pathway and enzymes for TAK-491 when catalyzing to TAK-536 would be the same as olmesartan medoxomil.

Evaluation of low background liquid scintillation counter for non-clinical ADME studies.

1. The performance of low background (BG) liquid scintillation counter (LSC) was evaluated for practical purposes of non-clinical drug absorption, distribution, metabolism and excretion (ADME) studies. The measurement conditions for the radioactivity for low BG LSC were investigated and metabolite profiling in rat plasma after single oral administration of (14)C-labeled compounds was performed. Metabolite profiling was also conducted using conventional LSC and accelerator mass spectrometer (AMS), and the performances of these measuring instruments were compared. 2. The established measurement conditions showed good linearity of the calibration curve over the concentration range from 3 to 300 dpm/vial. Metabolite profiling using low BG LSC for the plasma samples diluted to 5-55 times was comparable to that using conventional LSC for the undiluted plasma samples. Meanwhile, metabolite profiling using AMS for the plasma samples diluted to 250-2000 times was comparable to that using conventional LSC. 3. These results suggest that the application of low BG LSC is one of the useful tools for non-clinical ADME studies and that it is possible to select conventional LSC, low BG LSC or AMS for radioactivity measurement by considering the specific radioactivity of the compounds and the predicted concentrations of radioactivity in biological samples in ADME studies.

Application of high-resolution ESI and MALDI mass spectrometry to metabolite profiling of small interfering RNA duplex.

We investigated the application of a high-resolution Orbitrap mass spectrometer equipped with an electrospray ionization (ESI) source and a matrix-assisted laser desorption/ionization-time-of-flight (MALDI-TOF) mass spectrometer to the metabolite profiling of a model small interfering RNA (siRNA) duplex TSR#34 and compared their functions and capabilities. TSR#34 duplex was incubated in human serum in vitro, and the duplex and its metabolites were then purified by ion exchange chromatography in order to remove the biological matrices. The fraction containing the siRNA duplex and its metabolites was collected and desalted and then subjected to high-performance liquid chromatography (HPLC) equipped with a reversed phase column. The siRNA and its metabolites were separated into single strands by elevated chromatographic temperature and analyzed using the ESI-Orbitrap or the MALDI-TOF mass spectrometer. Using this method, the 5' and/or 3' truncated metabolites of each strand were detected in the human serum samples. The ESI-Orbitrap mass spectrometer enabled differentiation between two possible RNA-based sequences, a monoisotopic molecular mass difference which was less than 2 Da, with an intrinsic mass resolving power. In-source decay (ISD) analysis using a MALDI-TOF mass spectrometer allowed the sequencing of the RNA metabolite with characteristic fragment ions, using 2,4-dihydroxyacetophenone (2,4-DHAP) as a matrix. The ESI-Orbitrap mass spectrometer provided the highest mass accuracy and the benefit of on-line coupling with HPLC for metabolite profiling. Meanwhile, the MALDI-TOF mass spectrometer, in combination with 2,4-DHAP, has the potential for the sequencing of RNA by ISD analysis. The combined use of these methods will be beneficial to characterize the metabolites of therapeutic siRNA compounds.