Effect of the Phosphate Binder Sevelamer Carbonate on the Bioavailability of Enarodustat, an Oral Erythropoiesis Stimulating Agent.

Enarodustat is an orally available hypoxia-inducible factor-prolyl hydroxylase inhibitor which can correct the erythropoietic capacity and improve anemia in chronic kidney disease. Sevelamer carbonate, a non-calcium-based polymeric resin, is one of the commonly prescribed agents for the management of hyperphosphatemia in patients undergoing hemodialysis. This was an open-label, crossover study in healthy male subjects (N = 12) that evaluated the effect of sevelamer carbonate (2400 mg) on the bioavailability of enarodustat (25 mg) when the 2 drugs were administered together (Treatment B) or when enarodustat was administered 3 hours after (Treatment C) or 1 hour before (Treatment D) sevelamer carbonate compared to enarodustat alone (Treatment A). With coadministration of the 2 drugs (Treatment B), enarodustat Cmax and AUCinf reductions were 53% and 45%, respectively. For Treatment C, Cmax and AUCinf reductions were 11% and 6%, respectively, and for Treatment D the corresponding values were 8% and 20%. Thus, coadministration of enarodustat and sevelamer carbonate resulted in a substantial reduction (≈50%) in the oral bioavailability of enarodustat. However, the interaction was substantially mitigated by staggering the administration of enarodustat and sevelamer carbonate. Administration of 4 single oral doses of enarodustat 25 mg, with or without sevelamer carbonate, were safe and well tolerated in this study.

Evaluation of Drug-Drug Interaction Potential of Enarodustat (JTZ-951) Using a Cytochrome P450 Probe Cocktail.

The drug interaction potential of enarodustat (doses: 25, 50 mg) on the activity of cytochrome P450 (CYP) 1A2, 2C9, 2C19, 2D6, and 3A4 was evaluated after once-daily administration for 15 days in a phase 1 multiple-ascending-dose study in healthy subjects. Probe substrates specific for the enzymes, i.e., caffeine (CYP1A2), tolbutamide (CYP2C9), omeprazole (CYP2C19), dextromethorphan (CYP2D6), and midazolam (CYP3A4), were administered orally as a cocktail with (day 15) and without (day -3) enarodustat. Drug interaction was based on geometric mean maximum plasma concentration (Cmax ) and area under the plasma concentration-time curve from the time of dosing to infinity (AUCinf ) ratios (day 15/day -3) for CYP1A2, 2C9, 2C19, 2D6, 3A4, and urinary excretion of dextromethorphan metabolite dextrorphan for CYP2D6. At the 2 enarodustat doses, for caffeine, the geometric mean ratios (range) for Cmax and AUCinf were 0.99-1.06 and 1.61-1.63, respectively. The ratios for peak concentrations and total exposures were 0.98-1.07 and 0.71-1.78 for tolbutamide and omeprazole, respectively. For dextrorphan the Cmax and AUCinf ratios were 0.83-0.90 and 1.02-1.04, respectively. The mean dextrorphan cumulative amount excreted into the urine from the time of dosing to 24 hours values on day -3 and day 15 were 8.25 mg and 8.20 mg at the lower dose, and 9.40 mg and 9.51 mg at the higher dose. The ratios for midazolam Cmax and AUCinf were 1.42-1.63. Overall, there was a lack of enarodustat dose dependency regarding the geometric mean ratios and 90% confidence intervals and urinary excretion of dextrorphan. There were some cases where the 90% confidence intervals at the 2 enarodustat doses were outside the 0.80-1.25 range, but changes in the geometric mean ratios were all <2-fold.

Evaluation of Hemoglobin Response to Treatment With Enarodustat Using Pharmacometric Approach in Japanese Anemic Patients With Chronic Kidney Disease.

Enarodustat (JTZ-951) is a hypoxia-inducible factor prolyl hydroxylase inhibitor that has been approved and marketed in Japan for patients with anemia with chronic kidney disease (CKD). The pharmacometric approach was applied to assess the relationship between plasma concentrations of enarodustat and hemoglobin (Hb) levels, and to provide information regarding the optimal use of enarodustat in clinical practice by simulations based on the pharmacokinetic and pharmacodynamic (PK/PD) model that was developed. The PK/PD data of enarodusat obtained from phase 2 and phase 3 studies in Japanese patients with CKD were well described by the models: a 1-compartment model with first-order absorption and elimination for PK, and a semimechanistic model based on transit compartment model for PD. Although several factors were identified as statistically significant covariates on the PK/PD of enarodustat, model-based simulations showed that none of them had clinically relevant impacts on the treatment effect (ie, Hb levels) of enarodustat. Hence, enarodustat treatment provides the stable Hb control with the initial dose (hemodialysis-dependent CKD: 4 mg/day, non-dialysis-dependent CKD: 2 mg/day) and maintenance dose (1-8 mg/day) to the patients with varied demographic characteristics.

Pharmacokinetics of Enarodustat in Non-Japanese and Japanese Healthy Subjects and in Patients With End-Stage Renal Disease on Hemodialysis.

The pharmacokinetics of enarodustat were elucidated in healthy subjects and in patients with end-stage renal disease (ESRD) on hemodialysis in phase 1 studies conducted in the United States and Japan. In healthy non-Japanese and Japanese subjects, following single oral administration up to 400 mg, enarodustat was rapidly absorbed. Maximum plasma concentration and area under the plasma concentration-time curve from the time of dosing to infinity were dose-dependent, renal excretion of unchanged enarodustat was substantial (on average ≈45% of dose), and mean t1/2 of <10 hours indicated negligible accumulation with once-daily dosing. In general, with daily dosing (25, 50 mg), accumulation at steady-state was ≈1.5-fold (t1/2(eff) ≈15 hours), presumably due to a decrease in renal drug excretion which is not clinically relevant in patients with ESRD. In the single- and multiple-dose studies, plasma clearance (CL/F) was lower in healthy Japanese subjects. In non-Japanese patients with ESRD on hemodialysis, following once-daily dosing (2-15 mg), enarodustat was rapidly absorbed, steady-state maximum plasma concentration and area under the plasma concentration-time curve during the dosing interval were dose-dependent, and interindividual variability in the exposure parameters was low-to-moderate (coefficient of variation, 27%-39%). Steady-state CL/F was similar across doses, renal drug excretion was not significant (<10% of dose), mean t1/2 and t1/2(eff) were similar (overall, 8.97-11.6 hours), and accumulation was minimal (≈20%), demonstrating predictable pharmacokinetics. Japanese patients with ESRD on hemodialysis (15 mg, single dose) exhibited similar pharmacokinetics with mean t1/2 of 11.3 hours and low interindividual variability in the exposure parameters, albeit with lower CL/F versus non-Japanese patients. Body weight-adjusted clearance values were generally similar in non-Japanese and Japanese healthy subjects and also in patients with ESRD on hemodialysis.

Hemodialysis Clearance of Enarodustat (JTZ-951), an Oral Erythropoiesis Stimulating Agent, in Patients with End-Stage Renal Disease.

The dialysis clearance of enarodustat (JTZ-951) was determined in patients (N = 6) with end-stage renal disease on hemodialysis. Enarodustat (5 mg PO) was administered before (day 1) and after hemodialysis (day 8) with pharmacokinetic assessments on the 2 occasions. Dialysis clearance was based on plasma and dialysate enarodustat concentrations. Fraction of administered dose recovered in dialysate, total predialyzer and postdialyzer plasma enarodustat concentrations, and total and unbound venous plasma concentrations were determined. Hemodialysis did not significantly affect overall total concentrations with similar mean area under the plasma concentration-time curve from time 0 to infinity (coefficient of variation) of 3350 (26.4%) and 3640 (20.9%) ng · h/mL on days 1 and 8, respectively, and mean terminal half-life was 9.35 (11.9%) and 9.96 (18.7%) hours on the 2 occasions. Mean maximum concentration was somewhat lower on day 1 compared to day 8 (404 vs 559 ng/mL); the difference did not significantly affect total exposure (area under the plasma concentration-time curve from time 0 to infinity). Plasma protein binding was high (>99%) with similar binding on the 2 occasions, and total pre- and postdialyzer enarodustat concentrations were similar. Plasma unbound enarodustat concentrations decreased during dialysis, with a postdialysis rebound presumably due to re-equilibration with peripheral tissues. Mean unbound area under the plasma concentration-time curve from time 0 to infinity was marginally lower (∼22%) on day 1 compared to day 8. Dialysis clearance (0.415 L/h) was insignificant relative to dialyzer plasma flow (∼20 L/h), and the fraction of administered dose recovered in dialysate was small (6.74% of dose) with low intersubject variability (coefficient of variation, 14.7%). Thus, enarodustat can be administered regardless of dialysis schedule, and dose supplementation is not required in patients with end-stage renal disease on hemodialysis.

Thorough QT/QTc Evaluation of the Cardiac Safety of Enarodustat (JTZ-951), an Oral Erythropoiesis-Stimulating Agent, in Healthy Adults.

This study evaluated the effect of enarodustat on cardiac repolarization in healthy subjects. Enarodustat (20 and 150 mg [supratherapeutic dose]), placebo, and moxifloxacin (positive control, 400 mg) were administered orally to males and females (N = 54) in a crossover fashion. Continuous 12-lead Holter electrocardiogram (ECG) data were obtained before and after dosing, and blood samples were obtained for pharmacokinetic assessments of enarodustat, its circulating metabolite (R)-M2, and moxifloxacin. Central tendency analysis was performed for relevant ECG parameters, the relationship between individual-corrected interval from beginning of the QRS complex to end of the T wave in the frontal plane (QTcI, the primary end point) and plasma concentrations of enarodustat and (R)-M2 were assessed, and ECG waveforms were evaluated for morphological changes. The supratherapeutic dose resulted in 7- and 9-fold higher geometric mean maximum concentrations for enarodustat and (R)-M2, respectively, than the 20 mg dose. Based on time point analysis, the upper bound of the 2-sided 90% confidence interval (CI) for QTcI did not exceed 10 milliseconds at any of the time points for either dose. Based on QTcI-concentration analysis, the slopes for enarodustat and (R)-M2 were not statistically different than 0, and the upper bounds of the 2-sided 90% CI for QTcI at the geometric mean maximum concentrations for the supratherapeutic dose were 1.97 and 1.68 milliseconds for enarodustat and (R)-M2, respectively. The lower bound of the 2-sided 90% CI for moxifloxacin was ≥5 milliseconds, demonstrating assay sensitivity. The study demonstrated no clinically relevant effect of enarodustat and (R)-M2 on cardiac repolarization. There was no evidence of any clinically significant effect on the PR interval and QRS duration, and ECG waveforms showed no new clinically relevant morphological changes.

A Mass Balance Study of 14 C-Labeled JTZ-951 (Enarodustat), a Novel Orally Available Erythropoiesis-Stimulating Agent, in Patients With End-Stage Renal Disease on Hemodialysis.

The mass balance, pharmacokinetics, and biotransformation of JTZ-951 (enarodustat), a novel hypoxia-inducible factor prolyl hydroxylase inhibitor, were characterized in patients (N = 6) with end-stage renal disease on hemodialysis. Following a 10-mg (100 µCi) oral dose of 14 C-JTZ-951, whole blood, feces, dialysate, and, if feasible, urine were obtained for pharmacokinetic assessments and for metabolite profiling and identification in appropriate matrices. Fecal excretion was the major route of elimination of radioactivity, and urinary excretion a minor route, with mean (coefficient of variation [%CV]) recovery of 77.1 (16.2)% and 10.9 (92.0)% of the dose, respectively. Radioactivity was not detected in the dialysate, and mean (%CV) total recovery in excreta was 88.0 (14.9)%. For parent JTZ-951 in plasma, the mean (%CV) effective half-life was 8.96 (7.7)% hours, and area under the curve over 24 hours comprised the majority (>80%) of total exposure, with relatively low variability in these pharmacokinetic variables. Based on profiling of plasma radioactivity, parent JTZ-951 was the predominant circulating component, accounting for 93.7% or more of radioactivity, and metabolite M2 (hydroxylated product) was the only detectable metabolite, but its exposure was minor (<5%) versus unchanged JTZ-951. In urine and feces, the predominant analyte was JTZ-951, and metabolite M2 was the predominant albeit minor metabolite, with small amounts of other metabolites. Thus, plasma exposure to drug-derived radioactivity was primarily due to parent JTZ-951, and the drug was cleared mainly by excretion of unchanged JTZ-951. The study appropriately characterized the disposition of JTZ-951 in patients with end-stage renal disease.

Pharmacokinetics of Lapatinib, a Nonrenally Cleared Drug, in Patients With End-Stage Renal Disease on Maintenance Hemodialysis.

Lapatinib, a tyrosine kinase inhibitor, is approved for the treatment of breast cancer. The literature shows that it is metabolized by CYP3A4 and eliminated predominantly (>90%) by the fecal route, with minimal (<2%) renal elimination in healthy subjects (dose of 250 mg); in cancer patients, renal elimination is minimal at therapeutic doses. For nonrenally cleared drugs, while there is ample evidence of pharmacokinetic alterations secondary to renal impairment-induced effects on drug metabolizing enzymes and/or transporters, the effect of end-stage renal disease (ESRD) on lapatinib pharmacokinetics has not been determined. Rather, as stated in the drug's label, the expectation is lack of effect of renal impairment on lapatinib pharmacokinetics based on its minimal renal elimination. The current report addresses this gap with pharmacokinetic data (obtained in a 1-way drug interaction study) in ESRD patients (n = 11) on maintenance hemodialysis and compared with published data in 37 healthy subjects in 3 separate studies. Following a 250-mg oral dose in ESRD patients, the median tmax was 3.0 hours, and geometric mean (95%CI) values for Cmax , AUCinf , and t1/2 were 349 ng/mL (245-499 ng/mL), 4410 ng·h/mL (2960-6580 ng·h/mL), and 14.8 hours (9.7-22.5 hours), respectively. These parameters approximated published values in healthy subjects and demonstrated that renal impairment and hemodialysis did not affect lapatinib pharmacokinetics. The results of the present study in this renally impaired population, the only such information available to date, support the drug's label and are valuable in view of the recognized difficulties in enrolling organ-impaired patients in oncology trials.

Pharmacokinetics, Food Effect, Ketoconazole Interaction, and Safety of JTK-853, a Novel Nonnucleoside HCV Polymerase Inhibitor, After Ascending Single and Multiple Doses in Healthy Subjects.

Pharmacokinetics, safety, and tolerability of JTK-853, a novel HCV polymerase inhibitor, were evaluated in single and multiple ascending dose (SAD, MAD) studies, with food- and ketoconazole-related effects on exposure to JTK-853 and its active (CYP3A4 mediated) metabolite M2. JTK-853 was safe and well tolerated in both studies. In the SAD study, at doses >1600 mg (with standard breakfast [SBF]), JTK-853 exposure did not increase further, was substantially higher (AUCinf increase: 3- to 8-fold) with SBF (vs fasted), with a moderate increase in AUCinf (approximately 1.5-fold [1600 mg]) with a high-fat breakfast (vs SBF). In the SAD study (400-1600 mg, SBF), mean effective half-life (t1/2(eff) ) of JTK-853 was 8.3 to 10.9 hours, and 20.3 to 27.3 hours in the MAD study (twice daily dosing, fed condition), with 2- to 3-fold accumulation in exposure (AUCtau ). At steady-state, AUCtau increased dose proportionally, and was approximately 2-fold higher with ketoconazole coadministration. Metabolite M2 (equipotent to JTK-853 in vitro) did not contribute significantly to parent drug exposure and decreased with increase in dose, repeated dosing, and ketoconazole coadministration. Trial simulation-based ratios (n = 1000/dose level) of trough JTK-853 plasma concentrations to the in vitro EC90 for HCV genotype 1b were assessed for dose selection in a separate proof-of-concept study in patients. The studies enabled delineation of key drug attributes for further assessments in the target population.

An improved LC-ESI-MS-MS method for simultaneous quantitation of rosiglitazone and N-desmethyl rosiglitazone in human plasma.

A fast, sensitive, and selective method for the simultaneous quantitation of rosiglitazone and N-desmethyl rosiglitazone in human plasma, using rosiglitazone-d(4) and N-desmethyl rosiglitazone-d(4) as the respective internal standards, has been developed and validated. The analytes in human plasma (50 microL sample aliquot) were isolated through supported liquid/liquid extraction (SLE) and separated by isocratic HPLC over a 3-min period. The precursor and product ions were detected by ESI-MS-MS with multiple reaction monitoring (MRM) in a triple quadrupole mass spectrometer. For both rosiglitazone and N-desmethyl rosiglitazone, the lower limit of quantitation (LLOQ) was 1.00 ng/mL, and the quantitation range was 1.00-500 ng/mL (with an average correlation coefficient >0.9990). The intra-assay and inter-assay precision had a maximum %CV of 9.37%, and the accuracy had a maximum %difference from theoretical of 12.7%. This method was applied to a clinical study where 16 healthy volunteers were administered a single dose of 4.0mg rosiglitazone. The pharmacokinetic parameters of rosiglitazone and N-desmethyl rosiglitazone were consistent with the results reported in the literature.

A semimechanistic model of the time-course of release of PTH into plasma following administration of the calcilytic JTT-305/MK-5442 in humans.

JTT-305/MK-5442 is a calcium-sensing receptor (CaSR) allosteric antagonist being investigated for the treatment of osteoporosis. JTT-305/MK-5442 binds to CaSRs, thus preventing receptor activation by Ca(2+) . In the parathyroid gland, this results in the release of parathyroid hormone (PTH). Sharp spikes in PTH secretion followed by rapid returns to baseline are associated with bone formation, whereas sustained elevation in PTH is associated with bone resorption. We have developed a semimechanistic, nonpopulation model of the time-course relationship between JTT-305/MK-5442 and whole plasma PTH concentrations to describe both the secretion of PTH and the kinetics of its return to baseline levels. We obtained mean concentration data for JTT-305/MK-5442 and whole PTH from a multiple dose study in U.S. postmenopausal women at doses of 5, 10, 15, and 20 mg. We hypothesized that PTH is released from two separate sources: a reservoir that is released rapidly (within minutes) in response to reduction in Ca(2+) binding, and a second source released more slowly following hours of reduced Ca(2+) binding. We modeled the release rates of these reservoirs as maximum pharmacologic effect (Emax ) functions of JTT-305/MK-5442 concentration. Our model describes both the dose-dependence of PTH time of occurrence for maximum drug concentration (Tmax ) and maximum concentration of drug (Cmax ), and the extent and duration of the observed nonmonotonic return of PTH to baseline levels following JTT-305/MK-5442 administration.

Population pharmacodynamic parameter estimation from sparse sampling: effect of sigmoidicity on parameter estimates.

The objective of this stimulation study was to evaluate effect of simoidicity of the concentration-effect (C-E) relationship on the efficiency of population parameter estimation from sparse sampling and is a continuation of previous work that addressed the effect of sample size and number of samples on parameters estimation from sparse sampling for drugs with C-E relationship characterized by high sigmoidicity (gamma > 5). The findings are based on observed C-E relationships for two drugs, octreotide and remifentanil, characterized by simple E (max) and sigmoid E (max) models (gamma = ~2.5), respectively. For each model, C-E profiles (100 replicates of 100 subjects each) were simulated for several sampling designs, with four or five samples/individual randomly obtained from within sampling windows based on EC(50)-normalized plasma drug concentrations, PD parameters based on observed population mean values, and inter-individual and residual variability of 30% and 25%, respectively. The C-E profiles were fitted using non-linear mixed effect modeling with the first-order conditional estimation method; variability parameters were described by an exponential error model. The results showed that, for the sigmoid E (max) model, designs with four or five samples reliably estimated the PD parameters (EC(50), E (max), E (0), and gamma), whereas the five-sample design, with two samples in the 2-3 E (max) region, provided in addition more reliable estimates of inter-individual variability; increasing the information content of the EC(50) region was not critical as long as this region was covered by a single sample in the 0.5-1.5 EC(50) window. For the simple E (max) model, because of the shallower profile, enriching the EC(50) region was more important. The impact of enrichment of appropriate regions for the two models can be explained based on the shape (sigmoidicity) of the concentration-effect relationships, with shallower C-E profiles requiring data enrichment in the EC(50) region and steeper curves less so; in both cases, the E (max) region needs to be adequately delineated, however. The results provide a general framework for population parameter estimation from sparse sampling in clinical trials when the underlying C-E profiles have different degrees of sigmoidicity.

Pharmacodynamic parameter estimation: population size versus number of samples.

The purpose of this study was to evaluate the effects of population size, number of samples per individual, and level of interindividual variability (IIV) on the accuracy and precision of pharmacodynamic (PD) parameter estimates. Response data were simulated from concentration input data for an inhibitory sigmoid drug efficacy (E(max)) model using Nonlinear Mixed Effect Modeling, version 5 (NONMEM). Seven designs were investigated using different concentration sampling windows ranging from 0 to 3 EC(50) (EC(50) is the drug concentration at 50% of the E(max)) units. The response data were used to estimate the PD and variability parameters in NONMEM. The accuracy and precision of parameter estimates after 100 replications were assessed using the mean and SD of percent prediction error, respectively. Four samples per individual were sufficient to provide accurate and precise estimate of almost all of the PD and variability parameters, with 100 individuals and IIV of 30%. Reduction of sample size resulted in imprecise estimates of the variability parameters; however, the PD parameter estimates were still precise. At 45% IIV, designs with 5 samples per individual behaved better than those designs with 4 samples per individual. For a moderately variable drug with a high Hill coefficient, sampling from the 0.1 to 1, 1 to 2, 2 to 2.5, and 2.5 to 3 EC(50) window is sufficient to estimate the parameters reliably in a PD study.