Development and validation of a Level A in-vitro in-vivo correlation for tofacitinib modified-release tablets using extrudable core system osmotic delivery technology.

PURPOSE: To determine if a validated Level A in-vitro in-vivo correlation (IVIVC) could be achieved with the extrudable core system (ECS) osmotic tablet platform. Tofacitinib is an oral JAK inhibitor for the treatment of rheumatoid arthritis. METHODS: Fast-, medium-, and slow-release modified-release formulations of 11 mg tofacitinib ECS tablets, and one formulation of 22 mg tofacitinib ECS tablet, were manufactured. In vitro dissolution of the tofacitinib ECS tablets was performed using USP Apparatus 2 (paddles) and in vivo pharmacokinetic (PK) data were obtained from a Phase 1 study in healthy volunteers. A 5 mg immediate-release formulation tablet was included to support deconvolution of the tofacitinib ECS PK tablet data to obtain the in vivo absorption profiles. A linear, piecewise correlation and a simple linear correlation were used to build and validate two IVIVC models. RESULTS: The prediction errors (PEs) for the linear, piecewise correlation met the Food and Drug Administration's criteria for establishing a Level A IVIVC, with a maximum absolute individual internal PE of 4.6%, a maximum absolute average internal PE of 3.9%, and a maximum absolute external PE of 8.4% obtained. CONCLUSIONS: This study demonstrates that the tofacitinib ECS osmotic tablet platform can achieve a Level A IVIVC, similar to other osmotic delivery systems.

Assessment of the Drug Interaction Potential of Ertugliflozin With Sitagliptin, Metformin, Glimepiride, or Simvastatin in Healthy Subjects.

Ertugliflozin, a sodium-glucose cotransporter 2 inhibitor for the treatment of adults with type 2 diabetes mellitus, is expected to be coadministered with sitagliptin, metformin, glimepiride, and/or simvastatin. Four separate open-label, randomized, single-dose, crossover studies were conducted in healthy adults to assess the potential pharmacokinetic interactions between ertugliflozin 15 mg and sitagliptin 100 mg (n = 12), metformin 1000 mg (n = 18), glimepiride 1 mg (n = 18), or simvastatin 40 mg (n = 18). Noncompartmental pharmacokinetic parameters derived from plasma concentration-time data were analyzed using mixed-effects models to assess interactions. Coadministration of sitagliptin, metformin, glimepiride, or simvastatin with ertugliflozin had no effect on area under the plasma concentration-time profile from time 0 to infinity (AUCinf ) or maximum observed plasma concentration (Cmax ) of ertugliflozin (per standard bioequivalence boundaries, 80% to 125%). Similarly, ertugliflozin did not have any impact on AUCinf or Cmax of sitagliptin, metformin, or glimepiride. AUCinf for simvastatin (24%) and simvastatin acid (30%) increased slightly after coadministration with ertugliflozin and was not considered clinically relevant. All treatments were well tolerated. The lack of clinically meaningful pharmacokinetic interactions demonstrates that ertugliflozin can be coadministered safely with sitagliptin, metformin, glimepiride, or simvastatin without any need for dose adjustment.

Distribution, Metabolism, and Excretion of Gedatolisib in Healthy Male Volunteers After a Single Intravenous Infusion.

In this open-label study (NCT02142920), we investigated the distribution, pharmacokinetics, and metabolism of the pan-class-I isoform phosphatidylinositol 3-kinase/mammalian target of rapamycin inhibitor gedatolisib (PF-05212384), following a single intravenous administration in healthy male subjects. A single, 89-mg, intravenous dose of gedatolisib was associated with a favorable safety profile in the 6 healthy subjects evaluated. Peak plasma concentrations for unchanged gedatolisib and total radioactivity were observed at the end of the 30-minute infusion. The only observed drug-related material in plasma was the parent drug, gedatolisib. Terminal half-life for plasma gedatolisib was ∼37 hours. Following the dose, 66%-73% of drug-related material was recovered in the feces. Metabolism of gedatolisib was trace; only 1 oxidative metabolite, M5, was identified in feces (<1% of total dose). Identification of gedatolisib in feces suggests that biliary and/or intestinal secretion of unchanged parent drug significantly contributes to gedatolisib clearance.

Evaluation of a Janus kinase 1 inhibitor, PF-04965842, in healthy subjects: A phase 1, randomized, placebo-controlled, dose-escalation study.

AIMS: To determine the safety, tolerability, pharmacokinetics and pharmacodynamics of the Janus kinase 1-selective inhibitor, PF-04965842. METHODS: This was a phase 1, first-in-human, randomized, double-blind, placebo-controlled, combination single- and multiple-dose escalation, parallel design study in healthy subjects (http://clinicaltrials.gov, NCT01835197). Subjects received a single dose of placebo or 3, 10, 30, 100, 200, 400 or 800 mg PF-04965842 (single ascending dose phase) and placebo or 30 mg once daily (QD), 100 mg QD, 200 mg QD, 400 mg QD, 100 mg twice daily (BID) or 200 mg BID PF-04965842 for 10 consecutive days (multiple ascending dose phase). The primary objective was to determine the safety and tolerability of PF-04965842. RESULTS: Seventy-nine subjects were randomized and received study treatments. There were no deaths or serious adverse events. The most frequent treatment-emergent adverse events were headache (n = 13), diarrhoea (n = 11) and nausea (n = 11). PF-04965842 was absorbed rapidly (median time at which maximum plasma concentration occurred generally ≤1 h following either single- or multiple-dose administration) and eliminated rapidly (mean t½ 2.8-5.2 h after 10 days of QD or BID administration in the multiple ascending dose phase). Increases in maximum plasma concentration and area under the concentration-time curve were dose proportional up to 200 mg (single or total daily doses) with an apparent trend towards greater than proportional increases with higher doses. Less than 4.4% of the dose was recovered unchanged in urine. Changes in pharmacodynamic biomarkers were consistent with the known effects of Janus kinase signalling inhibition. CONCLUSIONS: These results support further evaluation of PF-04965842 for clinical use in patients with inflammatory diseases.

Novel Application of the Two-Period Microtracer Approach to Determine Absolute Oral Bioavailability and Fraction Absorbed of Ertugliflozin.

Ertugliflozin, a sodium glucose cotransporter-2 inhibitor, is approved in the United States for treatment of type 2 diabetes mellitus. A novel two-period study design with 14 C microtracer dosing in each period was used to determine absolute oral bioavailability (F) and fraction absorbed (Fa ) of ertugliflozin. Eight healthy adult men received 100-µg i.v. 14 C-ertugliflozin (400 nCi) dose 1 h after a 15-mg oral unlabeled ertugliflozin dose (period 1), followed by 100 µg 14 C-ertugliflozin orally along with 15 mg oral unlabeled ertugliflozin (period 2). Unlabeled ertugliflozin plasma concentrations were determined using high-performance liquid-chromatography tandem mass spectrometry (HPLC-MS/MS). 14 C-ertugliflozin plasma concentrations were determined using HPLC-accelerator mass spectrometry (AMS) and 14 C urine concentrations were determined using AMS. F ((area under the curve (AUC)p.o. /14 C-AUCi.v. )*(14 C-Dosei.v. /Dosep.o. )) and Fa ((14 C_Total_Urinep.o. /14 C_Total_Urinei.v. )* (14 C-Dosei.v. /14 C-Dosep.o. )) were estimated. Estimates of F and Fa were 105% and 111%, respectively. Oral absorption of ertugliflozin was complete under fasted conditions and F was ∼100%. Ertugliflozin was well tolerated.

Safety, Tolerability, Pharmacokinetics, and Pharmacodynamics of Domagrozumab (PF-06252616), an Antimyostatin Monoclonal Antibody, in Healthy Subjects.

Safety, tolerability, anabolic effects, pharmacokinetics, and pharmacodynamics of single ascending and multiple doses of domagrozumab, an antimyostatin monoclonal antibody, were assessed following intravenous (IV) and subcutaneous (SC) administration in healthy subjects. A range of single ascending dose levels between 1 and 40 mg/kg IV and multiple doses (3 doses) of 10 mg/kg IV were tested (n = 8 per cohort). Additionally, a 3 mg/kg SC (n = 8) cohort also received domagrozumab. Magnetic resonance imaging and whole-body dual-energy x-ray absorptiometry imaging were conducted to investigate the anabolic effects of domagrozumab. Domagrozumab was well tolerated with no severe and 1 non-treatment-related serious adverse event. The most commonly reported adverse events were headache (21 subjects) and fatigue, upper respiratory tract infections, and muscle spasms (10 subjects each). Domagrozumab demonstrated typical IgG1 pharmacokinetics, with slow SC absorption and slow clearance, low volume of distribution, and a long half-life. Target engagement was observed with an increase in extent of myostatin modulation, plateauing at the 20 mg/kg IV dose. Downstream pharmacology following myostatin binding by domagrozumab was only observed in the 10 mg/kg single IV cohort (increase in whole-body lean mass of 5.38% using dual-energy x-ray absorptiometry) and the 10 mg/kg repeat-dose cohort (muscle volume increase of 4.49% using magnetic resonance imaging).

Pharmacokinetic and safety profile of tofacitinib in children with polyarticular course juvenile idiopathic arthritis: results of a phase 1, open-label, multicenter study.

BACKGROUND: Juvenile idiopathic arthritis (JIA) is the most common pediatric rheumatic disease and a leading cause of childhood disability. The objective of this study was to characterize the PK, safety, and taste acceptability of tofacitinib in patients with JIA. METHODS: This Phase 1, open-label, multiple-dose (twice daily [BID] for 5 days) study of tofacitinib in patients with active (≥ 5 joints) polyarticular course JIA was conducted from March 2013-December 2015. Patients were allocated to one of three age-based cohorts: Cohort 1, 12 to < 18 years; Cohort 2, 6 to < 12 years; and Cohort 3, 2 to < 6 years. Tofacitinib was administered according to age and body weight as tablets or oral solution (grape flavor). PK were assessed on Day 5; safety was assessed at screening, Day 1, and Day 5. Taste acceptability of the oral solution was evaluated. RESULTS: Twenty-six patients (age range 2-17 years) were enrolled: Cohort 1, N = 8; Cohort 2, N = 9; Cohort 3, N = 9; median tofacitinib doses were 5.0, 2.5, and 3.0 mg BID, respectively. The higher median tofacitinib dose in Cohort 3 versus Cohort 2 reflected implementation of an amended dosing scheme following an interim PK analysis after Cohort 2 recruitment. Geometric mean AUC at steady state (AUCtau) was 156.6 ng•h/mL in Cohort 1, 118.8 ng•h/mL in Cohort 2, and 142.5 ng•h/mL in Cohort 3; Cmax (ng/mL) was 47.0, 41.7, and 66.2, respectively. Ctrough, Cmin, and t1/2 were similar in Cohorts 2 and 3, but higher in Cohort 1. Median time to Cmax (Tmax) was similar between cohorts. Apparent clearance and volume of distribution decreased with decreasing age. Tofacitinib was well tolerated, with no serious adverse events or discontinuations due to adverse events reported. Taste acceptability was confirmed. CONCLUSIONS: PK findings from this study in children with polyarticular course JIA established dosing regimens and acceptable taste for use in subsequent studies within the tofacitinib pediatric development program. TRIAL REGISTRATION: ClinicalTrials.gov: NCT01513902 .

Confirmation of longer FIX activity half-life with prolonged sample collection after single doses of nonacog alfa in patients with haemophilia B.

A multicentre, single-dose study enrolled 12 previously treated patients with moderately severe to severe (factor IX [FIX] levels ≤2 IU/dl) haemophilia B to assess FIX pharmacokinetics after nonacog alfa administration and to evaluate the impact of length of sampling time on half-life (t½). After refraining from FIX replacement for four days, patients received 50 IU/kg as an intravenous (IV) infusion over 10 minutes. Blood samples were collected predose and 0.25, 0.5, 1, 3, 6, 9, 24, 50, 72, and 96 h post dose. Tolerability and safety were assessed by monitoring adverse events and were subsequently summary tabulated. FIX activity was measured by a one-stage clotting assay with a lower limit of quantification of 0.010 IU/ml, and inhibitors to FIX were measured using the Bethesda assay. Pharmacokinetic parameters were calculated by noncompartmental analysis and were descriptively summarised. Half-life estimates were calculated first using all available data, then excluding 96-h observations (truncated at 72 h) and, finally, excluding both 72- and 96-h observations (truncated at 50 h). No patient was positive for FIX inhibitors. No treatment-emergent adverse events were reported. Prolonging the duration of the sample collection to 96 h resulted in a terminal t½ estimate of 39.6 ±7.4 h in the eight patients aged 18 years and older, which was longer than the estimates obtained using shorter periods of observation: 29.6 ± 5.5 h (truncated at 72 h) and 27.2 ± 7.0 h (truncated at 50 h). To accurately assess an adult patient's t½, sampling should be continued for at least 96 h.

Evaluation of the Effect of Tofacitinib on the Pharmacokinetics of Oral Contraceptive Steroids in Healthy Female Volunteers.

Tofacitinib is an oral Janus kinase inhibitor. Tofacitinib metabolism is primarily mediated by cytochrome P450 3A4. This phase 1 randomized, open-label, 2-way crossover study (NCT01137708) evaluated the effect of tofacitinib 30 mg twice daily on the single-dose pharmacokinetics of combination oral contraceptives ethinylestradiol (EE) and levonorgestrel (LN). EE and LN were administered as a single Microgynon 30® tablet (30 µg EE and 150 µg LN) to 19 healthy women. In the presence of tofacitinib, the area under the curve from time zero to infinity (AUC∞ ) increased by 6.6% and 0.9% for EE and LN, respectively. Maximal plasma concentrations decreased by 10.4% for EE and increased by 12.2% for LN when coadministered with tofacitinib. The 90% confidence intervals for the adjusted geometric mean ratios for AUC∞ fell within the 80%-125% region for both EE and LN. Mean half-life was similar in the presence and absence of tofacitinib: 13.8 and 13.3 hours, respectively, for EE; 25.9 and 25.4 hours, respectively, for LN. Tofacitinib had no clinically relevant net inhibitory or inductive effect on the pharmacokinetics of EE and LN. Therefore, there is no evidence to suggest dose adjustments of oral contraceptive drugs containing EE or LN when coadministered with tofacitinib.

The Pharmacokinetics of Pregabalin in Breast Milk, Plasma, and Urine of Healthy Postpartum Women.

BACKGROUND: Limited data exist on the presence of pregabalin in human breast milk of nursing mothers. OBJECTIVES: This study aimed to determine pregabalin concentrations in breast milk, estimate the infant daily pregabalin dose from nursing mothers, and evaluate pregabalin pharmacokinetic data in lactating women (≥ 12 weeks postpartum). METHODS: In this multiple-dose, open-label, pharmacokinetic study, 4 doses of pregabalin 150 mg were administered orally at 12-hour intervals. Urine, blood, and breast milk samples were collected up to 12, 24, and 48 hours, respectively, following the fourth dose. Pharmacokinetic parameters were estimated using noncompartmental methods. Adverse events were monitored throughout. RESULTS: Ten healthy lactating women (age 24-37 years) received pregabalin. Geometric mean pregabalin Cmaxss and AUCτ values in breast milk were approximately 53% and 76%, respectively, of those for plasma. The mean amount of pregabalin in breast milk recovered in a 24-hour period after the last dose was 574 µg (range, 270-1720 µg), which is approximately 0.2% of the administered daily maternal dose of 300 mg. The estimated average daily infant dose of pregabalin from breast milk was 0.31 mg/kg/day, which would be approximately 7% (23% coefficient of variation) of the body weight normalized maternal dose. Approximately 89% of the dose administered was recovered in urine. Renal clearance averaged 68.2 mL/min. Adverse events were of mild or moderate severity. CONCLUSION: Lactation appears to have had little influence on pregabalin pharmacokinetics. Overall, the estimated dose of pregabalin in breastfed children of women receiving pregabalin is low. Pregabalin was well tolerated in lactating women. DECLARATION OF CONFLICTING INTERESTS: The authors declared the following potential conflicts of interest with respect to the research, authorship, and/or publication of this article: Peter A. Lockwood, Lynne Pauer, Joseph M. Scavone, Maud Allard, Laure Mendes da Costa, Tanja Alebic-Kolbah, Anna Plotka, Christine W. Alvey, and Marci L. Chew were all full-time employees of Pfizer at the time the study was completed and hold stock and/or stock options in Pfizer. FUNDING: The authors disclosed receipt of the following financial support for the research, authorship, and/or publication of this article: This study was sponsored by Pfizer, which was involved in the study design, the collection, analysis, and interpretation of the data, the writing of the report, and the decision to submit the paper for publication. Medical writing support was provided by Penny Gorringe, MSc, of Engage Scientific Solutions and funded by Pfizer.

Extended-Release Once-Daily Formulation of Tofacitinib: Evaluation of Pharmacokinetics Compared With Immediate-Release Tofacitinib and Impact of Food.

Tofacitinib is an oral Janus kinase inhibitor for the treatment of rheumatoid arthritis. An extended-release (XR) formulation has been designed to provide a once-daily (QD) dosing option to patients to achieve comparable pharmacokinetic (PK) parameters to the twice-daily immediate-release (IR) formulation. We conducted 2 randomized, open-label, phase 1 studies in healthy volunteers. Study A characterized single-dose and steady-state PK of tofacitinib XR 11 mg QD and intended to demonstrate equivalence of exposure under single-dose and steady-state conditions to tofacitinib IR 5 mg twice daily. Study B assessed the effect of a high-fat meal on the bioavailability of tofacitinib from the XR formulation. Safety and tolerability were monitored in both studies. In study A (N = 24), the XR and IR formulations achieved time to maximum plasma concentration at 4 hours and 0.5 hours postdose, respectively; terminal half-life was 5.9 hours and 3.2 hours, respectively. Area under plasma concentration-time curve (AUC) and maximum plasma concentration (Cmax ) after single- and multiple-dose administration were equivalent between the XR and IR formulations. In study B (N = 24), no difference in AUC was observed for fed vs fasted conditions. Cmax increased by 27% under the fed state. On repeat administration, negligible accumulation (<20%) of systemic exposures was observed for both formulations. Steady state was achieved within 48 hours of dosing with the XR formulation. Tofacitinib administration as an XR or IR formulation was generally well tolerated in these studies.

Effect of the gastrointestinal prokinetic agent erythromycin on the pharmacokinetics of pregabalin controlled-release in healthy individuals: a phase I, randomized crossover trial.

BACKGROUND AND OBJECTIVES: The controlled-release (CR) formulation of pregabalin is designed to remain in the stomach for a prolonged period while slowly releasing pregabalin for absorption in the small intestine. This study evaluated the effect of the gastrointestinal prokinetic agent, erythromycin, on the pharmacokinetics of a single dose of pregabalin CR 330 mg administered following an evening meal and the safety and tolerability of a single dose of pregabalin CR 330 mg when administered with and without multiple doses of erythromycin 500 mg. METHODS: This was a phase I, open-label, randomized, two-period, two-treatment crossover study. Participants received (in a randomized sequence) a single oral dose of pregabalin CR 330 mg alone and pregabalin CR 330 mg co-administered with multiple doses of erythromycin 500 mg. The CR formulation was administered immediately following a standardized 600-750 calorie 30 % fat evening meal. Erythromycin 500 mg was administered orally approximately 1 h prior to pregabalin CR, as well as 6 and 12 h following the first erythromycin dose. Blood samples were collected up to 48 h post-pregabalin CR dose. Pharmacokinetic parameters were estimated from concentration-time data using standard noncompartmental methods. Adverse events were monitored throughout. RESULTS: Eighteen healthy participants (aged 19-52 years) received pregabalin CR. Co-administration of pregabalin CR with erythromycin resulted in a 17 % decrease in total exposure [area under the plasma concentration-time curve from zero to infinity (AUC∞)] and a 13 % decrease in peak plasma concentrations (C max) relative to pregabalin CR administered alone. The 90 % CI for the ratio of the adjusted geometric mean AUC∞ was 76.5-89.2 % (outside the 80-125 % range prespecified for bioequivalence). Adverse events were of mild to moderate severity and the adverse event profile was similar for pregabalin CR administered with and without erythromycin. CONCLUSION: Co-administration of multiple high doses of erythromycin resulted in 17 % lower pregabalin exposure for a single dose of pregabalin CR 330 mg than for pregabalin CR 330 mg administered alone. Although the two treatments did not achieve formal bioequivalence, the impact of co-administered erythromycin treatment was small and not considered clinically relevant.

Single- and multiple-dose pharmacokinetics of tofacitinib in healthy Chinese volunteers.

Tofacitinib is an oral Janus kinase inhibitor. The objective of this phase 1, open-label study was to characterize the single- and multiple-dose pharmacokinetics (PK) of tofacitinib in 12 healthy, adult Chinese volunteers. Eligible subjects received oral tofacitinib 10 mg once daily on days 1 and 6 and twice daily on days 2-5. Blood samples were collected on day 1 predose and over 24 hours postdose (day 2 predose), predose on days 3-6, and over 12 hours postdose on day 6. PK parameters were calculated using noncompartmental analysis. Mean concentration-time profiles for days 1 and 6 were similar, with median time to peak concentration of 0.5 hours on both days. Plasma concentrations declined rapidly following attainment of peak concentrations, with a mean terminal half-life of 3.3 hours on day 1 (single dose) and 2.5 hours on day 6 (multiple dose). No accumulation in plasma occurred with twice-daily administration: accumulation ratio of 1.04. The rapid absorption, elimination, and systemic exposures (peak and area under the concentration-time curve) observed in healthy Chinese volunteers in this study are similar to those previously reported in white subjects.

Safety, tolerability, and pharmacokinetics of pregabalin in children with refractory partial seizures: a phase 1, randomized controlled study.

OBJECTIVE: To evaluate the safety, tolerability, and pharmacokinetics (PK) of pregabalin as adjunctive therapy in children with refractory partial seizures. METHODS: This was a phase 1, randomized, placebo-controlled, parallel-group, escalating-dose, multiple-dose study comprising a 7-day, double-blind treatment period and a single-blind, single dose of pregabalin administered to all children on day 8. Children in four age cohorts (1-23 months, 2-6, 7-11, and 12-16 years) received one of four doses of pregabalin (2.5, 5, 10, or 15 mg/kg/day) or placebo. Safety and tolerability were assessed throughout the study. Steady-state and single-dose PK parameters on day 8 were analyzed using standard noncompartmental procedures. RESULTS: Sixty-five children received at least one dose of treatment. Four pregabalin-treated children discontinued treatment, three of whom received 15 mg/kg/day. Two children experienced serious adverse events, one of whom received pregabalin 15 mg/kg/day. During double-blind treatment, the most common adverse events reported in the pregabalin-treated population were somnolence (27.1%) and dizziness (12.5%). Steady-state pregabalin peak and total exposure in each age cohort appeared to increase linearly with dose. Apparent oral clearance (CL/F) was directly related to creatinine clearance, consistent with adults. CL/F normalized for body weight was 43% higher in patients weighing <30 kg. Steady-state and single-dose PK were consistent. SIGNIFICANCE: Pregabalin at doses up to 10 mg/kg/day in children aged 1 month to 16 years, and at doses up to 15 mg/kg/day in those aged <6 years, demonstrated acceptable safety and tolerability. For children weighing <30 kg, a dose increase of 40% (mg/kg dosing) is required to achieve comparable exposure with adults or children weighing ≥30 kg. These data will inform dose selection in phase 3 trials of the efficacy and safety of adjunctive pregabalin in children with refractory partial seizures.

Pharmacokinetics of pregabalin controlled-release in healthy volunteers: effect of food in five single-dose, randomized, clinical pharmacology studies.

BACKGROUND: The pharmacokinetic properties of the immediate-release (IR) and the recently developed controlled-release (CR) formulation of pregabalin are dose proportional. Pregabalin IR can be taken with or without food. OBJECTIVES: This analysis characterizes the effect of food on pregabalin CR. The objectives of this analysis were: (1) to evaluate the effect of administration time and fat or caloric content of an accompanying meal on the pharmacokinetic properties of a single dose of pregabalin CR (330 mg) relative to a single dose of pregabalin IR (300 mg); (2) to evaluate the pharmacokinetic properties of a single dose of pregabalin CR administered fasted relative to a single dose of pregabalin CR administered immediately after food; and (3) to determine the safety and tolerability of single-dose administration of pregabalin CR and IR with and without food. METHODS: The effect of food on the pharmacokinetic properties of pregabalin CR was determined in five phase I, open-label, single-dose, crossover studies (24-28 participants/study). Caloric and fat content of meals were varied and treatments were administered in the morning, at midday, or in the evening. Blood samples were collected up to 48 h post-dose. Pharmacokinetic parameters were estimated from plasma concentration-time data using standard noncompartmental methods. Adverse events were monitored throughout all studies. RESULTS: One hundred and twenty-eight healthy participants (19-54 years of age) received pregabalin. Peak plasma concentrations (C max) were lower for CR than the respective pregabalin IR doses, and time to C max occurred later. When pregabalin CR was administered with food at midday or in the evening, total exposures [area under the plasma concentration-time curve from time zero extrapolated to infinite time (AUC∞)] were equivalent for pregabalin CR and IR formulations regardless of fat or caloric content. When pregabalin CR was administered with an 800-1,000 calorie medium-fat breakfast, AUC∞ was equivalent for pregabalin CR and IR. Bioequivalence criteria for comparison of pregabalin CR after a low- or medium-calorie breakfast relative to pregabalin IR were not met; however, bioavailability of the pregabalin CR vs. IR formulation was relatively high (75-86 %). When pregabalin CR was administered fasted, the AUC∞ was 70-78 % of the AUC∞ of pregabalin CR administered with food and bioequivalence criteria were not met. Additionally, the AUC∞ of the pregabalin CR formulation administered fasted was 62-69 % of that of pregabalin IR administered fasted and bioequivalence criteria were not met. Single-dose pregabalin CR and IR were well tolerated in all studies, with no serious or severe adverse events reported. CONCLUSION: Time of day of administration and the fat and caloric content of the accompanying meal had minimal overall effect on the pharmacokinetic properties and bioavailability of the pregabalin CR formulation.

Pregabalin controlled-release pharmacokinetics in healthy volunteers: analysis of four multiple-dose randomized clinical pharmacology studies.

BACKGROUND: Pregabalin (Lyrica(®)) is approved as an immediate-release (IR) formulation for administration twice (BID) or three times (TID) a day depending on indication. Once daily (QD) dosing may be appropriate for ease of clinical use and patient convenience. OBJECTIVES: The objectives of this analysis were: (1) to evaluate the pharmacokinetics of pregabalin controlled-release (CR) administered with food relative to the pregabalin IR formulation administered fasted; (2) to evaluate the pharmacokinetics of a two-tablet dose of pregabalin CR compared with the equivalent one-tablet dose of pregabalin CR; and (3) to determine the safety and tolerability of multiple-dose administration of pregabalin CR and IR. METHODS: The pharmacokinetic properties of pregabalin CR were determined in four phase I, open-label, multiple-dose crossover studies (18-24 participants/study). Pregabalin CR (82.5, 165, 330 or 660 mg/day) administered QD was compared with pregabalin IR (75, 150, 300 or 600 mg/day, respectively) administered either BID or TID. Blood samples were collected up to 24 h post-dose. Pharmacokinetic parameters were estimated from plasma concentration-time data using standard noncompartmental methods. Adverse events were monitored throughout all studies. RESULTS: Eight-four healthy participants (19-55 years of age) received pregabalin. For all pregabalin CR doses, total exposure was equivalent to the corresponding pregabalin IR dose. Relative bioavailability of pregabalin CR was 93-97 % of pregabalin IR, and bioequivalence criteria with respect to the 24-h steady-state exposure (area under the plasma concentration-time curve from 0 to 24 h [AUC24]) were met. Administration of a two-tablet dose of pregabalin CR was bioequivalent to one-tablet pregabalin CR. The relative bioavailability of two-tablet pregabalin CR was 97-102 % of one-tablet pregabalin CR, and bioequivalence criteria with respect to AUC24 and peak plasma concentrations were met. Pregabalin CR pharmacokinetic parameters were dose proportional following administration of 82.5-660 mg/day pregabalin CR. Pregabalin was well tolerated across studies, with no serious or severe adverse events. CONCLUSION: Total daily exposure with multiple-dose pregabalin CR is equivalent to the corresponding pregabalin IR dose.

Evaluation of the effect of fluconazole and ketoconazole on the pharmacokinetics of tofacitinib in healthy adult subjects.

Tofacitinib is a novel, oral JAK inhibitor that is being investigated as a targeted immunomodulator. Tofacitinib is predominantly metabolized by cytochrome P450 (CYP) 3A4 and to a lesser extent by CYP2C19. Two Phase 1, randomized, open-label, single sequence studies in 24 healthy subjects (12 per study) characterized the effects of fluconazole (moderate CYP3A4/potent CYP2C19 inhibitor) and ketoconazole (potent CYP3A4 inhibitor) on tofacitinib pharmacokinetics. In the fluconazole study, subjects received a single tofacitinib 30 mg dose. After 72 hours, subjects received fluconazole 400 mg, followed by 200 mg once daily (QD; days 2-7) plus tofacitinib 30 mg on day 5. In the ketoconazole study, a single tofacitinib 10 mg dose was administered. After 24 hours, subjects received ketoconazole (400 mg QD; days 1-3) plus tofacitinib 10 mg on day 3. Treatment comparisons were made using mixed-effect models. Tofacitinib area under the curve and maximal plasma concentration increased by 79% and 27%, respectively, with fluconazole co-administration and by 103% and 16%, respectively, with ketoconazole co-administration. Tofacitinib half-life increased by approximately 1 hour during co-administration with fluconazole or ketoconazole. Co-administration of moderate to potent CYP3A4 inhibitors is likely to increase the systemic exposure of tofacitinib and thus may warrant dosage adjustments or restrictions.

The effect of mild and moderate hepatic impairment on the pharmacokinetics of tofacitinib, an orally active Janus kinase inhibitor.

Tofacitinib is an oral Janus kinase inhibitor for the treatment of rheumatoid arthritis. We report here an evaluation of the pharmacokinetics of a single 10 mg dose of tofacitinib in healthy volunteers (n = 6) and subjects with mild (n = 6) or moderate (n = 6) hepatic impairment. Compared to healthy volunteers, tofacitinib area under the plasma concentration-time profile from time 0 to infinity (AUCinf ) and maximum observed concentration (Cmax ) in subjects with mild hepatic impairment were not altered. In subjects with moderate hepatic impairment, the geometric mean AUCinf and Cmax of tofacitinib were increased (90% confidence intervals of percentage increase) by approximately 65% (25%, 117%) and 49% (12%, 97%), respectively. A single dose of tofacitinib 10 mg resulted in two treatment-emergent adverse events (AE) in the mild hepatic impairment group, and one in the moderate hepatic impairment group; they were not considered related to study treatment. There were no deaths, serious AEs, discontinuations due to AEs, or dose reductions due to AEs. Data from this study were critical to deriving dose adjustments for subjects with hepatic impairment.

Evaluation of the potential interaction between tofacitinib and drugs that undergo renal tubular secretion using metformin, an in vivo marker of renal organic cation transporter 2.

Tofacitinib is a novel, oral Janus kinase inhibitor. The potential for drug-drug interactions (DDIs) between tofacitinib and drugs that undergo renal tubular secretion was evaluated using metformin as a probe transporter substrate, and genotyping for organic cation transporter (OCT) 1, OCT2 and multidrug and toxin extrusion 1 polymorphisms. Twenty-four healthy male subjects completed this open-label, fixed-sequence study. Subjects were administered a single oral metformin 500 mg dose on Days 1 and 4, and multiple oral tofacitinib 30 mg twice daily doses on Days 2, 3, and 4. Subjects underwent serial blood and urine samplings (Days 1 and 4) to estimate metformin pharmacokinetics. A single blood sample for tofacitinib was collected 2 hours after the morning dose (Day 4). The 90% confidence intervals for the ratios of maximum plasma concentration, area under the curve and renal clearance of metformin, with and without tofacitinib, were contained within the 80-125% acceptance range commonly used to establish a lack of DDI. No deaths, serious adverse events (AEs), severe AEs or discontinuations due to AEs were reported. The study confirms tofacitinib is unlikely to impact the pharmacokinetics of drugs that undergo renal tubular secretion, and concurs with its weak in vitro OCT2 inhibitory profile.

A phase I, open-label, mass balance study of [(14)C] dacomitinib (PF-00299804) in healthy male volunteers.

PURPOSE: This study aimed to characterize the primary routes of elimination of the pan-HER tyrosine kinase inhibitor, dacomitinib (PF-00299804), to evaluate the pharmacokinetics of total radioactivity and of dacomitinib and to identify the metabolites of dacomitinib in plasma, urine, and feces in the healthy volunteers. METHODS: Six male healthy volunteers (mean age 31.5 years) received a single 45-mg oral dose containing ~100 µCi [(14)C] dacomitinib. Whole blood, urine, and fecal samples were collected throughout the study and analyzed for total radioactivity by liquid scintillation counting. Safety evaluations included vital signs, 12-lead ECGs, safety laboratory tests, and monitoring of adverse events. RESULTS: 78.8 % of the radiolabeled material was excreted in feces, and 3.2 % was recovered in urine. Peak concentrations of dacomitinib in plasma occurred 12 h (median) after oral dosing. Mean terminal plasma half-life was 55 and 182 h for dacomitinib and total plasma radioactivity, respectively. Geometric mean C max was approximately 2-fold higher, and total exposure (AUCinf) was almost 6-fold higher for total radioactivity than for dacomitinib in plasma. O-desmethyl dacomitinib (PF-05199265) was the major circulating metabolite. T max of this metabolite occurred 6 h after oral dosing with dacomitinib. Plasma exposure for the metabolite was one-third that of the parent compound. There were no serious/severe adverse events or deaths during the study. Dacomitinib was well tolerated. CONCLUSIONS: In humans, [(14)C] dacomitinib underwent oxidative and conjugative metabolism. Most of the administered dose was eliminated via the fecal route, and the major circulating metabolite was PF-05199265.