A Randomized, Multicenter, Blinded Pilot Study Assessing the Effects of Gaseous Nitric Oxide in an Ex Vivo System of Human Lungs.

INTRODUCTION: Normothermic ex vivo lung perfusion (EVLP) is used to evaluate and condition donor lungs for transplantation. The objective of this study was to determine whether administration of exogenous nitric oxide during EVLP contributes to improvement of lung health. METHODS: A multicenter, blinded, two-arm, randomized pilot study evaluated the effect of gaseous nitric oxide (gNO) administered during EVLP on donor lungs rejected for transplantation. gNO introduced into the perfusate at 80 parts per million (ppm) was compared with perfusate alone (P). An open-label substudy assessed inhaled nitric oxide gas (iNO) delivered into the lungs at 20 ppm via a ventilator. Primary endpoints were an aggregate score of lung physiology indicators and total duration of stable EVLP time. Secondary endpoints included assessments of lung weight and left atrium partial pressure of oxygen (LAPO2). RESULTS: Twenty bilateral donor lungs (blinded study, n = 16; open-label substudy, n = 4) from three centers were enrolled. Median (min, max) total EVLP times for the gNO, P, and iNO groups were 12.4 (8.6, 12.6), 10.6 (6.0, 12.4), and 12.4 (8.7, 13.0) hours, respectively. In the blinded study, median aggregate scores were higher in the gNO group compared to the P group at most time points, suggesting better lung health with gNO (median score range [min, max], 0-3.5 [0, 7]) vs. P (0-2.0 [0, 5] at end of study). In the substudy, median aggregate scores did not improve for lungs in the iNO group. However, both the gNO and iNO groups showed improvements in lung weight and LAPO2 compared to the P group. CONCLUSIONS: The data suggest that inclusion of gNO during EVLP may potentially prolong duration of organ stability and improve donor lung health, which warrants further investigation.

Pharmacokinetics and Pharmacodynamics of Repository Corticotropin Injection Compared With Synthetic ACTH1-24 Depot and Methylprednisolone in Healthy Subjects.

Repository corticotropin injection (RCI; Acthar Gel) is a naturally sourced complex mixture of adrenocorticotropic hormone (ACTH) analogs and other pituitary peptides. This phase 1, single-center, open-label, randomized parallel study directly compared the pharmacokinetics and pharmacodynamics of RCI and synthetic ACTH1-24 depot. Methylprednisolone was included to estimate the steroidogenic exposure of RCI and synthetic ACTH1-24 depot when used to treat nephrotic syndrome. A total of 48 healthy subjects aged 18 to 50 years were randomly assigned 1:1:1 to RCI (80 IU subcutaneously twice weekly on study days 1 and 4), synthetic ACTH1-24 depot (1 mg subcutaneously twice weekly on study days 1 and 4), or methylprednisolone (32 mg orally once daily on study days 1 through 6). After 2 doses, RCI induced about 5-fold lower free cortisol exposure and an estimated 4-fold lower steroidogenic exposure than synthetic ACTH1-24 depot. The lower endogenous cortisol response of RCI was achieved despite higher observed mean plasma concentrations of N25-deamidated porcine ACTH1-39 (the pharmacokinetic marker for RCI) than of ACTH1-24 . The different pharmacodynamic properties demonstrated by RCI and synthetic ACTH1-24 depot in this study suggest that these products in the ACTH class are not interchangeable.

A phase I study of the WT2725 dosing emulsion in patients with advanced malignancies.

WT2725 is a Wilms' tumor gene 1 (WT1)-derived-oligopeptide vaccine designed to induce WT1-specific cytotoxic T-lymphocytes against WT1+ tumors in human leukocyte antigen (HLA)-A*0201+ and/or HLA-A*0206+ patients. Here, we report the results of a phase I study of WT2725. In this phase I, open-label, dose-escalation and expansion two-part study, the WT2725 dosing emulsion was administered as a monotherapy to patients with advanced malignancies known to overexpress WT1, including glioblastoma. In part 1, 44 patients were sequentially allocated to four doses: 0.3 mg (n = 5), 0.9 mg (n = 5), 3 mg (n = 6), and 9 mg (n = 28). In part 2, 18 patients were allocated to two doses: 18 mg (n = 9) and 27 mg (n = 9). No dose-limiting toxicities were observed, so the maximum tolerated dose was not reached. Median progression-free survival was 58 (95% confidence interval [CI] 56-81) days (~ 2 months) across all patients with solid tumors; median overall survival was 394 days (13.0 months) (95% CI 309-648). Overall immune-related response rate in solid tumor patients was 7.5% (95% CI 2.6-19.9); response was most prominent in the glioblastoma subgroup. Overall, 62.3% of patients were considered cytotoxic T-lymphocyte responders; the proportion increased with increasing WT2725 dosing emulsion dose. WT2725 dosing emulsion was well tolerated. Preliminary tumor response and biological marker data suggest that WT2725 dosing emulsion may exert antitumor activity in malignancies known to overexpress the WT1 protein, particularly glioblastoma, and provide a rationale for future clinical development.Trial registration: NCT01621542.

Exposures of Phenylacetic Acid and Phenylacetylglutamine Across Different Subpopulations and Correlation with Adverse Events.

BACKGROUND: Elevated plasma ammonia is central to the pathogenesis of hepatic encephalopathy. Sodium phenylacetate or glycerol phenylbutyrate is approved for urea cycle disorders, but limited clinical data are available for hepatic encephalopathy. Phenylacetic acid (PAA) plasma exposure has been reported to correlate with neurologic adverse events in patients with cancer but not in patients with urea cycle disorders or hepatic encephalopathy. Ornithine phenylacetate, an intravenous dosage form of the L-ornithine salt of phenylacetate, is under development for hepatic encephalopathy. OBJECTIVE: This analysis summarized the pharmacokinetics and safety of ornithine phenylacetate to support the dosing strategy and to assist with the monitoring and management of neurologic adverse events in a global clinical development program. METHODS: Phenylacetic acid and phenylacetylglutamine (PAGN) pharmacokinetic data and adverse events from five clinical studies were included in the analysis. Hepatic and renal dysfunction were assessed by baseline Child-Pugh score and creatinine clearance, respectively. Predicted plasma exposures of PAA at the occurrence of neurologic adverse events were used for exposures and neurologic adverse event analysis. RESULTS: Phenylacetic acid exhibited nonlinear pharmacokinetics. Phenylacetic acid exposure was 35% higher in Child-Pugh C than in Child-Pugh B. No significant pharmacokinetic difference was identified between Caucasian and Asian subjects after body weight adjustment. Phenylacetylglutamine renal clearance decreased by five-fold in severe renal impairment compared with subjects with normal renal function. Renal dysfunction significantly elevated PAGN plasma concentrations; however, elevated PAGN due to reduced excretion of PAGN did not change PAA exposure and plasma ammonia levels. No correlation was observed between PAA plasma exposure and neurologic adverse events in patients with stable cirrhosis or acute hepatic encephalopathy. CONCLUSIONS: Dose adjustment should be considered for patients with low body weight and severely impaired hepatic function. Phenylacetic acid plasma exposure was not correlated with neurologic adverse events in the ornithine phenylacetate target patient population.

Comparison of Steroidogenic Exposure Following the Administration of Repository Corticotropin Injection With a Synthetic ACTH1-24 Depot and Methylprednisolone in Healthy Subjects.

The pharmacokinetics (PK) and pharmacodynamics (PD) of clinically relevant doses of repository corticotropin injection (Acthar Gel) and synthetic ACTH1-24 depot have not been fully characterized. We compared the steroidogenic exposure of repository corticotropin injection and synthetic ACTH1-24 depot in healthy adults at therapeutic doses using data from 2 separate phase 1 studies. Subjects were randomly assigned to repository corticotropin injection 40 or 80 IU subcutaneously twice weekly or 80 IU subcutaneously 3 times weekly for 15 days or to daily synthetic ACTH1-24 depot doses of 0.5 mg subcutaneously, 0.75 mg subcutaneously, 1 mg subcutaneously, or 1 mg intramuscularly for 5 days. A population PK/PD model was developed to simulate the free cortisol exposure of a clinically relevant dose of synthetic ACTH1-24 depot (1 mg subcutaneously twice weekly). Study drug doses were converted to methylprednisolone-equivalent doses using the steroidogenic exposure of methylprednisolone 16 mg daily as a conversion factor. Doses were also converted to prednisone equivalents using a coefficient of 1.25. These analyses revealed that the steroidogenic exposure of repository corticotropin injection at clinically relevant doses was substantially lower than that for synthetic ACTH1-24 depot. The 3 repository corticotropin injection regimens were equivalent to approximately 5, 8, and 16 mg of daily prednisone, respectively. On the basis of simulated free cortisol exposure, synthetic ACTH1-24 depot 1 mg subcutaneously twice weekly was comparable to 57 mg of daily prednisone. These results suggest that repository corticotropin injection has pharmacological effects that cannot be considered identical to synthetic ACTH1-24 depot.

Lurasidone drug-drug interaction studies: a comprehensive review.

BACKGROUND: To evaluate potential drug-drug interactions with the atypical antipsychotic lurasidone. METHODS: Seven phase I studies were conducted to investigate the effects of repeated dosing of ketoconazole, diltiazem, rifampin, or lithium on the pharmacokinetics (PK) of single oral doses of lurasidone, or the effects of repeated dosing of lurasidone on the PK of digoxin, midazolam, or the oral contraceptive norgestimate/ethinyl estradiol. Two 6-week, phase III studies included evaluation of the potential for interaction between lurasidone and lithium or valproate. Maximum serum or plasma concentration (Cmax) and area under the concentration-time curve (AUC) were calculated. RESULTS: Concomitant ketoconazole administration resulted in a 6.8-fold increase in lurasidone Cmax and a 9.3-fold increase in lurasidone AUC; concomitant diltiazem administration resulted in 2.1- and 2.2-fold increases, respectively. Rifampin decreased lurasidone Cmax and AUC (one-seventh and one-fifth of lurasidone alone, respectively). Steady-state dosing with lurasidone increased Cmax and AUC0-24 (AUC from time 0 to 24 h postdose) of digoxin by 9% and 13%, respectively, and of midazolam by 21% and 44%, respectively. There were no significant interactions between lurasidone and lithium, valproate, ethinyl estradiol, or norelgestromin (the major active metabolite of norgestimate). CONCLUSIONS: Lurasidone PK is altered by strong cytochrome P450 (CYP) 3A4 inhibitors or inducers, and coadministration is contraindicated; whereas moderate CYP3A4 inhibitors have less effect, and lurasidone dosage restrictions are recommended. No dose adjustment for lurasidone is needed when administered with lithium or valproate. Dose adjustment is not required for lithium, valproate, digoxin (a P-glycoprotein substrate), or midazolam or oral contraceptives (CYP3A4 substrates) when coadministered with lurasidone.

Pharmacokinetics of continuous once-a-week combination 17ß-Estradiol/Low- or high-dose levonorgestrel transdermal delivery systems in postmenopausal women.

Two open-label, randomized, two-period, crossover studies were performed to determine the safety, delivery rates, and pharmacokinetic properties of a combination estradiol (E2)/levonorgestrel (LNG) transdermal delivery system (TDS). Study 1 enrolled 24 postmenopausal women who received a single TDS containing 4.4 mg E2 and 1.39 mg of LNG (E2/LNG Low) or E2 0.050 mg/24 hours TDS and 0.090 mg LNG oral tablet. Study 2 enrolled 44 postmenopausal women who received either E2/LNG Low or TDS containing 4.4 mg E2 and 2.75 mg LNG (E2/LNG High) weekly for a period of 4 weeks. E2, estrone (E1), LNG, and sex hormone-binding globulin (SHBG) serum concentrations were determined. Overall, both E2/LNG TDS were well tolerated and had excellent adhesion properties. The average daily delivery for E2/LNG Low was 0.045 mg for E2 and 0.0132 mg for LNG. Following weekly delivery of E2/LNG Low or High for 4 weeks, the combination of E2 with two different strengths of LNG did not alter the pharmacokinetic profile of E2. SHBG, total cholesterol, and triglycerides concentrations significantly decreased compared to baseline. Both E2/LNG Low and High TDSs were well tolerated and provided continuous drug delivery over 7 days supporting the benefits of the transdermal route of administration in optimally delivering hormonal therapy.

Effect of food on the pharmacokinetics of lurasidone: results of two randomized, open-label, crossover studies.

OBJECTIVE: This study aimed to investigate the effect of prandial status and caloric and fat composition of meals on the pharmacokinetics of lurasidone. METHODS: Two randomized, open-label, crossover studies were conducted in clinically stable adults with schizophrenia or schizoaffective disorder. Study 1 (n = 16) evaluated the effect of fasting and three meal types (100 kcal/medium fat, 200 kcal/medium fat, and 800-1000 kcal/high fat), and Study 2 (n = 26) evaluated the effect of fasting and five meal types (350 kcal/high fat, 500 kcal/low fat, 500 kcal/high fat, 800-1000 kcal/low fat, and 800-1000 kcal/high fat) on the bioavailability of lurasidone. Subjects received lurasidone 120 mg once daily. Maximum serum concentration (Cmax ) and area under the serum concentration-time curve over the dosing interval (AUC0-tau ) were determined on Day 5 for each meal type. RESULTS: In Study 1, the geometric mean Cmax in the fasted state was 56.7 ng/mL compared with 123.0 ng/mL for the 800- to 1000-kcal meal; mean AUC0-tau was 360.0 versus 752.4 ng·h/mL (both p < 0.001). Lurasidone exposure following meals containing 100 and 200 kcal was substantially lower than with meals containing 800-1000 kcal. In Study 2, the geometric mean Cmax was 52.9 ng/mL in the fasted state, 161 ng/mL for the 350-kcal/high-fat meal, 135 ng/mL for the 500-kcal/high-fat meal, and 131 ng/mL for the 800- to 1000-kcal/high-fat meal; mean AUC0-tau was 390, 743, 727, and 769 ng·h/mL, respectively. For all comparisons, the 90% confidence interval of the fed to fasted ratios indicated nonequivalence. Lurasidone exposure was similar following meals containing 350-1000 kcal and was independent of fat content. CONCLUSION: Lurasidone should be administered with food-at least 350 kcal-to ensure maximum exposure.

Species differences in the formation of vabicaserin carbamoyl glucuronide.

Vabicaserin is a potent 5-hydroxtryptamine 2C full agonist with therapeutic potential for a wide array of psychiatric disorders. Metabolite profiles indicated that vabicaserin was extensively metabolized via carbamoyl glucuronidation after oral administration in humans. In the present study, the differences in the extent of vabicaserin carbamoyl glucuronide (CG) formation in humans and in animals used for safety assessment were investigated. After oral dosing, the systemic exposure ratios of CG to vabicaserin were approximately 12 and up to 29 in monkeys and humans, respectively, and the ratios of CG to vabicaserin were approximately 1.5 and 1.7 in mice and dogs, respectively. These differences in systemic levels of CG are likely related to species differences in the rate and extent of CG formation and elimination. Whereas CG was the predominant circulating metabolite in humans and a major metabolite in mice, dogs, and monkeys, it was a relatively minor metabolite in rats, in which oxidative metabolism was the major metabolic pathway. Although the CG was not detected in plasma or urine of rats, approximately 5% of the dose was excreted in bile as CG in the 24-h collection postdose, indicating the rat had the metabolic capability of producing the CG. In vitro, in a CO(2)-enriched environment, the CG was the predominant metabolite in dog and human liver microsomes, a major metabolite in monkey and mice, and only a very minor metabolite in rats. Carbamoyl glucuronidation and hydroxylation had similar contributions to vabicaserin metabolism in mouse and monkey liver microsomes. However, only trace amounts of CG were formed in rat liver microsomes, and other metabolites were more prominent than the CG. In conclusion, significant differences in the extent of formation of the CG were observed among the various species examined. The exposure ratios of CG to vabicaserin were highest in humans, followed by monkeys, then mice and dogs, and lowest in rats, and the in vitro metabolite profiles generally correlated well with the in vivo metabolites.

Pharmacokinetics and pharmacodynamics of drospirenone-estradiol combination hormone therapy product coadministered with hydrochlorothiazide in hypertensive postmenopausal women.

The effects of combination hormone therapy of drospirenone (DRSP), a novel progestin with antialdosterone properties, and 17beta-estradiol (E2) on hydrochlorothiazide (HCTZ) pharmacokinetics/pharmacodynamics versus placebo were investigated in a double-blind, placebo-controlled, crossover study. Thirty-six postmenopausal women with stage 1 hypertension maintained on 25 mg of HCTZ once daily were randomized to receive either 3 mg of DRSP/1 mg of E2 or placebo once daily for 4 weeks. Plasma HCTZ, serum DRSP, E2, potassium, aldosterone, and plasma renin activity were determined at baseline and after 4 weeks. Results showed that the combination of DRSP/E2 plus 25 mg of HCTZ is safe and well tolerated in hypertensive postmenopausal women. The pharmacokinetics of HCTZ were not affected by coadministration of DRSP/E2. The geometric mean ratios and 90% confidence intervals ([HCTZ + DRSP/E2]/[HCTZ + placebo]) for HCTZ (a) area under the serum/plasma concentration-time curve from 0 to 24 hours and (b) maximum plasma concentration were 101 (90.7, 112) and 103 (92.8, 115), respectively. In the HCTZ + DRSP/E2 group, serum potassium, aldosterone, and plasma renin activity all increased in a manner marginally consistent with a beneficial antialdosterone effect, counteracting the HCTZ-induced potassium loss and lowering both systolic and diastolic blood pressure. No dose adjustment is required when DRSP/E2 is added to antihypertensive therapy with HCTZ in hypertensive postmenopausal women.

Characterization of pentamidine excretion in the isolated perfused rat kidney.

OBJECTIVE: To study the renal excretion and kidney accumulation of pentamidine, a potentially nephrotoxic compound, in the isolated perfused rat kidney (IPK). MATERIALS AND METHODS: IPK experiments (3-4 per treatment group) were conducted using male Sprague-Dawley rats (250-350 g). Dose proportionality studies were carried out over a pentamidine dosing range of 80-4000 microg, designed to target initial perfusate concentrations from 1 to 50 microg/mL. Separate interaction experiments were conducted between pentamidine (800 microg) and tetraethylammonium (dose 8000 microg) or dideoxyinosine (dose 80 microg). Inulin was used as a glomerular filtration rate (GFR) marker. Control (drug-naive) perfusions were also carried out. Pentamidine was analysed in perfusate, kidney and urine samples by HPLC. Inulin was measured by a colorimetric method. RESULTS: Pentamidine CLR (1.1 +/- 0.6 to 0.05 +/- 0.03 mL/min) and excretion ratio (3.6 +/- 1.5 to 0.56 +/- 0.15) significantly decreased over the range of doses studied. Significant reductions in viability parameters (GFR, Na reabsorption) were noted in kidneys perfused with high dose pentamidine (4000 microg). Tetraethylammonium co-administration reduced pentamidine renal excretion, resulting in significantly greater kidney accumulation of pentamidine and reduced kidney function. Dideoxyinosine administration had minimal effects on pentamidine disposition. CONCLUSIONS: Pentamidine renal transport involves a combination of mechanisms (filtration, secretion and passive reabsorption). Dose proportionality studies demonstrated non-linear excretion of pentamidine. Inhibition of pentamidine renal clearance by tetraethylammonium was consistent with decreased luminal transport. The detrimental effects of pentamidine on kidney function were the result of significant kidney accumulation of drug. The potential exists for drug-drug interactions between pentamidine and organic cations, increasing the risk of drug-induced nephrotoxicity.

A novel HPLC assay for pentamidine: comparative effects of creatinine and inulin on GFR estimation and pentamidine renal excretion in the isolated perfused rat kidney.

PURPOSE: 1. To develop and validate an analytical method for pentamidine (PTM) by reversed-phase HPLC. 2. To compare the effects of creatinine and inulin on PTM excretion in the isolated perfused rat kidney. METHODS: The HPLC method utilized a base deactivated, 5 micro, C18 column and a mobile phase containing acetonitrile (24%) and 0.025 M monobasic phosphate buffer, pH 3.2 (76%). Mobile phase flow rate and UV detection wavelength were 1 mL/min and 270 nm, respectively. Sulfadiazine (SDZ) was used as the internal standard. The method was used to measure pentamidine in perfusate and urine samples generated from studies with the isolated perfused rat kidney (IPK) model. Perfusion experiments were conducted in the presence of two different GFR markers: creatinine and inulin (PTM dose 800 micro g). Both creatinine and inulin were assayed using colorimetric methods. RESULTS: The HPLC assay is rapid, sensitive and reproducible. The method was validated over two standard concentration ranges: 0.1 to 1 micro g/mL, and 1 to 10 micro g/mL. In control (drug-naïve) IPK perfusions, creatinine clearance was approximately 15% greater than inulin clearance (0.80+/- 0.21 mL/min vs. 0.69+/-0.17 mL/min, p > 0.05). In the presence of PTM, however, creatinine clearance was reduced to 0.56+/-0.27 (p < 0.05 compared to control). Inulin clearance was not altered by PTM administration (0.76+/-0.26 mL/min). Cumulative urinary excretion of PTM (% dose) was 3.0+/-0.47% and 9.6+/-4.2% in the presence of creatinine and inulin, respectively. PTM clearance was significantly reduced (0.06+/-0.01 mL/min vs. 0.13+/-0.01 mL/min, p < 0.05) and % kidney accumulation significantly enhanced (66+/-4.7% vs. 37+/-9.7%, p < 0.05) by creatinine. CONCLUSIONS: Creatinine overestimated GFR in the IPK. The altered renal excretion of PTM by creatinine is consistent with inhibition of PTM tubular secretion. Because of increased kidney accumulation, detrimental effects of PTM on renal function were observed. Based on these findings, creatinine should be used cautiously as an indicator of GFR in IPK experimentation.