Proof of pharmacology of Org 48775-0, a p38 MAP kinase inhibitor, in healthy volunteers.

AIM: To investigate the safety, tolerability, pharmacokinetics and pharmacodynamics of the highly selective oral p38alpha/beta mitogen-activated protein (MAP) kinase inhibitor Org 48,775-0 in a first-in-human study. METHODS: In the single ascending dosing (SAD) study, an oral dose of Org 48,775-0 (0.3-600 mg) was evaluated in healthy males. In the multiple ascending dosing (MAD) study, levels of 30, 70 and 150 mg were dosed for six consecutive days, twice daily. Both studies were performed in a double-blind, randomized, placebo-controlled, cross-over fashion and evaluated pharmacokinetics, pharmacodynamics (ex vivo inhibition of lipopolysaccharide [LPS]-induced tumor necrosis factor (TNFα) release) and routine clinical and laboratory data. Pharmacokinetic and pharmacodynamic parameters of Org 48,775-0 were compared between healthy males and postmenopausal females, and the effect of a standardized fat meal was evaluated. RESULTS: All adverse events observed in the SAD (16; dizziness and headache, diarrhoea and catheter-related phlebitis) and MAD (43; mainly somnolence, dizziness, headache and nasopharyngitis) cohorts were mild, transient and completely reversible. Pharmacokinetics were linear up to single doses of 400 mg. Median Tmax ranged from 0.5 to 1.8 hours, geometric mean for T1/2 from 7.0 to 14.4 hours. Org 48,775-0 doses equal to and greater than 30 mg significantly inhibited LPS-induced TNFα release (42.3%; 95% CI = -65.2, -4.3) compared to placebo. In the MAD study, Org 48,775-0 treatment inhibited LPS-induced TNFα release during the entire steady-state period. Levels of inhibition amounted 30-75% for 30 mg, 53-80% for 70 mg and 77-92% for 150 mg Org 48,775-0. CONCLUSION: Org 48,775-0 has the capacity to significantly inhibit MAP kinase activity in humans without safety concerns.

Pharmacokinetics and Pharmacodynamics of the Dual Orexin Receptor Antagonist Daridorexant in Japanese and Caucasian Subjects.

PURPOSE/BACKGROUND: Daridorexant is a dual orexin receptor antagonist in development for the treatment of sleep disorders. Thus far, it has not yet been studied in Japanese subjects. Study objectives were to evaluate the pharmacokinetics (PK), pharmacodynamics (PD), and safety of single- and multiple-dose administration of daridorexant in healthy Caucasian and Japanese subjects. METHODS/PROCEDURES: This was a double-blind, placebo-controlled, randomized study. Subjects received once-daily doses of daridorexant (25 or 50 mg) or placebo for 5 days. Pharmacokinetics and safety were investigated using standard assessments. To assess PD effects, a battery of tests (saccadic peak velocity, body sway, adaptive tracking performance, and visual analog scales for alertness, mood, and calmness), known to be sensitive to sleep-promoting drugs was used. FINDINGS/RESULTS: On day 1, PK variables were similar between Caucasian and Japanese subjects. On day 5, slight accumulation occurred in Japanese but not in Caucasian subjects, resulting in a higher maximum concentration (1403 vs 1006 ng/mL) and area under the curve (8256 vs 6306 ng·h/mL) at a dose of 50 mg, whereas values for time to maximum concentration and half-life were similar. Daridorexant dose-dependently reduced vigilance, attention, visuomotor coordination, and postural stability. Pharmacokinetic effects were detectable within 1 hour after drug administration and returned to baseline 4 to 8 hours postdose. Overall, Japanese showed slightly larger PD effects and reported more adverse events than Caucasians. The most frequently reported were somnolence, fatigue, and headache. Changes in other safety assessments were unremarkable. IMPLICATIONS/CONCLUSIONS: The PK, PD, and safety profile of daridorexant were similar in Japanese and Caucasian subjects.

Assessment of Dermal Absorption of Aluminum from a Representative Antiperspirant Formulation Using a 26 Al Microtracer Approach.

A clinical pharmacokinetic study was performed in 12 healthy women to evaluate systemic exposure to aluminum following topical application of a representative antiperspirant formulation under real-life use conditions. A simple roll-on formulation containing an extremely rare isotope of aluminum (26 Al) chlorohydrate (ACH) was prepared to commercial specifications. A 26 Al radio-microtracer was used to distinguish dosed aluminum from natural background, using accelerated mass spectroscopy. The 26 Al citrate was administered intravenously (i.v.) to estimate fraction absorbed (Fabs ) following topical delivery. In blood samples after i.v. administration, 26 Al was readily detected (mean area under the curve (AUC) = 1,273 ± 466 hours×fg/mL). Conversely, all blood samples following topical application were below the lower limit of quantitation (LLOQ; 0.12 fg/mL), except two samples (0.13 and 0.14 fg/mL); a maximal AUC was based on LLOQs. The aluminum was above the LLOQ (61 ag/mL) in 31% of urine samples. From the urinary excretion data, a conservative estimated range for dermal Fabs of 0.002-0.06% was calculated, with a mean estimate of 0.0094%.

Pharmacological interactions between brivaracetam and ethanol in healthy males.

This double-blind, randomized, three-way crossover study explored the potential pharmacokinetic and pharmacodynamic interactions between ethanol and brivaracetam in 18 healthy males, as required for the development of CNS-active drugs. Subjects received (A) ethanol+brivaracetam, (B) ethanol placebo+brivaracetam and (C) ethanol+brivaracetam placebo. Ethanol was infused as a 5.5-hour intravenous clamp with the first 0.5-hour as loading phase to a target level of 0.6 g/L, and brivaracetam was orally administered as a single 200 mg dose. No relevant pharmacokinetic interactions were observed. Co-administration of brivaracetam and ethanol resulted in decreased saccadic peak velocity, smooth pursuit, adaptive tracking and VAS alertness, and increased body sway, saccadic reaction time and VAS score for ethanol effect compared with brivaracetam alone or ethanol alone. Additionally, the immediate word recall scores were generally lower when brivaracetam was co-administered with ethanol, whereas the delayed word test did not show clear additional effects. A post-hoc exploratory analysis for supra-additivity suggested that most pharmacodynamic effects were likely to be additive in nature, except for adaptive tracking, which appeared to be slightly supra-additive. In conclusion, brivaracetam increased ethanol effects on psychomotor function, attention and memory in healthy males. Intake of brivaracetam with alcohol is not recommended.

The effect of food on the high clearance drug asenapine after sublingual administration to healthy male volunteers.

PURPOSE: To determine the effects of food on the pharmacokinetics of sublingual asenapine. METHODS: Healthy male volunteers (n=26, age 19-53 years) randomly received a single sublingual dose of asenapine 5 mg after ≥ 10 h fasting (Treatment A, reference), after a high-fat meal (Treatment B) and after ≥ 10 h fasting with a high-fat meal at 4 h post-dose (Treatment C). Blood samples were drawn over 72 h to measure asenapine plasma concentrations. Effects of food intake on asenapine pharmacokinetics were assessed using bioequivalence criteria and evaluated using a compartmental modelling analysis. RESULTS: Compared with the reference, mean asenapine exposure (AUC0-last and AUC0-∞) was approximately 20 % lower after intake of a high-fat meal prior to dosing, whereas Cmax decreased by only about 10 %. When a high-fat meal was taken 4 h post-dose in the fasting state, asenapine concentrations were similar to the reference during the first 4 h post-dose. After the meal intake, asenapine concentrations decreased quickly for several hours. Compartmental modelling indicated that a transient 2.5-fold increase in asenapine clearance after eating could explain the asenapine concentration-time profiles for both food regimens. CONCLUSIONS: To our knowledge, this is the first study investigating the effect of food upon the sublingual administration of a drug. A high-fat meal taken before or 4 h post-dose of sublingual asenapine indirectly caused a transient increase in liver blood flow that resulted in a temporal increase in asenapine clearance. As the effects on asenapine exposure were small and not clinically relevant, no additional restrictions are required for the timing of food intake in relation to asenapine dosing.

Effects of sugammadex on activated partial thromboplastin time and prothrombin time in healthy subjects.

OBJECTIVES: To assess the impact of sugammadex on activated partial thromboplastin time (APTT) and international normalized ratio for prothrombin time (PT(INR)) in healthy subjects and characterize the concentration-dependency of sugammadex effects on APTT and prothrombin time (PT) in normal human plasma in vitro. METHODS: Eight healthy subjects (18 - 45 years of age) were administered intravenous doses of 4 mg/kg sugammadex, 16 mg/kg sugammadex, or placebo in a randomized, placebo-controlled, three period cross-over trial. The primary endpoint was area under the curve from 2 to 60 minutes post-dose (AUC2-60min) for APTT and PT(INR). In vitro, the effects of sugammadex on APTT and PT were assessed in pooled normal human citrate plasma. RESULTS: In subjects dosed with 4 and 16 mg/kg sugammadex, geometric mean ratios (treated vs. placebo) for AUC2-60min were 1.085 (95% confidence interval, 0.888 - 1.325) and 1.019 (0.868 - 1.195), respectively, for APTT, and 1.047 (0.904 - 1.213) and 1.096 (0.953 - 1.261), respectively, for PT(INR). At individual timepoints, mean APTT and PT(INR) increased by up to 22% after 16 mg/kg sugammadex compared with placebo. All such increases occurred within 30 minutes post-dose. Sugammadex was generally well tolerated. In the in vitro experiments, addition of sugammadex to plasma resulted in limited, concentration dependent increases in both APTT and PT. At 200 µg/mL (the mean maximum concentration reached therapeutically), the relative increases were 29% and 19%, respectively. CONCLUSIONS: Administration of sugammadex is associated with a dose-related, limited and transient prolongation of APTT and PT(INR) that is unlikely to be of clinical relevance.

No clinically relevant interaction between sugammadex and aspirin on platelet aggregation and coagulation parameters.

OBJECTIVES: This study evaluated interaction potential between sugammadex and aspirin on platelet aggregation. METHODS: This was a randomized, double-blind, placebo-controlled, four-period crossover study in 26 healthy adult males. Treatments were i.v. placebo, i.v. sugammadex 4 mg/kg, and i.v. placebo/sugammadex with oncedaily oral aspirin 75 mg. Primary objective was to assess interaction between sugammadex and aspirin on platelet aggregation using collagen-induced whole-blood aggregometry. Effects on activated partial thromboplastin time (APTT) and cutaneous bleeding time were also evaluated. Platelet aggregation and APTT were evaluated by geometric mean ratios, using area-under-effect curves 3 - 30 minutes after sugammadex/placebo dosing. Bleeding time ratio was evaluated at 5 minutes post-dosing. Non-inferiority margins were pre-specified via literature review. Type I error was controlled using a hierarchical strategy. RESULTS: Ratio for platelet aggregation for aspirin with sugammadex vs. aspirin alone was 1.01, with lower limit of two-sided 90% CI of 0.91(above non-inferiority margin of 0.75). Ratio for statistical interaction between sugammadex and aspirin on APTT was 1.01, with upper 90% CI of 1.04 (below non-inferiority margin of 1.50), and for sugammadex vs. placebo alone was 1.06, with an upper 90% CI of 1.07 (below non-inferiority margin of 1.50). Ratio for bleeding time for aspirin with sugammadex vs. aspirin plus placebo was 1.20, with upper 90% CI of 1.45 (below non-inferiority margin of 1.50). Sugammadex was generally well tolerated. CONCLUSION: There was no clinically relevant reduction in platelet aggregation with addition of sugammadex 4 mg/kg to aspirin. Pre-determined non-inferiority margins were not exceeded for bleeding time and APTT.

Effect of sugammadex on QT/QTc interval prolongation when combined with QTc-prolonging sevoflurane or propofol anaesthesia.

BACKGROUND: We evaluated the potential for QT/corrected QT (QTc) interval prolongation after sugammadex given with propofol or sevoflurane anaesthesia. METHODS: This was a two-factorial, randomized, parallel-group study in 132 healthy subjects. Anaesthesia was maintained with sevoflurane or propofol. At ~20 min following sevoflurane/propofol initiation, sugammadex 4 mg/kg or placebo was administered. Neuromuscular blocking agents were not administered. Electrocardiograms were recorded regularly. The primary variable was the time-matched mean difference in the Fridericia-corrected QT interval (QTcF) change from baseline for sugammadex versus placebo when combined with propofol or sevoflurane. No relevant QTcF prolongation was concluded if the upper one-sided 95 % confidence interval (CI) was below the 10 ms margin of regulatory non-inferiority, up to 30 min post-study drug. Blood samples were taken for pharmacokinetic analysis. An exploratory analysis evaluated potential QT/QTc effects of neostigmine 50 µg/kg/glycopyrrolate 10 µg/kg in combination with propofol. RESULTS: The estimated mean QTcF differences between sugammadex and placebo ranged from -2.4 to 0.6 ms when combined with either anaesthetic. The largest upper one-sided 95 % CI for the mean QTcF difference between sugammadex and placebo was 2 ms, occurring 2 min post-dosing. Propofol and sevoflurane resulted in mean QTcF increases exceeding 10 and 30 ms, respectively. On top of these prolongations, the effect of sugammadex was negligible at all timepoints. The mean peak sugammadex concentration was 66.5 µg/mL, with exposure similar in the sevoflurane/propofol groups. The mean QTcF changes from baseline following neostigmine/glycopyrrolate in 10 healthy subjects ranged between -1.4 and 3.6 ms. CONCLUSION: Sugammadex 4 mg/kg does not cause clinically relevant QTc interval prolongation versus placebo when combined with propofol or sevoflurane.

Pharmacokinetic profile of nomegestrol acetate and 17ß-estradiol after multiple and single dosing in healthy women.

BACKGROUND: The pharmacokinetics of the monophasic oral contraceptive nomegestrol acetate (NOMAC) plus 17ß-estradiol (E(2)) were investigated after a single dose and multiple dosing. STUDY DESIGN: NOMAC/E2 (2.5 mg/1.5 mg) was administered daily to healthy women (18-50 years, n=23) for 24 days; blood samples for pharmacokinetic analysis were obtained on Day 24 and again, after a 10-day pill-free interval, on Day 35 after a single dose. RESULTS: NOMAC reached steady state after 5 days with mean ±standard deviation (SD) trough NOMAC concentration (C(av)) of 4.4±1.4 ng/mL. On Day 24, mean±SD peak NOMAC concentration (Cmax, 12.3±3.5 ng/mL) was reached in mean 1.5 h (t(max)); the mean±SD elimination half-life (t(½)) was 45.9±15.3 h. After a single dose, NOMAC mean±SD C(max) was 7.2±2.0 ng/mL and mean±SD t(½) was 41.9±16.2 h. On Day 24, E2 mean±SD C(av) was 50.3±25.7 pg/mL; mean±SD Cmax was 86.0±51.3 pg/mL. After a single dose, mean±SD E2 Cmax was 253±179 pg/mL. CONCLUSIONS: These data demonstrate that NOMAC/E2 has a pharmacokinetic profile consistent with once-daily dosing.

Early stage development of the glycine-1 re-uptake inhibitor SCH 900435: central nervous system effects compared with placebo in healthy men.

AIMS: To report the first three studies with SCH 900435, a selective glycine-1 re-uptake inhibitor in development for treating schizophrenia, using systematic evaluations of pharmacodynamics to understand the observed effects. METHODS: Three double-blind, placebo-controlled studies (single, visual effect and multiple dose) were performed. In the single and multiple dose study SCH 900435 (0.5-30 mg) was given to healthy males and frequent pharmacokinetic and pharmacodynamic measurements were performed. The visual effects study incorporated visual electrophysiological measures of macular, retinal and intracranial visual pathway function. RESULTS: In the single dose study (highest difference, 95% CI, P) increases in smooth pursuit eye movements (8, 12 mg (-6.09, 10.14, -2.04, 0.013), 30 mg), pupil : iris ratio (20 and 30 mg (-0.065, 0.09, -0.04, <0.0001)), VAS colour perception (30 mg (-9.48, 13.05, -5.91, <0.0001)) and changes in spontaneous reports of visual disturbance were found, while FSH (8 mg (0.42, 0.18, 0.66, 0.0015), 12, 20 mg), LH (8-30 mg (1.35, 0.65, 2.05, 0.0003)) and EEG alpha2 activity decreased (12, 20, 30 mg (0.27, 0.14, 0.41, 0.0002)). A subsequent dedicated visual effects study demonstrated that visual effects were transient without underlying electrophysiological changes. This provided enough safety information for starting a multiple ascending dose study, showing less visual symptoms after twice daily dosing and titration, possibly due to tolerance. CONCLUSIONS: Several central nervous system (CNS) effects and gonadotropic changes resulted from administration of 8 mg and higher, providing evidence for CNS penetration and pharmacological activity of SCH 900435. Antipsychotic activity in patients, specificity of the reported effects for this drug class and possible tolerance to visual symptoms remain to be established.

Sugammadex is not associated with QT/QTc prolongation: methodology aspects of an intravenous moxifloxacin-controlled thorough QT study.

OBJECTIVE: Sugammadex is a novel γ-cyclodextrin and the first selective relaxant binding agent to be developed for the reversal of rocuronium and vecuroniuminduced neuromuscular blockade. According to International Conference on Harmonization (ICH) E14, a thorough QT/QTc study is required for most new compounds to assess the potential to cause QT prolongation, because a delay in cardiac repolarization may create an electrophysiological environment that favors the development of cardiac arrhythmias, most notably Torsade de Pointes. Therefore a thorough QTc study was conducted to evaluate the effect of sugammadex on the individually corrected QTc interval (QTcI). METHODS: Following two baseline electrocardiogram (ECG) days (Day -2 and Day -1), in this randomized, double-blind, cross-over study, healthy volunteers received a sequence of four treatments comprising single intravenous doses of placebo, moxifloxacin 400 mg (positive control, open label), sugammadex 4 mg/kg and sugammadex 32 mg/kg. ECGs were recorded in triplicate at 12 time points up to ~ 24 h after study drug administration, and the QT intervals were evaluated manually under blinded conditions. The pre-specified primary endpoint was the largest time-matched mean QTcI difference compared with placebo across all time points. RESULTS: A total of 62 subjects received treatment, of which 58 completed the study. After intravenous moxifloxacin, QTcI prolongations compared with placebo exceeded the ICH E14 safety margin of 10 msec and the one-sided 95% lower confidence limit exceeded 5 msec, confirming assay sensitivity. For both sugammadex doses, the one-sided 95% upper confidence limits for the largest time-matched mean QTcI differences compared with placebo were ≤ 5.3 msec at each timepoint and thus considerably below the 10 msec safety margin. Unexpectedly, the two full-day baseline ECGs indicated systematically prolonged QTc values when comparing the first baseline with the second baseline day, reaching a maximum mean difference of 3.8 msec. CONCLUSION: Single therapeutic (4 mg/kg) and supra-therapeutic (32 mg/kg) intravenous doses of sugammadex are not associated with clinically important QTc prolongation.

Valproate reduces the glucuronidation of asenapine without affecting asenapine plasma concentrations.

Asenapine is indicated for treatment of schizophrenia in the United States and acute treatment of manic or mixed episodes, as monotherapy (United States and European Union) or adjunct therapy (United States only), associated with bipolar I disorder. It is extensively metabolized; the 2 main metabolites are asenapine N-glucuronide and N-desmethyl-asenapine. The authors investigated the pharmacokinetic interactions between asenapine and valproate in an open-label, randomized, 2-way crossover study. Twenty-four healthy male volunteers received sublingual doses of asenapine 5 mg alone or under steady-state valproate (500 mg bid for 9 days). Blood samples collected until 72 hours postdosing were analyzed for asenapine, N-desmethyl-asenapine, and asenapine N-glucuronide. Compared with asenapine alone, valproate substantially reduced N-glucuronide formation (area under the curve from 0 to infinity [AUC(0-∞)] reduced 7.4-fold, maximum concentration [C(max)] reduced 6.6-fold) and moderately reduced N-desmethyl-asenapine formation (AUC(0-∞) reduced 30%, C(max) unchanged). Coadministration of valproate did not affect asenapine AUC(0-∞) and C(max) (confidence intervals for the ratios of asenapine AUC(0-∞) and C(max) were contained within the predefined 0.80-1.25 acceptance range). Low-dose valproate, although almost completely inhibiting glucuronidation of asenapine, did not affect the pharmacokinetics of asenapine itself, the entity primarily responsible for the pharmacologic effects of the drug.

Asenapine Safety, Tolerability, and Pharmacokinetics After Single and Multiple Doses in Healthy Volunteers.

This double-blind, placebo-controlled, randomized study is the first in healthy volunteers to describe the safety, tolerability, and pharmacokinetics of sublingual asenapine at therapeutic dosages. After a 2-day placebo run-in phase, healthy male volunteers received placebo or asenapine escalated to dosages of 3, 5, 10, or 15 mg bid. Another group received single doses (2 and 5 mg) 1 week apart. Serial blood samples were obtained for pharmacokinetic analysis. The single asenapine doses and multiple bid doses up to 10 mg were well tolerated. The most frequent treatment-emergent adverse events were somnolence, oral paresthesia, fatigue, headache, dizziness, and dyspnea. Clinically relevant abnormalities or trends in laboratory and vital signs measures, physical examinations, or electrocardiograms were not observed. Asenapine was rapidly absorbed, with a tmax of ∼1 hour, and was biphasically eliminated with a terminal elimination half-life of 20 to 30 hours. In the range of 3 to 10 mg bid, increases in plasma concentrations were less than dose proportional. Asenapine appears to be well tolerated at single doses up to 5 mg and multiple doses up to 10 mg bid and can be administered to healthy volunteers in clinical pharmacology studies using the dosing regimens described.

Flucloxacillin and diclofenac do not cause recurrence of neuromuscular blockade after reversal with sugammadex.

BACKGROUND: Sugammadex, a modified γ-cyclodextrin, facilitates rapid reversal of rocuronium- and vecuronium-induced neuromuscular blockade (NMB). Cyclodextrins are known for their ability to form inclusion complexes with various drugs. Theoretically, molecules with a high affinity for sugammadex could interact and displace sugammadex from the sugammadex-rocuronium or sugammadex-vecuronium complex, potentially resulting in the recurrence of NMB due to recirculation of free rocuronium or vecuronium. OBJECTIVE: This study aimed to evaluate whether the administration of high doses of flucloxacillin or diclofenac can result in recurrence of NMB through displacement of sugammadex from its complex with rocuronium or vecuronium, following successful reversal of NMB by a suboptimal dose of sugammadex 2 mg/kg. Flucloxacillin has previously been identified using a modelling approach as a drug with displacement potential, while diclofenac was assessed due to its common intravenous use in the peri-operative and post-surgery setting. METHODS: This was a randomized, open-label, parallel, single-centre study conducted at SGS Life Services-CPU, Antwerp, Belgium. Twenty-four healthy, propofol-anaesthetized, adult volunteers were randomized to either rocuronium 0.6 mg/kg or vecuronium 0.1 mg/kg, followed by a suboptimal dose of sugammadex 2 mg/kg 15 minutes after induction of NMB. Five minutes after successful sugammadex reversal, subjects received either diclofenac 75 mg (15-minute infusion) or flucloxacillin 2 g (5-minute infusion) according to randomization. The suboptimal dose of sugammadex and relatively high doses of diclofenac and flucloxacillin were applied to create favourable conditions for the potential displacement of sugammadex from the sugammadex-rocuronium or sugammadex-vecuronium complex, and thus possible recurrence of NMB due to recirculation of free rocuronium or vecuronium. Possible recurrence of NMB was assessed by neuromuscular monitoring, performed with acceleromyography, and was continued until ∼90 minutes after the start of diclofenac or flucloxacillin administration. Recurrence of NMB was concluded if three consecutive train-of-four (TOF) ratios were <0.8. RESULTS: Following successful reversal with a suboptimal dose of sugammadex 2 mg/kg administered 15 minutes after NMB induction, subsequent administration of diclofenac or flucloxacillin did not result in recurrence of NMB in any subject based on measurement of TOF ratios during anaesthesia and neuromuscular function tests upon awakening. There were no adverse events considered to be related to sugammadex. CONCLUSION: Administration of flucloxacillin or diclofenac does not result in recurrence of NMB through displacement of sugammadex from the sugammadex-rocuronium or sugammadex-vecuronium complex.

Glycine transporter inhibitor attenuates the psychotomimetic effects of ketamine in healthy males: preliminary evidence.

Enhancing glutamate function by stimulating the glycine site of the NMDA receptor with glycine, D-serine, or with drugs that inhibit glycine reuptake may have therapeutic potential in schizophrenia. The effects of a single oral dose of cis-N-methyl-N-(6-methoxy-1-phenyl-1,2,3,4-tetrahydronaphthalen-2-ylmethyl) amino-methylcarboxylic acid hydrochloride (Org 25935), a glycine transporter-1 (GlyT1) inhibitor, and placebo pretreatment on ketamine-induced schizophrenia-like psychotic symptoms, perceptual alterations, and subjective effects were evaluated in 12 healthy male subjects in a randomized, counter-balanced, within-subjects, crossover design. At 2.5 h after administration of the Org 25935 or placebo, subjects received a ketamine bolus and constant infusion lasting 100 min. Psychotic symptoms, perceptual, and a number of subjective effects were assessed repeatedly before, several times during, and after completion of ketamine administration. A cognitive battery was administered once per test day. Ketamine produced behavioral, subjective, and cognitive effects consistent with its known effects. Org 25935 reduced the ketamine-induced increases in measures of psychosis (Positive and Negative Syndrome Scale (PANSS)) and perceptual alterations (Clinician Administered Dissociative Symptoms Scale (CADSS)). The magnitude of the effect of Org 25935 on ketamine-induced increases in Total PANSS and CADSS Clinician-rated scores was 0.71 and 0.98 (SD units), respectively. None of the behavioral effects of ketamine were increased by Org 25935 pretreatment. Org 25935 worsened some aspects of learning and delayed recall, and trended to improve choice reaction time. This study demonstrates for the first time in humans that a GlyT1 inhibitor reduces the effects induced by NMDA receptor antagonism. These findings provide preliminary support for further study of the antipsychotic potential of GlyT1 inhibitors.

Asenapine pharmacokinetics in hepatic and renal impairment.

BACKGROUND AND OBJECTIVE: The effects of hepatic or renal impairment on the pharmacokinetics of atypical antipsychotics are not well understood. Drug exposure may increase in patients with hepatic disease, owing to a reduction of certain metabolic enzymes. The objective of the present study was to study the effects of hepatic or renal impairment on the pharmacokinetics of asenapine and its N-desmethyl and N⁺-glucuronide metabolites. METHODS: Two clinical studies were performed to assess exposure to asenapine, desmethylasenapine and asenapine N⁺-glucuronide in subjects with hepatic or renal impairment. Pharmacokinetic parameters were determined from plasma concentration-time data, using standard noncompartmental methods. The pharmacokinetic variables that were studied included the maximum plasma concentration (C(max)) and the time to reach the maximum plasma concentration (t(max)). Eligible subjects, from inpatient and outpatient clinics, were aged ≥18 years with a body mass index of ≥18 kg/m² and ≤32 kg/m². Sublingual asenapine (Saphris®) was administered as a single 5 mg dose. RESULTS: Thirty subjects participated in the hepatic impairment study (normal hepatic function, n = 8; mild hepatic impairment [Child-Pugh class A], n = 8; moderate hepatic impairment [Child-Pugh class B], n = 8; severe hepatic impairment [Child-Pugh class C], n = 6). Thirty-three subjects were enrolled in the renal impairment study (normal renal function, n = 9; mild renal impairment, n = 8; moderate renal impairment, n = 8; severe renal impairment, n = 8). Asenapine and N-desmethylasenapine exposures were unaltered in subjects with mild or moderate hepatic impairment, compared with healthy controls. Severe hepatic impairment was associated with increased area under the plasma concentration-time curve from time zero to infinity (AUC(∞)) values for total asenapine, N-desmethylasenapine and asenapine N⁺-glucuronide (5-, 3-, and 2-fold, respectively), with slight increases in the C(max) of asenapine but 3- and 2-fold decreases in the C(max) values for N-desmethylasenapine and asenapine N⁺-glucuronide, respectively, compared with healthy controls. The mean AUC(∞) of unbound asenapine was more than 7-fold higher in subjects with severe hepatic impairment than in healthy controls. Mild renal impairment was associated with slight elevations in the AUC(∞) of asenapine compared with healthy controls; alterations observed with moderate and severe renal impairment were marginal. N-desmethylasenapine exposure was only slightly altered by renal impairment. No correlations were observed between exposure and creatinine clearance. CONCLUSION: Severe hepatic impairment (Child-Pugh class C) was associated with pronounced increases in asenapine exposure, but significant increases were not seen with mild (Child-Pugh class A) or moderate (Child-Pugh class B) hepatic impairment, or with any degree of renal impairment. Asenapine is not recommended in patients with severe hepatic impairment; no dose adjustment is needed in patients with mild or moderate hepatic impairment, or in patients with renal impairment.

Sugammadex is cleared rapidly and primarily unchanged via renal excretion.

Sugammadex is a modified γ-cyclodextrin which rapidly reverses rocuronium-and vecuronium-induced neuromuscular blockade. Previous studies suggest that sugammadex is mostly excreted unchanged via the kidneys. This single-center, open-label, non-randomized study used (14)C-labeled sugammadex to further investigate the excretion, metabolic and pharmacokinetic (PK) profiles of sugammadex in six healthy male volunteers. (14)C-labeled sugammadex 4 mg/kg (0.025 MBq/kg of (14)C-radioactivity) was administered as a single intravenous bolus. Blood, urine, feces and exhaled air samples were collected at pre-defined intervals for assessment of sugammadex by liquid chromatography-mass spectrometry (LC-MS) and for radioactivity measurements. Adverse events were also assessed. Excretion of sugammadex was rapid with ∼70% of the dose excreted within 6 h and ∼90% within 24 h. Less than 0.02% of radioactivity was excreted in feces or exhaled air. Ninety-five percent of the radioactivity detected in urine could be attributed to sugammadex, as determined by LC-MS, suggesting very limited metabolism of sugammadex. LC-MS analysis of plasma samples found that sugammadex accounted for 100% of total (14)C-radioactivity in the plasma. In general, PK parameters determined from radioactivity and sugammadex plasma concentrations were very similar. Any adverse events were of mild-to-moderate intensity, and judged unrelated to sugammadex. These findings demonstrate that sugammadex is cleared rapidly, almost exclusively via the kidney, with minimal or no metabolism.

Residual effects of esmirtazapine on actual driving performance: overall findings and an exploratory analysis into the role of CYP2D6 phenotype.

INTRODUCTION: Esmirtazapine is evaluated as a novel drug for treatment of insomnia. PURPOSE: The present study was designed to assess residual effects of single and repeated doses of esmirtazapine 1.5 and 4.5 mg on actual driving in 32 healthy volunteers in a double-blind, placebo-controlled study. Treatment with single doses of zopiclone 7.5 mg was included as active control. METHODS: Treatments were administered in the evening. Driving performance was assessed in the morning, 11 h after drug intake, in a standardized on-the-road highway driving test. The primary study parameter was standard deviation of lateral position (SDLP), a measure of "weaving". All subjects were subjected to CYP2D6 phenotyping in order to distinguish poor metabolizers from extensive metabolizers of esmirtazapine. RESULTS: Overall, esmirtazapine 1.5 mg did not produce any clinically relevant change in SDLP after single and repeated dosing. Driving impairment, i.e., a rise in SDLP, did occur after a single-dose administration of esmirtazapine 4.5 mg but was resolved after repeated doses. Acute driving impairment was more pronounced after both doses of esmirtazapine in a select group of poor metabolizers (N = 7). A single-dose zopiclone 7.5 mg also increased SDLP as expected. CONCLUSION: It is concluded that single and repeated doses of 1.5 mg esmirtazapine are generally not associated with residual impairment. Single-dose administration of 4.5 mg esmirtazapine was associated with residual impairment that generally resolved after repeated administration. Exploratory analysis in a small group of poor CYP 2D6 metabolizers suggested that these subjects are more sensitive to the impairing effects of esmirtazapine on car driving.

Safety, tolerability and pharmacokinetics of sugammadex using single high doses (up to 96 mg/kg) in healthy adult subjects: a randomized, double-blind, crossover, placebo-controlled, single-centre study.

BACKGROUND AND OBJECTIVE: Sugammadex facilitates rapid reversal of rocuronium- and vecuronium-induced neuromuscular blockade. This study aimed to evaluate the safety, tolerability and pharmacokinetics of high doses of sugammadex (up to 96 mg/kg) in healthy subjects. METHODS: In this randomized, double-blind, crossover, placebo-controlled, single-centre study, 13 healthy adults were scheduled to receive three single intravenous doses of sugammadex in ascending order (32, 64 and 96 mg/kg) and placebo (interspersed between sugammadex doses), each separated by a 1-week washout period. Subjects were randomized to one of four treatment sequences, receiving doses as constant rate infusions over 5 minutes. Safety was assessed by adverse events, 12-lead ECGs, vital signs, and blood and urine laboratory parameters; pharmacokinetics were evaluated from blood and urine sugammadex concentrations. RESULTS: Sugammadex was well tolerated in 12 of the 13 subjects, with adverse events being generally mild, of limited duration and more frequent at higher doses. The most common adverse event was dysgeusia; there were no serious adverse events. One subject was withdrawn from the study after experiencing several adverse events following first exposure to sugammadex, related to a probable hypersensitivity reaction to sugammadex. Pharmacokinetics were dose linear over the dose range studied (32-96 mg/kg), and 90-93% of the sugammadex dose was excreted unchanged in urine within 48 hours. CONCLUSION: High doses of sugammadex (up to 96 mg/kg) were well tolerated in 12 of the 13 subjects. One male subject experienced several adverse events associated with a probable hypersensitivity reaction to sugammadex. Pharmacokinetics were dose linear over the range 32-96 mg/kg, with elimination predominantly via the renal route.

Effects of sugammadex doses up to 32 mg/kg alone or in combination with rocuronium or vecuronium on QTc prolongation: a thorough QTc study.

BACKGROUND: Sugammadex reverses the effects of rocuronium- and vecuronium-induced neuromuscular blockade, which are achieved by encapsulation. It is known that some non-antiarrhythmic drugs have the potential to delay cardiac repolarization and it is therefore recommended that the effects of all new drugs on the QT interval are assessed. OBJECTIVE: This thorough corrected QT (QTc) study evaluated the effect of sugammadex alone and in combination with rocuronium or vecuronium on the individually corrected QTc interval (QTcI). METHODS: This was a randomized, double-blind, six-period crossover, placebo-controlled study, with an open-label active-controlled component (moxifloxacin). The study was designed according to International Conference on Harmonization (ICH) E14 guidelines. The study was conducted in a clinical research unit from November 2006 to April 2007. Healthy male and female subjects (n = 84) were enrolled in the study. Subjects were randomized to six treatment sequences comprising single intravenous doses of placebo, moxifloxacin 400 mg (positive control), sugammadex 4 mg/kg, sugammadex 32 mg/kg, sugammadex 32 mg/kg with rocuronium 1.2 mg/kg and sugammadex 32 mg/kg with vecuronium 0.1 mg/kg. Triplicate ECGs were recorded at 13 timepoints up to 23.5 hours after study drug administration and QT intervals were evaluated manually under blinded conditions. The primary outcome was the largest time-matched mean difference in QTcI change from baseline compared with placebo across the 13 timepoints up to 23.5 hours after study drug administration. Blood samples were also collected for pharmacokinetic analysis. RESULTS: Of the 84 randomized healthy subjects, 80 completed the study. After moxifloxacin, QTcI prolongations were observed compared with placebo; the lower limit of the one-sided 95% confidence interval (CI) for the largest time-matched mean difference in QTcI change compared with placebo was 20.8 msec (90% CI 18.5, 23.1), thus exceeding the ICH E14 safety margin of 5 msec and demonstrating assay sensitivity. In contrast, the largest time-matched mean difference in QTcI (msec) from placebo with sugammadex treatments ranged from 2.1 (sugammadex 4 mg/kg alone) to 4.3 (sugammadex 32 mg/kg with vecuronium 0.1 mg/kg). For the largest time-matched mean difference in QTcI change compared with placebo the corresponding upper limit of the one-sided 95% CI was well below the 10 msec margin for both sugammadex doses. Telemetry results revealed that one subject experienced a non-sustained ventricular tachycardia 4 hours after sugammadex 32 mg/kg, which was self-terminating after 20 beats and considered unlikely to be drug related. Pharmacokinetic-QTc analysis showed a statistically significant (p < 0.01) relationship between sugammadex plasma concentration and QTcI; however, at mean maximum plasma concentrations of the therapeutic and supra-therapeutic sugammadex dose, the predicted one-sided upper 95% CI for the largest time-matched QTcI difference from placebo was below 10 msec. Rocuronium or vecuronium co-administration did not affect the relationship between sugammadex concentrations and QTc. CONCLUSIONS: Based on the results of this study of healthy subjects, it can be concluded that sugammadex alone or in combination with rocuronium or vecuronium is not associated with QTc prolongation.