Adinazolam pharmacokinetics and behavioral effects following administration of 20–60 mg oral doses of its mesylate salt in healthy volunteers

The pharmacokinetics and pharmacodynamics of adinazolam were studied in 15 normal, healthy, non-obse volunteers. Placebo capsules and capsules containing 20, 40, and 60 mg adinazolam mesylate were administered as single oral doses in a randomized, 4-way crossover design. Plasma concentrations of adinazolam and mono-N-desmethyladinazolam (NDMAD) were determined by HPLC. Psychomotor performance and memory tests were performed and the degree of sedation assessed at designated times following drug administration. Adinazolam and NDMAD pharmacokinetics were linear throughout the dosage range studied. The ratio of NDMAD to adinazolam area under the curve was approximately 4:1. Dose-related decrements in psychomotor performance and memory were observed up to 8h after dosing (P<0.025 in all cases). Psychomotor performance decrements correlated more closely with NDMAD plasma concentrations than with adinazolam concentrations. These results suggest that NDMAD is responsible for a significant degree of the sedative and psychomotor effects observed after the administration of adinazolam.     

Clinical pharmacology of adinazolam and N-desmethyladinazolam mesylate following single intravenous infusions of each compound in healthy volunteers

Summary The tolerability, pharmacokinetics and pharmacodynamics of adinazolam and N-desmethyladinazolam (NDMAD) were assessed following intravenous infusions of 5, 10, 15, and 20 mg adinazolam mesylate, 10, 20, 30 and 40 mg NDMAD mesylate, and placebo. Six subjects per dose level received treatments in a double-blind crossover design.No clinically significant changes were seen in blood pressure, pulse, respiration, or clinical laboratory parameters. Untoward effects typical of benzodiazepines were observed almost exclusively after NDMAD administration. Adinazolam and NDMAD pharmacokinetics were dose-independent. NDMAD clearance was 50% of the value for adinazolam. Adinazolam and NDMAD administrations increased uric acid clearance and decreased plasma uric acid. Adinazolam administration had no significant effect on psychomotor performance. NDMAD administration produced dose related decreases in performance; 286 ng/ml NDMAD produced a 50% decrease in DSST.These results confirm that adinazolam and NDMAD both produce uricosuria and definitively show that adinazolam is devoid of benzodiazepine-like effects at therapeutic concentrations; NDMAD mediates these effects. Uricosuric activity is present for both compounds, but the relative potencies are still unknown.Presented in part at the Nineteenth Annual Meeting of the American College of Clinical Pharmacology, Las Vegas, NV, November 4–8, 1990     

Pharmacokinetic and Pharmacodynamic Comparison of Immediate-Release and Sustained-Release Adinazolam Mesylate Tablets After Single- and Multiple-Dose Administration

The effect of adinazolam release rate on psychomotor performance and sedation was assessed by administering 40 mg adinazolam mesylate immediate-release (CT) tablets, 60 mg sustained-release (SR) tablets, and placebo in a double-blind crossover study in 15 healthy male subjects. A separate panel of 16 subjects received the above single doses and multiple-dose regimens of 40 mg CT tablets every 8 hr and 60 mg SR tablets every 12 hr according to a crossover design. Psychomotor performance was assessed by digit symbol substitution test, card sorting tasks, and sedation ratings. Following single-dose administration, dose-corrected adinazolam and N-desmethyladinazolam (NDMAD) AUC values were equivalent for SR and CT tablets. Peak adinazolam and NDMAD levels were lower and occurred later for the SR tablets. Decrements in card sorting were 50 and 3% at 1 hr and 17 and 20% at 6 hr for the CT and SR tablets, respectively. Maximal sedation scores were lower for the SR tablets compared to the CT. Dose-corrected AUC was comparable between single and multiple doses for both adinazolam and NDMAD; no differences were observed in 24-hr AUC at steady-state between CT and SR tablets. Fluctuation ratios were reduced for both adinazolam and NDMAD following SR tablets. Psychomotor and sedative effects were attenuated upon multiple dosing. Thus, the reduction in peak plasma NDMAD following SR tablet administration results in a lesser sedation and psychomotor impairment on acute administration, and tolerance to these effects occurs on mulitiple dosing.     

Comparison of adinazolam pharmacokinetics and effects in healthy and cirrhotic subjects

The pharmacokinetics and pharmacodynamics of adinazolam were investigated in six patients with cirrhosis and six sex-matched control subjects. These subjects received a single 30-mg oral dose of adinazolam mesylate. Serial blood samples were collected for 24 hours after drug administration. Plasma was assayed for adinazolam and mono-desmethyl-adinazolam (NDMAD) concentrations by a specific HPLC technique. Pharmacokinetic parameters were estimated by noncompartmental methods. Psychomotor effects of adinazolam were assessed using a digit-symbol substitution test (DSST) and aiming test (AIM). Memory effects were assessed by a modification of the Randt memory test (MEM); sedation was assessed using an observer-rated scale. Differences in pharmacokinetics of the parent drug were noted: adinazolam oral clearance was lower in patients with cirrhosis (35.0 +/- 27.9 L/hr) than in normal subjects (73.7 +/- 22.1 L/hr; P = .024); Kel was significantly lower in patients with cirrhosis (.126 +/- .084 vs. .278 +/- .070; P = .007), whereas the mean t1/2 in patients with cirrhosis was 7.70 hours as compared with 2.67 hours in normal subjects. Cmax was higher in the group with cirrhosis (266 +/- 95.5 vs. 153 +/- 29.3 ng/mL; P = .019). For NDMAD, Kel was lower in cirrhotic subjects and resulted in a prolonged t1/2 in cirrhotic subjects compared with normal subjects (6.70 vs. 3.79 hr; P = .0152). NDMAD AUC tended to be higher in cirrhotic subjects (1515 +/- 254 vs. 1162 +/- 254 ng.hr/mL; P = .064). No significant differences were noted in psychomotor performance, memory, or sedation.(ABSTRACT TRUNCATED AT 250 WORDS)     

Pharmacokinetics and pharmacodynamics of adinazolam and N-desmethyladinazolam after oral and intravenous dosing in healthy young and elderly volunteers.

The pharmacokinetics and pharmacodynamics of adinazolam and N-desmethyladinazolam were studied in 18 young subjects, from 21 to 36 years of age, and 18 elderly subjects, ranging in age from 65 to 76 years. Nine men and 9 women per age group were studied in a randomized three-way crossover design. Single doses of one 30-mg adinazolam mesylate sustained release tablet, one 30-mg immediate release tablet, and 15 mg of intravenous adinazolam mesylate were administered. Plasma adinazolam and N-desmethyladinazolam were determined by high-performance liquid chromatography, and psychomotor performance tests, including digit-symbol substitution and two card-sorting tasks, were performed. An effect index, defined as the maximal performance decrement divided by N-desmethyladinazolam maximum plasma concentration was calculated as a measure of sensitivity to these effects. Adinazolam oral and systemic clearances were reduced approximately 30% and 25%, respectively, in elderly volunteers. Adinazolam half-life was prolonged approximately 40% in the elderly after oral dosing. N-Desmethyladinazolam plasma concentrations and half-life were increased approximately 40% in elderly volunteers. Psychomotor performance decrements were observed following all treatments; decrements were lowest following sustained release tablets and intravenous adinazolam. Maximal performance decrements in elderly subjects were approximately twice those observed in young subjects. No significant influence of age on the effect index for digit-symbol substitution was evident. Effect indices for card-sorting tests were significantly higher in the elderly. Lower clearances of adinazolam and N-desmethyladinazolam are observed in elderly volunteers, and increased N-desmethyladinazolam levels contribute to increased psychomotor performance decrements in elderly subjects. Results also suggest that elderly subjects may be more sensitive to certain cognitive effects of N-desmethyladinazolam.     

Ranitidine does not alter adinazolam pharmacokinetics or pharmacodynamics.

Adinazolam is a triazolobenzodiazepine with anxiolytic and antidepressant activity. Adinazolam is metabolized extensively; the major metabolite, N-desmethyladinazolam (NDMAD), possesses significant pharmacologic activity. NDMAD is eliminated predominantly by renal excretion. Ranitidine, a histamine H2-receptor antagonist, is also excreted renally and may compete with NDMAD for renal secretion. The purpose of this study was to examine the effect of ranitidine on the pharmacokinetics and pharmacodynamics of adinazolam and NDMAD. In a randomized, cross-over study, 12 healthy male volunteers received 300 mg of ranitidine orally followed by 30 mg of adinazolam 1 hour later (treatment A), or adinazolam alone (treatment B). Pharmacodynamic alterations were assessed using card sorting, digit-symbol substitution, and short-term memory tests. Venous blood samples were obtained over 24 hours for analysis of adinazolam and NDMAD by high-performance liquid chromatography. Urine samples also were collected and analyzed for NDMAD. No significant difference in adinazolam oral clearance (1,149 vs. 1,135 ml/hr/kg) was noted between treatments (A vs. B, respectively). Furthermore, the renal clearance of NDMAD (196 vs. 198 ml/min) and the cumulative urinary excretion of NDMAD (% dose; 61.2 vs. 62.3) were not significantly different. Repeated-measures analysis of variance indicated no significant differences in psychomotor performance or short-term memory between treatments. Results suggest that ranitidine has no effect on adinazolam disposition, NDMAD renal clearance, or the central nervous system effects mediated by the drug.     

The pharmacokinetics and pharmacodynamics of adinazolam: multi-ethnic comparisons

The pharmacokinetics and pharmacodynamics of adinazolam and N-demethyladinazolam (NDMAD), its major active metabolite, were compared in 39 healthy male volunteers (13 Asian, 12 Caucasian and 14 African-American). In a four-way, double-blind crossover design, subjects were administered (1) 30 mg oral adinazolam mesylate SR tablets, (2) 10 mg parenteral (IV) adinazolam mesylate, (3) 30 mg IV NDMAD and (4) placebo. Venous blood samples were collected at specific time intervals after drug administration and assayed for adinazolam and NDMAD concentrations. Sedation was rated at the time of each blood draw according to the Nurse-Rated Sedation Scale, and the digit-symbol substitution test was administered to evaluate psychomotor performance. After IV administration of adinazolam, Asians manifested significantly higher C_max, larger AUC and lower CL of both adinazolam and NDMAD than their Caucasian and African-American counterparts. Likewise, after IV NDMAD Asians had significantly higher NDMAD C_max and AUC than Caucasians and African-Americans. Most of these differences remained statistically significant after controlling for body surface area. With PO adinazolam, Asians also manifested substantially higher C_max, larger AUC and lower CL for both adinazolam and NDMAD; however, with the exception of C_max, these differences did not reach statistical significance. These results are in accordance with previous observations for ethnic-related differences in drug pharmacokinetics. In contrast, pharmacodynamic differences were not noted among the three study groups. Received: 19 June 1996/Final version: 17 September 1996     

Kinetics and dynamics of intravenous adinazolam, N-desmethyl adinazolam, and alprazolam in healthy volunteers

The pharmacokinetics and pharmacodynamics of adinazolam mesylate (10 mg), N-desmethyl adinazolam mesylate (NDMAD, 10 mg), and alprazolam (1 mg) were investigated in 9 healthy male subjects in a randomized, blinded, single-dose, 4-way crossover study. All drugs were intravenously infused over 30 minutes. Plasma adinazolam, NDMAD, and alprazolam concentrations, electroencephalographic (EEG) activity in the beta (12-30 Hz) range, performance on the Digit Symbol Substitution Test (DSST), and subjective measures of mood and sedation were monitored for 12 to 24 hours. Mean pharmacokinetic parameters for adinazolam, NDMAD, and alprazolam, respectively, were as follows: volume of distribution (L), 106, 100, and 77; elimination half-life (hours), 2.9, 2.8, and 14.6; and clearance (mL/min), 444, 321, and 84. More than 80% of the total infused adinazolam dose was converted to systemically appearing NDMAD. All 3 benzodiazepine agonists significantly increased beta EEG activity, with alprazolam showing the strongest agonist activity and adinazolam showing the weakest activity. Alprazolam and NDMAD significantly decreased DSST performance, whereas adinazolam had no effect relative to placebo. Adinazolam, NDMAD, and alprazolam all produced significant observer-rated sedation. Plots of EEG effect versus plasma alprazolam concentration demonstrated counterclockwise hysteresis, consistent with an effect site delay. This was incorporated into a kinetic-dynamic model in which hypothetical effect site concentration was related to pharmacodynamic EEG effect via the sigmoid E(max) model, yielding an effect site equilibration half-life of 4.8 minutes. The exponential effect model described NDMAD pharmacokinetics and EEG pharmacodynamics. The relation of both alprazolam and NDMAD plasma concentrations to DSST performance could be described by a modified exponential model. Pharmacokinetic-dynamic modeling was not possible for adinazolam, as the data did not conform to any known concentration-effect model. Collectively, these results indicate that the benzodiazepine-like effects occurring after adinazolam administration are mediated by mainly NDMAD.     

Effect of food on the bioavailability of adinazolam from a sustained release formulation: effect of meal timing and lack of dose dumping

Food effects on adinazolam absorption from sustained release (SR) adinazolam mesylate tablets were assessed in 28 healthy male volunteers. Subjects received 15 mg SR tablets, 15 mg immediate release tablets, 15 mg oral solution, administered after an overnight fast, and 15 mg SR tablets after a high fat breakfast. Treatments were administered in a crossover design. Plasma adinazolam and N-desmethyladinazolam (NDMAD) concentrations were determined by HPLC. Adinazolam and NDMAD AUC values were unaffected by food. Cmax for SR tablets was increased 33 per cent and 18 per cent for adinazolam and NDMAD, respectively, when administered postprandially. Tmax occurred later in the fed state; no dose dumping was observed. Meal timing effects on adinazolam absorption from SR tablets were assessed in 24 healthy subjects, who received 30 mg SR tablets 1 h before, 0.5 h after, 2 h after a high fat meal, and in the fasted state. Postprandial administration had no effect on AUC, but resulted later and higher adinazolam and NDMAD Cmax. Differences in these values were less than 11 per cent. Administration of SR tablets before meals yielded Cmax and Tmax values which were similar to the fasted state. Results suggest that meal timing does not substantially affect adinazolam absorption from the SR tablet.     

The lack of effect of smoking on the pharmacokinetics and pharmacodynamics of adinazolam and N-demethyladinazolam

The pharmacokinetics and pharmacodynamics of adinazolam and N-demethyladinazolam (NDMAD) were evaluated in twelve healthy non-smokers (NS) and twelve smokers (S, ? 20 cigarettes/day) following a single 60 mg dose of adinazolam mesylate sustained-release tablets in an open-label, parallel-group design. Venous blood samples were collected for up to 36 h following drug administration and assayed for adinazolam and NDMAD by HPLC. Urine samples were also collected and assayed for NDMAD by HPLC. Psychomotor performance was measured using the Neurobehavioral Evaluation System. No significant differences were observed in adinazolam oral clearance (51.8±25.8 versus 48.2±14.01 h^?1) or peak adinazolam plasma concentrations (C_max) (93.3±31.8 versus 90.4±18.0 ng ml^?1) between groups. NDMAD AUC (2541.457 versus 2798±447 ng h ml^?1) and C_max (173±30.3 versus 175±26.9 ng ml^?1) did not differ significantly between groups. NDMAD renal clearance was significantly lower in smokers than non-smokers (8.7±0.7 versus 10.7±2.71 h^?1; p<0.05), but the clinical significance of this observation is unclear. Marginally significant differences were seen between groups in the symbol-digit substitution and digit span (forward) tasks. The results suggest that smoking has little effect on adinazolam and NDMAD pharmacokinetics or psychomotor effects but that smoking may slightly decrease renal clearance of NDMAD.     

Influence of repeated administration of cimetidine on the pharmacokinetics and pharmacodynamics of adinazolam in healthy subjects

Summary Adinazolam is a new triazolobenzodiazepine bearing an alkyl-amino side chain. A cross-over double-blind placebo controlled study was carried out in 12 healthy volunteers, in order to check the possible interaction between cimetidine and adinazolam after repeated co-administration.Cimetidine or placebo were given during 17 days. Beginning on Day 8 of each treatment, adinazolam was given in the increasing doses following sequence of doses for 3 days: 10 mg b.i.d., 20 mg b.i.d. and 20 mg t.i.d. A pharmacokinetic and pharmacodynamic study was performed on the third day at each dose. A wash-out of three weeks was included between the two treatments.Cimetidine increased significantly the AUC values of both adinazolam and N-desmethyladinazolam, reduced the oral clearance of adinazolam, and prolonged adinazolam's half-life.The digit symbol substitution test was significantly affected at each dose level while the manual dexterity was marginally impaired by adinazolam plus cimetidine.Saftee-up interview and Clyde mood scale indicated an increased sedation under adinazolam plus cimetidine in four subjects.     

Extent and Variability of the First-Pass Elimination of Adinazolam Mesylate in Healthy Male Volunteers

The pharmacokinetics of adinazolam and N-desmethyladinazolam (NDMAD) were studied in 14 healthy male volunteers who received 15 mg adinazolam mesylate orally as a solution and 5 mg adinazolam mesylate intravenously in a crossover design. Two weeks prior to the crossover study, each subject received 5 mg/kg indocyanine green (ICG) as an intravenous bolus injection to estimate liver blood flow. The absolute bioavailability (F), calculated as the dose-corrected ratio of oral to iv adinazolam area under the curve (AUC) values, was found to be 39%. NDMAD AUC values were similar following oral and iv administration, and adinazolam mean absorption time was approximately 0.77 hr. Thus, adinazolam is completely and rapidly absorbed after oral administration in man; the incomplete bioavailability is due to first-pass metabolism. Mean liver blood flow, adinazolam systemic clearance, blood/plasma ratio, and extraction ratio were 1189 ml/min, 498 ml/min, 0.70, and 0.57, respectively. The extraction ratio agrees with that calculated as 1-F (0.62), suggesting that the liver is primarily responsible for first-pass metabolism of adinazolam. The unbound fraction of adinazolam in plasma was 0.31 (range, 0.25–0.36); adinazolam free intrinsic clearance (a reflection of metabolic capacity) was 4285 ml/min (range, 2168–6312 ml/min). These results suggest that the majority of the variability in adinazolam plasma concentrations following oral administration is due to the variability in the metabolic capacity of the liver for adinazolam, rather than variability in plasma protein binding.     

N-desmethyladinazolam pharmacokinetics and behavioral effects following administration of 10–50 mg oral doses in healthy volunteers

Results of previous studies suggest that N-desmethyladinazolam, the major metabolite of adinazolam in man, contributes substantially to psychomotor effects and sedation observed following adinazolam administration. Therefore, the pharmacokinetics and pharmacodynamics of N-desmethyladinazolam were explored following administration of single oral doses of placebo and solutions containing 10, 30, and 50 mg N-desmethyladinazolam mesylate in a double-blind, randomized, four-way crossover design to 15 healthy male volunteers. Plasma concentrations of N-desmethyladinazolam were determined by HPLC. Psychomotor performance tests (digit symbol substitution and card sorting by fours and suits), memory tests and sedation scoring were also performed following drug administration. N-desmethyladinazolam pharmacokinetics were dose independent over this range. Doserelated performance effects were observed at 1, 2, and 6 h after dosing. Memory was likewise affected at 2 h. Psychomotor performance decrements correlated with log N-desmethyladinazolam plasma concentrations. Analysis of the relationship between percentage decrements in digit-symbol substitution and plasma N-desmethyladinazolam using the Hill equation revealed a EC₅₀ of 325 ng/ml. These results establish the relationship between N-desmethyladinazolam plasma concentrations and performance effects; these data will be helpful in assessing the contribution of N-desmethyladinazolam to clinical effects observed after adinazolam administration.     

Kinetic Characterization and Identification of the Enzymes Responsible for the Hepatic Biotransformation of Adinazolam and N-Desmethyladinazolam in Man

The kinetics of the N-demethylation of adinazolam to N-desmethyladinazolam (NDMAD), and of NDMAD to didesmethyladinazolam (DDMAD), were studied with human liver microsomes using substrate concentrations in the range 10–1000 μm . The specific cytochrome P450 (CYP) isoforms mediating the biotransformations were identified using microsomes containing specific recombinant CYP isozymes expressed in human lympho-blastoid cells, and by the use of CYP isoform-selective chemical inhibitors. Adinazolam was demethylated by human liver microsomes to NDMAD, and NDMAD was demethylated to DDMAD; the substrate concentrations, K_m, at which the reaction velocities were 50% of the maximum were 92 and 259 μm , respectively. Another metabolite of yet undetermined identity (U) was also formed from NDMAD (K_m 498 μm ). Adinazolam was demethylated by cDNA-expressed CYP 2C19 (K_m 39 μm ) and CYP 3A4 (K_m 83 μm ); no detectable activity was observed for CYPs 1A2, 2C9, 2D6 and 2E1. Ketoconazole, a relatively specific CYP 3A4 inhibitor, inhibited the reaction; the concentration resulting in 50% of maximum inhibition, IC50, was 0·15 μm and the inhibition constant, K_i, was < 0·04 μm in five of six livers tested. Troleandomycin, a specific inhibitor of CYP 3A4, inhibited adinazolam N-demethylation with an IC50 of 1·96 μm . The CYP 2C19-inhibitor omeprazole resulted in only partial inhibition (IC50 21 μm ) and sulphaphenazole, α-naphthoflavone, quinidine and diethyldithiocarbamate did not inhibit the reaction. NDMAD was demethylated by cDNA-expressed CYP 3A4 (K_m 220 μm , Hill number A 1·21), CYP 2C19 (K_m 187 μm , Hill number A 1·29) and CYP 2C9 (K_m 1068 μm ). Formation of U was catalysed by CYP 3A4 alone. Ketoconazole strongly inhibited NDMAD demethylation (IC50 0·14 μm ) and formation of U (IC50 < 0·1 μm ) whereas omeprazole and sulphaphenazole had no effect on reaction rates. These results show that CYP 3A4 is the primary hepatic CYP isoform mediating the N-demethylation of adinazolam and NDMAD. Co-administration of adinazolam with CYP 3A4 inhibitors such as ketoconazole or erythromycin might lead to reduced efficacy, since adinazolam by itself has relatively weak benzodiazepine agonist activity, with much of the pharmacological activity of adinazolam being attributable to its active metabolite NDMAD.     

Alprazolam in the elderly: pharmacokinetics and pharmacodynamics during multiple dosing

Previous studies have suggested that elderly men eliminate alprazolam more slowly than young adults. This study in the elderly was designed to determine whether a change in pharmacokinetics influences the response to alprazolam during multiple dose regimens. In addition, the study was designed to determine alprazolam pharmacokinetics and the degree to which its hydroxymetabolites accumulate, the degree of psychomotor impairment, and whether tolerance to impairment and sedation develops during three different multiple dose regimens. Twenty-six subjects completed this study. The subjects were randomized into one of three treatment groups: 0.25 mg q8h, 0.5 mg q8h, and 2 mg q12h. Subjects remained in the clinic for 8 days (day — 2-day 5). Day 0 was used as a drug free testing day to establish baseline scores for sedation, digit symbol substitution (DSS), card sorting (CS) tasks, and two computer tests. Subjects received the drug according to schedule on days 1 through 4, with day 5 as the washout day. Blood samples were assayed for alprazolam, alpha-hydroxyalprazolam and 4-hydroxyalprazolam. Alpha-hydroxyalprazolam concentrations were below assay detection limits in all subjects in the 0.25 and 0.5 mg q8h groups and 2.6 ng/ml in the 2 mg q12h group. When detectable, 4-hydroxyalprazolam concentrations were <10% of the corresponding alprazolam concentration. Mean alprazolam oral clearance values in the three treatment groups ranged between 0.54 and 0.62 ml/min/kg and half-lives were in excess of 21 h. Degree of sedation and impairment was dose related. Sedation and impairment was not higher on day 4 despite concentrations 2–3 times as great as on day 1, indicating development of tolerance. Subjects were not, however, back to baseline level of performance on day 4.     

Inhibition of the metabolism of etizolam by itraconazole in humans: evidence for the involvement of CYP3A4 in etizolam metabolism

Objective To clarify the involvement of cytochrome P₄₅₀ (CYP) 3A4 in the metabolism of etizolam.Methods The effects of itraconazole, a potent and specific inhibitor of CYP3A4, on the single oral dose pharmacokinetics and pharmacodynamics of etizolam were examined. Twelve healthy male volunteers received itraconazole (200 mg/day) or placebo for 7 days in a double-blind randomized crossover manner, and on the 6th day they received a single oral 1-mg dose of etizolam. Blood samplings and evaluation of psychomotor function using the Digit Symbol Substitution Test and Stanford Sleepiness Scale were conducted up to 24 h after etizolam dosing. Plasma concentration of etizolam was measured by means of high-performance liquid chromatography.Results Itraconazole treatment significantly increased the total area under the plasma concentration–time curve (AUC; 213±106 ngh/ml versus 326±166 ngh/ml, P<0.001) and the elimination half-life (12.0±5.4 h versus 17.3±7.4 h, P<0.01) of etizolam. The 90% confidence interval of the itraconazole/placebo ratio of the total AUC was 1.38–1.68, indicating a significant effect of itraconazole. No significant change was induced by itraconazole in the two pharmacodynamic parameters.Conclusion The present study suggests that itraconazole inhibits the metabolism of etizolam, providing evidence that CYP3A4 is at least partly involved in etizolam metabolism.     

Effects of adinazolam and diazepam,alone and in combination with ethanol,on psychomotor and cognitive performance and on autonomic nervous system reactivity in healthy volunteers

Summary Effects on psychomotor and cognitive performance of adinazolam (15 or 30 mg), alone and in combination with ethanol (0.8 g/kg), were studied in healthy male volunteers and compared to effects of 10 mg diazepam.Adinazolam 30 mg produced relatively long-lasting impairments on tests of tracking, attention, verbal and nonverbal information processing, and memory. Adinazolam 15 mg resulted in descreased visual information processing. Adinazolam decreased supine mean arterial pressure, but only the 15 mg resulted in a tendency for decreased plasma norepinephrine concentrations.After standing for 5 min, 30 mg adinazolam was associated with increased heart rate.Although ethanol consumption produced additive decrements on a continuous performance task, there was little evidence to support a synergistic effect.Adinazolam 30 mg was accompanied by increased self-reports of side effects, especially drowsiness.     

Age and gender effects on the pharmacokinetics and pharmacodynamics of ramelteon, a hypnotic agent acting via melatonin receptors MT1 and MT2

Effects of age and gender on the pharmacokinetics and pharmacodynamics of ramelteon, a hypnotic acting via binding to melatonin MT(1) and MT(2) receptors, were evaluated in healthy young (18-34 years) and elderly (63-79 years) volunteers. Part 1 evaluated the pharmacokinetics of open-label oral ramelteon, 16 mg. Part 2 was a double-blind, randomized, 2-trial crossover pharmacodynamic study of 16-mg ramelteon and matching placebo. Ramelteon clearance was significantly reduced in elderly vs young volunteers (384 vs 883 mL/min/kg, P<.01) and half-life significantly increased (1.9 vs 1.3 h, P<.001). Gender did not significantly influence clearance or half-life. Ramelteon was extensively transformed to its hydroxylated M-II metabolite, with serum AUC values averaging about 30 times those of the parent drug. Compared to placebo, ramelteon increased self- and observer-rated sedation, but age and gender did not influence the magnitude of the ramelteon-placebo difference. Ramelteon did not significantly impair digit-symbol substitution test performance or impair information acquisition and recall. Thus, the reduced clearance and higher serum levels of ramelteon in elderly subjects were not associated with enhanced pharmacodynamic effects. The usually recommended clinical dose of ramelteon (8 mg) does not require modification based on age or gender.     

Single and multiple dose pharmacokinetics of ticlopidine in young and elderly subjects.

The pharmacokinetics of orally administered ticlopidine hydrochloride, a novel inhibitor of platelet aggregation, were determined both after a single dose and after 21 days of twice daily dosing in 12 young (mean 28.6 years) and 13 elderly (mean 69.5 years) subjects. Concentrations of unchanged ticlopidine in plasma were measured by g.l.c. After a single 250 mg dose of ticlopidine, the mean area under the curve, AUC (0-12 h) was 1.11 micrograms ml-1 h in young subjects and 2.04 micrograms ml-1 h in old subjects (P = 0.002). Mean values of t1/2,z in young and elderly subjects were 7.9 h and 12.6 h, respectively (P = 0.01). Steady state plasma drug concentrations were attained after 14 days of dosing with ticlopidine. After the final dose on day 21, AUC values in elderly subjects were 2-3 times those in young subjects (P less than 0.001). The plasma t1/2,z averaged 4.0 days for young subjects and 3.8 days for elderly subjects (P = 0.7). The longer t1/2,z and higher AUC values after multiple dosing probably reflect an increase in bioavailability of ticlopidine after repeated dosing, saturation of metabolism or insufficient analytical sensitivity to characterize the terminal elimination phase after single dose.     

Pharmacokinetics and pharmacodynamics of alprazolam following single and multiple oral doses of a sustained-release formulation

The pharmacokinetics and pharmacodynamics of alprazolam after IV and oral sustained-release (SR) tablet administration were evaluated in 42 healthy, normal, male volunteers. All 42 subjects received a single 1-mg intravenous (IV) alprazolam dose. After a 1-week washout period, the subjects received one of three SR treatments as a single dose: one 1-mg SR tablet, three 1-mg SR tablets, or six 1-mg SR tablets. Beginning 2 days after single-dose SR treatment, each subject received the above SR doses for 3 days. The daily dose for the multiple-dose study was the same as the subject received in the single-dose study. Serial blood samples were collected after each treatment (single-dose IV, single-dose SR, and after the last SR multiple dose), and plasma samples were analyzed by high performance liquid chromatography. Sedation was assessed by a blinded observer at each blood sampling time. Mean pharmacokinetic parameters for IV administration were consistent with previous results. Pharmacokinetic parameters for the SR doses were consistent with linear kinetics over the dosage range studied. The mean absolute bioavailabilities of the SR tablets were greater than 0.84 after single SR doses. Maximal sedation was related to dose after single-dose SR administration. During multiple dosing, chronic tolerance was observed. Maximal sedation scores after 3 days of alprazolam SR administration were independent of the dose administered and were lower after multiple-dose administration than scores observed after single oral SR doses, although plasma alprazolam concentrations were at least 1.5 times higher with multiple dosing. Sedation data indicate that oral SR doses were well tolerated in multiple dosing.(ABSTRACT TRUNCATED AT 250 WORDS)