Metabolic profile of oxazepam and related benzodiazepines: clinical and forensic aspects.

Anxiolytic drugs, namely benzodiazepines, are the most commonly used psychoactive substances since anxiety disorders are prevalent mental disorders particularly in the Western world. Oxazepam is a short-acting benzodiazepine and one of the most frequently prescribed anxiolytic drugs. It is also the active metabolite of a wide range of other benzodiazepines, such as diazepam, ketazolam, temazepam, chlordiazepoxide, demoxazepam, halazepam, medazepam, prazepam, pinazepam, and chlorazepate. Therefore, relevant clinical and forensic outocomes may arise, namely those related to interference in driving performance. It is clinically available as a racemic formulation, with S-enantiomer being more active than R-enantiomer. In humans, it is mainly polimorphically metabolized by glucuronide conjugation at the 3-carbon hydroxyl group, yielding stable diastereomeric glucuronides (R- and S-oxazepam glucuronide). Relevant metabolic and stereoselective interspecies differences have been reported. In this work, the pharmacokinetics of oxazepam with particular focus on metabolic pathways is fully reviewed. Moreover, the metabolic profile of other prescribed benzodiazepines that produce oxazepam as a metabolite is also discussed. It is aimed that knowing the metabolism of oxazepam and related benzodiazepines may lead to the development of new analytical strategies for its early detection and help in further toxicological and clinical interpretations.

Toxicodynetics in nordiazepam and oxazepam overdoses.

OBJECTIVES: Toxicodynetics aims at defining the time-course of major clinical events in drug overdose. We report the toxicodynetics in mono-intoxications with oxazepam and nordiazepam. METHODS: Cases of oxazepam or nordiazepam overdoses collected at the Paris poison control centre from 1999 to 2014 on the basis of self-report. A particular attention was paid to eliminate the concomitant alcohol or psychotropic co-ingestions. The toxicodynetic parameters were assessed as previously described. Results are expressed using 10-90 percentiles. In adults, the dose was normalized (TI, toxic Index) by dividing the supposed ingested dose by the maximal recommended dose. RESULTS: Two hundred and fifty-one and 74 cases of oxazepam and nordiazepam poisonings were included, respectively. The Emax for oxazepam and nordiazepam were sleepiness or obtundation in 106 and 36 cases, respectively. Coma was used to qualify only one oxazepam overdose. The median delay in onset of the Emax was 1.5h (0.33-15) in nordiazepam and 4h (0.5-15) in oxazepam overdose. In both overdoses, the onset of Emax occurred on an "on-off" mode. In adults, the greatest TIs in nordiazepam and oxazepam overdoses were 45 and 26.7, respectively. The TI in the oxazepam-induced coma was 26.7, the largest dose. CONCLUSION: Data collected in PCC allow determining a number of toxicodynetic parameters. Toxicodynetics showed that nordiazepam is not a cause of coma even in large overdose while oxazepam causes coma only at a very high dose. Deep coma in nordiazepam overdose whatever the dose and deep coma in overdose with oxazepam involving TI less than 20 result from unrecognized drug-drug interaction.

Population Pharmacokinetics of High-Dose Oxazepam in Alcohol-Dependent Patients: Is There a Risk of Accumulation?

BACKGROUND: According to the guidelines, benzodiazepines with a short half-life are the reference medication to treat alcohol withdrawal syndrome. The doses of oxazepam used in this population may reach up to 300 mg per day, significantly higher than usual doses. Its use in these patients deserves further information to confirm that the half-life remains constant and that no accumulation appears. The objective of this study was to investigate the pharmacokinetics of high doses of oxazepam in alcohol-dependent patients treated for alcohol withdrawal syndrome. METHODS: Overall, 63 outpatients [weight, 71.1 kg (45.0-118.0); age, 47.6 years (31-67)] followed in the addictology unit, were studied. Total mean dose of 96.0 mg per day (range, 20-300 mg/d) was administered by oral route. Therapeutic drug monitoring allowed the measurement of 96 plasma concentrations. The following covariates were evaluated: demographic data (age, body weight, height, gender) and biological data (creatinine, aspartate aminotransferase, alanine aminotransferase, alkaline phosphatase, gamma-glutamyl transferase). Pharmacokinetic analysis was performed using a nonlinear mixed-effect population model. RESULTS: Data were modeled with a 1-compartment pharmacokinetic model. The population typical mean 90% confidence interval values for clearance, apparent volume of distribution (V), and duration of absorption (D1) were 6.8 L/h (range, 3.9-8.0 L/h), 159 L (range, 98.0-282 L), and 2 hours (fixed), respectively. The interindividual variability of clearance and V, and residual variability (90% confidence interval) were 74% (44%-96%), 69% (40%-89%), and 32% (20%-41%), respectively. The elimination half-life was 16 hours (range, 3-42 hours). CONCLUSIONS: Oxazepam exhibited a linear pharmacokinetics with a proportional relationship from 20 to 300 mg per day, the dose range currently used in alcohol-dependent patients treated for alcohol withdrawal syndrome. We did not find any evidence of drug accumulation with these doses.

Characterization of equine cytochrome P450: role of CYP3A in the metabolism of diazepam.

Research on drug metabolism and pharmacokinetics in large animal species including the horse is scarce because of the challenges in conducting in vivo studies. The metabolic reactions catalyzed by cytochrome P450s (CYPs) are central to drug pharmacokinetics. This study elucidated the characteristics of equine CYPs using diazepam (DZP) as a model compound as this drug is widely used as an anesthetic and sedative in horses, and is principally metabolized by CYPs. Diazepam metabolic activities were measured in vitro using horse and rat liver microsomes to clarify the species differences in enzyme kinetic parameters of each metabolite (temazepam [TMZ], nordiazepam [NDZ], p-hydroxydiazepam [p-OH-DZP], and oxazepam [OXZ]). In both species microsomes, TMZ was the major metabolite, but the formation rate of p-OH-DZP was significantly less in the horse. Inhibition assays with a CYP-specific inhibitors and antibody suggested that CYP3A was the main enzyme responsible for DZP metabolism in horse. Four recombinant equine CYP3A isoforms expressed in Cos-7 cells showed that CYP3A96, CYP3A94, and CYP3A89 were important for TMZ formation, whereas CYP3A97 exhibited more limited activity. Phylogenetic analysis suggested diversification of CYP3As in each mammalian order. Further study is needed to elucidate functional characteristics of each equine CYP3A isoform for effective use of diazepam in horses.

Pharmacokinetics of the cytochrome P-450 substrates phenytoin, theophylline, and diazepam in healthy Greyhound dogs.

The purpose of this study was to determine the pharmacokinetics of phenytoin, theophylline, and diazepam in six healthy Greyhound dogs. Additionally, the pharmacokinetics of the diazepam metabolites, oxazepam and nordiazepam, after diazepam administration was determined. Phenytoin sodium (12 mg/kg), aminophylline (10 mg/kg), and diazepam (0.5 mg/kg) were administered IV on separate occasions, and blood was collected at predetermined time points for the quantification of plasma drug concentrations by fluorescence polarization immunoassay (phenytoin, theophylline) or mass spectrometry (diazepam, oxazepam, and nordiazepam). The terminal half-life was 4.9, 9.2, and 1.0 h, respectively, for phenytoin, theophylline, and diazepam, and 6.2 and 2.4 h for oxazepam and nordiazepam after IV diazepam. The clearance was of 2.37, 0.935, and 27.9 mL · min/kg, respectively, for phenytoin, theophylline, and diazepam. The C(MAX) was 44.7 and 305.2 ng/mL for oxazepam and nordiazepam, respectively, after diazepam administration. Temazepam was not detected above 5 ng/mL in any sample after IV diazepam.

An in vitro approach to estimate putative inhibition of buprenorphine and norbuprenorphine glucuronidation.

An in vitro inhibition study was performed to investigate potential drug-drug interactions on glucuronidation of buprenorphine (BUP) and norbuprenorphine (NBUP), which represents the major elimination pathway of the drug using cDNA-expressed uridine 5'-diphosphate glucuronosyltransferases (UGTs) and human liver microsomes (HLMs). Following identification of major UGT enzymes for BUP and NBUP glucuronidation, substrates were incubated with drugs (amitriptyline, nortriptyline, lamotrigine, oxazepam, and temazepam), which are extensively cleared by glucuronidation as well as are often used during maintenance treatment. To evaluate the inhibitory potential, the half maximal inhibitor concentration (IC(50)), the inhibition constant (K (i)), and the inhibitor concentration (K (I)) that yield half the maximum rate of inactivation and the enzyme inactivation rate constant (k (inact)) were determined, if appropriate. Amitriptyline and temazepam are inhibitors of NBUP glucuronidation (UGT1A3, HLMs), whereas BUP glucuronidation was affected by amitriptyline (HLMs), oxazepam, and temazepam (UGT2B7). Additionally, BUP inhibits NBUP glucuronidation (UGT1A1, 1A3, HLMs) and vice versa (UGT1A3). A decrease in the metabolic clearance of NBUP may increase the risk of adverse effects such as respiratory depression. Further investigations are needed to evaluate whether inhibition of BUP and NBUP glucuronidation contributes to adverse events.

Construction and Verification of Physiologically Based Pharmacokinetic Models for Four Drugs Majorly Cleared by Glucuronidation: Lorazepam, Oxazepam, Naloxone, and Zidovudine.

Physiologically based pharmacokinetic (PBPK) modeling is less well established for substrates of UDP-glucuronosyltransferases (UGT) than for cytochrome P450 (CYP) metabolized drugs and more verification of simulations is necessary to increase confidence. To address specific challenges of UGT substrates, we developed PBPK models for four drugs cleared majorly via glucuronidation (lorazepam, oxazepam, naloxone, and zidovudine). In vitro to in vivo scaling of intrinsic clearance generated with co-cultured human hepatocytes was applied for hepatic metabolism and extra-hepatic clearance was extrapolated based on relative expression of UGT isoforms in the liver, kidney, and intestine. Non-metabolic clearance and the contributions of individual UGT isoforms to glucuronidation were based on in vitro and in vivo studies taken from the literature and simulations were verified and evaluated with a broad set of clinical pharmacokinetic data. Model evaluation showed systemic clearance predictions within 1.5-fold for all drugs and all simulated parameters were within 2-fold of observed. However, during the verification step, top-down model fitting was necessary to adjust for under-prediction of zidovudine VSS and renal clearance and over estimation of intestinal first pass for lorazepam, oxazepam, and zidovudine. The impact of UGT2B15 polymorphisms on the pharmacokinetics of oxazepam and lorazepam was simulated and glucuronide metabolites were also simulated for all four drugs. To increase confidence in predicting extra-hepatic clearance, improvement of enzyme phenotyping for UGT substrates and more quantitative tissue expression levels of UGT enzymes are both needed. Prediction of glucuronide disposition is also challenging when active transport processes play a major role.

The concentration of oxazepam and oxazepam glucuronide in oral fluid, blood and serum after controlled administration of 15 and 30 mg oxazepam.

AIMS: To measure and compare the concentration-time profiles of oxazepam and oxazepam glucuronide in blood, serum and oral fluid within the scope of roadside testing. METHODS: Biological samples were collected from eight male subjects after ingestion of 15 or 30 mg oxazepam on separate dosing occasions with an interval of 7 days. The concentration-time profiles of oxazepam and oxazepam glucuronide were fitted by using a one-compartment model. RESULTS: For oxazepam and oxazepam glucuronide, the mean oral fluid/blood ratios were 0.05 (range 0.04-0.07) and 0.004 (range 0.002-0.006), respectively. The concentration-time profiles in oral fluid paralleled those in blood. CONCLUSION: After oral administration of therapeutic doses of oxazepam, concentrations in oral fluid are very much lower than those in blood, and those of oxazepam glucuronide are much lower than those of the parent compound. Nevertheless, assay of oral fluid for oxazepam can be used to detect recent ingestion of the drug in drivers suspected of impaired driving performance.

Effects of the combination of metyrapone and oxazepam on cocaine and food self-administration in rats.

For several years, our laboratory has investigated the role for the HPA axis in cocaine reinforcement. Two classes of drugs that we have studied include corticosterone synthesis inhibitors (e.g., metyrapone) and benzodiazepine receptor agonists (e.g., oxazepam). In the experiments described in this manuscript, we tested the effects of various doses of metyrapone and oxazepam against several doses of self-administered cocaine. Behavioral, endocrine and pharmacokinetic measures of the effects of the combination of metyrapone and oxazepam on cocaine reward are presented. Combinations of metyrapone and oxazepam at doses that produced no observable effects when administered separately significantly reduced cocaine self-administration without affecting food-maintained responding during the same sessions. Changes in pharmacokinetics or endocrine function do not appear to mediate these effects, suggesting a central mechanism of action. Therefore, although these drugs produce their effects through distinct mechanisms, an additive effect on cocaine self-administration is obtained when these drugs are administered together, suggesting that combinations of low doses of metyrapone and oxazepam may be useful in reducing cocaine seeking with a reduced incidence of unwanted side effects and a decreased potential for abuse.

New high-performance liquid chromatographic method for serum analysis of oxazepam: application to bioequivalence and pharmacokinetic study.

A rapid and sensitive high-performance liquid chromatographic method was developed and validated for determination of oxazepam in serum. Oxazepam was isolated from biological fluid using a simple liquid-liquid extraction with dichloromethane. Nordazepam was used as the internal standard. The chromatographic separation was accomplished using a 125 x 4-mm (inner diameter) stainless-steel (5 microm) Perfectsil Target ODS-3 reversed phase column with a mobile phase consisting of ammonium dihydrogen phosphate buffer (0.05 mol x L(-1), pH 5.8) and methanol (50:50, v/v), running at a flow rate of 1.5 ml x min(-1). The absorbance of the fluent was monitored at 254 nm. The developed method resulted in totally symmetrical peaks. It has been applied to assess the pharmacokinetics of oxazepam. Also the bioequivalence of two different oxazepam preparations following oral administration in healthy volunteers was assessed by this method.

Site-, Technique-, and Time-Related Aspects of the Postmortem Redistribution of Diazepam, Methadone, Morphine, and their Metabolites: Interest of Popliteal Vein Blood Sampling.

Sampling site, technique, and time influence postmortem drug concentrations. In 57 cases, we studied drug concentration differences as follows: subclavian vein-dissection/clamping versus blind stick, femoral vein-dissection/clamping versus blind stick, right cardiac chamber, and popliteal vein-dissection and clamping only. Cases were distributed in group #1 (all cases with both techniques), group #2 (dissection/clamping), and group #3 (blind stick). Sampled drugs were diazepam, methadone, morphine, and their metabolites. To assess PMR, mean concentrations and ratios were calculated for each group. Time-dependent variations of blood concentrations and ratios were also assessed. Results indicate that site, method, and time may influence postmortem distribution interpretation in different ways. Popliteal blood seems less subject to PMR. In conclusion, our study is the first to evaluate concurrently three main aspects of PMR and confirms that the popliteal vein may represent a site that is more resistant to the changes seen as a result of PMR.

Home alone-The effects of isolation on uptake of a pharmaceutical contaminant in a social fish.

A wide range of biologically active pharmaceutical residues is present in aquatic systems worldwide. As uptake potential and the risk of effects in aquatic wildlife are directly coupled, the aim of this study was to investigate the relationships between stress by isolation, uptake and effects of the psychiatric pharmaceutical oxazepam in fish. To do this, we measured cortisol levels, behavioral stress responses, and oxazepam uptake under different stress and social conditions, in juvenile perch (Perca fluviatilis) that were either exposed (1.03µgl-1) or not exposed to oxazepam. We found single exposed individuals to take up more oxazepam than individuals exposed in groups, likely as a result of stress caused by isolation. Furthermore, the bioconcentration factor (BCF) was significantly negatively correlated with fish weight in both social treatments. We found no effect of oxazepam exposure on body cortisol concentration or behavioral stress response. Most laboratory experiments, including standardized bioconcentration assays, are designed to minimize stress for the test organisms, however wild animals experience stress naturally. Hence, differences in stress levels between laboratory and natural environments can be one of the reasons why predictions from artificial laboratory experiments largely underestimate uptake of oxazepam, and other pharmaceuticals, in the wild.

Interindividual variability in the glucuronidation of (S) oxazepam contrasted with that of (R) oxazepam.

Although conjugation with glucuronic acid is a major process for converting many xenobiotics into hydrophilic, excretable metabolites, relatively little has been reported concerning interindividual variability of glucuronidation in human populations. Oxazepam, a therapeutically active metabolite of diazepam, is one of a number of C3-hydroxylated benzodiazepines for which glucuronide conjugation is the predominant pathway of biotransformation. The drug is normally formulated as a racemic mixture of inactive (R) and active (S) enantiomers. In the present study we have investigated the use of oxazepam as a potential probe drug for studying the variability of glucuronide conjugation, and for demonstrating the extent to which genetic factors may be responsible. In preliminary studies we determined oxazepam pharmacokinetics metabolite profiles after administration of racemic (R,S) oxazepam to eleven human volunteers. The (S) glucuronide was preferentially formed and excreted in nine of the eleven subjects. The ratios of (S) to (R) glucuronide metabolites (S/R ratios) were 3.87 +/- 0.79 (mean +/- SD) and 3.52 +/- 0.60 in urine and plasma, respectively. However, both ratios were significantly lower in two subjects (p < 0.01). In these two atypical subjects, the half-life of (R,S) oxazepam was also markedly longer (14.7 and 15.9 h) than in the other subjects (8.1 +/- 3.2 h). A good correlation (rs = 0.90) between the S/R-glucuronide ratio in urine and the plasma clearance of (R,S) oxazepam suggested that a low S/R ratio may be a marker of poor elimination of oxazepam. In further investigations, the drug was administered to 66 additional subjects. The S/R-glucuronide ratio in 8 h pooled urine was bimodally distributed, with 10% of all subjects possessing ratios below an apparent antimode of 1.9. A survey of the in vitro formation of oxazepam glucuronides by microsomes from 37 human livers also showed that 10% of the livers displayed an abnormally high apparent Michaelis constant (Km) for the formation of the (S) glucuronide, but not of the (R) glucuronide. These results suggest that the glucuronidation of the pharmacologically active (S) enantiomer of oxazepam is decreased in a significant percentage (10%) of Caucasian individuals. The observed in vitro differences in apparent kinetics of the S-glucuronidation reaction may reflect defects at the genetic level, leading to structural changes in the isozyme(s) of UDP-glucuronyltransferase that catalyse this reaction.

Effects of protein and carbohydrate content of diet on drug conjugation.

Eight healthy subjects were fed a high-protein-low-carbohydrate diet and, after a 3-day washout period, an isocaloric low-protein-high-carbohydrate diet. They received acetaminophen and oxazepam, drugs metabolized primarily by conjugation, on days 11 and 13, respectively, of each diet. Changing the diets of subjects from the high-protein-low-carbohydrate diet to the low-protein-high-carbohydrate diet resulted in a 14% increase in urinary recovery of acetaminophen glucuronide and a 32% increase in urinary recovery of oxazepam glucuronide (p less than 0.05). The increases in glucuronidation were at the expense of other pathways of metabolism, and there were no significant changes in the metabolic clearance rates of acetaminophen and oxazepam. Mean renal clearances of acetaminophen glucuronide, acetaminophen sulfate, and oxazepam glucuronide decreased 45%, 32%, and 54%, respectively (p less than 0.05), when the subjects were switched to the low-protein-high-carbohydrate diet.

Pharmacokinetics of zidovudine alone and in combination with oxazepam in the HIV infected patient.

This three-phase study was designed to determine if a pharmacokinetic drug-drug interaction exists between zidovudine and oxazepam. Six individuals infected with human immunodeficiency virus (HIV) and receiving zidovudine at 500 mg daily, with normal renal and hepatic function, were enrolled. During phase I, zidovudine pharmacokinetics were studied after steady-state oral administration (100 mg every 4 h) and after a single dose (70 mg) of intravenous zidovudine. Phase II consisted of a single oral dose (30 mg) of oxazepam followed by a 48-h blood sampling period. Phase III began with 48 h of concomitant zidovudine, 100 mg orally every 4 h, and oxazepam, 15 mg orally every 8 h, followed by concomitant dosing of intravenous zidovudine and oral oxazepam. Zidovudine concentrations were determined by radioimmunoassay. Oxazepam concentrations were determined with use of a fluorescence polarization immunoassay. The calculated bioavailability was 0.61 for zidovudine alone and 0.75 when administered in combination with oxazepam (p = 0.16). Plasma half-life for oral zidovudine alone and in combination with oxazepam was 1.17 h versus 0.99 h, respectively (p = 0.25), and 1.38 h versus 1.15 h (p = 0.38) for intravenous zidovudine during single and combination therapy, respectively. Total body clearance of zidovudine was not significantly altered by oxazepam (93 L/h vs. 109 L/h, p = 0.16). The mean pharmacokinetic parameters determined for a single 30-mg dose of oxazepam for oral clearance, apparent volume of distribution, and plasma half-life were 9.8 L/h, 65.7 L, and 5.1 h, respectively.(ABSTRACT TRUNCATED AT 250 WORDS)

Pharmacokinetic-pharmacodynamic modelling of the anticonvulsant effect of oxazepam in individual rats.

1. The purpose of this investigation was to examine in vivo drug-concentration anticonvulsant effect relationships of oxazepam in individual rats following administration of a single dose. 2. Whole blood concentration vs time profiles of oxazepam were determined following administration of doses of 4, 8 and 12 mg kg-1. The pharmacokinetics could be described by an open 2-compartment pharmacokinetic model. Following 12 mg kg-1 the values (mean +/- s.e., n = 11) of clearance and volume of distribution were 28 +/- 2 ml min-1 kg-1 and 2.6 +/- 0.31 kg-1, respectively, and were not significantly different from the values obtained at the other doses. 3. The anticonvulsant effect was quantitated by a new technique which allows repetitive determination of the convulsive threshold by direct cortical stimulation within one rat. Significant dose-dependent elevations of the seizure threshold were observed. 4. By pharmacokinetic-pharmacodynamic modelling, a log-linear relationship was found between concentration and anticonvulsant effect. Following 12 mg kg-1 the values (mean +/- s.e., n = 11) of the pharmacodynamic parameters slope and minimal effective concentration (Cmin) were 243 +/- 27 microA and 0.11 +/- 0.02 mg l-1, respectively and not significantly different from the values obtained at the other doses. 5. In a repeatability study the pharmacodynamic parameters were determined twice on two different occasions with an interval of two weeks in the same group of 11 rats. The inter-animal variability in the pharmacodynamic parameter slope was 46%, whereas the intra-animal variability was 24 +/- 18%. The value of the minimal effective concentration was in each animal and on each occasion close to zero within the relatively narrow range of 0.01-0.30mgI. 6. The results of this study showed that it is possible to determine in vivo concentration-anticonvulsant effect relationships of oxazepam under non-steady-state conditions in individual rats. The anti-convulsant effect of oxazepam appeared to be a rapidly reversible direct effect and acute tolerance did not develop within the time frame of the experiments.

Pharmacodynamics of the anticonvulsant effect of oxazepam in aging BN/BiRij rats.

1. The purpose of this investigation was to examine the influence of increasing age on the pharmacokinetics and the time course of the anticonvulsant response of oxazepam in BN/BiRij rats as an animal model of aging. 2. Oxazepam was administered intravenously in a dose of 12 mg kg-1 body weight and the anticonvulsant effect intensity was measured as elevation above baseline of a threshold for induction of localized seizure activity (TLS). Direct cortical stimulation with ramp shaped electrical pulse trains of increasing intensity was used to determine this threshold. 3. The pharmacological effect vs. time profile showed in young rats an anticonvulsant component followed by proconvulsant component which is suggestive for the occurrence of acute tolerance and/or withdrawal syndrome. With increasing age the proconvulsant component disappeared, resulting in a monophasic effect profile (anticonvulsant effect only) at the age of 35 months with significantly higher anticonvulsant effect intensity immediately following drug administration. No age-related changes in the pharmacokinetic parameters of oxazepam were observed. 4. In five animals of each age group, benzodiazepine receptor binding characteristics were determined in vitro with [3H]-flunitrazepam as a ligand. Both receptor density and affinity did not show age-related changes. Available literature data on post-receptor events do not indicate conclusive age-related changes. 5. It is concluded, that the observed change in the pharmacodynamics of anticonvulsant effect of oxazepam can be explained by the disappearance of the tolerance/withdrawal phenomenon. This is compatible with a decreased efficiency of homeostatic control mechanisms in the elderly.

Distribution of diazepam, nordiazepam, and oxazepam between brain extraneuronal space, brain tissue, plasma, and cerebrospinal fluid in diazepam and nordiazepam dependent dogs.

The compartmental distribution of diazepam (DZ) and nordiazepam (ND) and their metabolites was studied in DZ and ND dependent dogs. The levels of DZ, and ND and their metabolites were determined during the last week of stabilization in the extraneuronal brain space, in brain tissue, in plasma and in CSF. In these studies dependent dogs were anesthetized with pentobarbital and microdialysis probes were inserted bilaterally into the parietal cortex and perfused with artificial cerebrospinal fluid. Microdialysis probes were also used to determine the unbound parent drugs and their metabolites in plasma. The brain-plasma distribution of total ND and oxazepam (OX) is about equal in ND dependent dogs but in DZ dependent dogs total ND and OX are about 2-fold higher in brain than in plasma. The levels of DZ, ND, and OX in the extraneuronal brain space are similar to their unbound levels in plasma. These data suggest that the concentration of free benzodiazepines in plasma is a good approximation of the concentration in the vicinity of the membrane receptors in the dependent dogs.

Pharmacokinetic and pharmacodynamic interaction between the antidepressant tianeptine and oxazepam at steady-state.

To assess if any pharmacokinetic or pharmacodynamic interaction at steady-state occurs between the new antidepressant tianeptine and a benzodiazepine (oxazepam) following multiple oral dosing of both drugs, 12 healthy male volunteers entered a balanced three-way double blind cross-over study. Tianeptine (12.5 mg) and/or oxazepam (10 mg) were given three times daily for 4 days. Pharmacokinetic data within a dosing interval at steady-state showed that there were no statistically significant changes in the pharmacokinetics of either tianeptine (and its two major metabolites) or oxazepam when both drugs were co-administered. Psychometric data showed that there was no synergistic negative interaction between the two drugs and that their combination may result in beneficial effects on "alertness" and "happiness".

Oxazepam: update 1989.

Oxazepam is an anxiolytic with established clinical efficacy. Compared to other benzodiazepines it may offer advantages in some patient populations, such as the elderly. Oxazepam has not been associated with more or different risks than other benzodiazepines, and there is no evidence that physiological dependence occurs more frequently with oxazepam than other benzodiazepines. Available evidence suggests that oxazepam may be associated with a lower risk of seizure-induction than lorazepam and alprazolam, and that compared to diazepam, oxazepam may have lower abuse potential.