Pharmacokinetics of Diazepam and Its Metabolites in Urine of Chinese Participants.

BACKGROUND: Urine is conventionally used as a specimen to document diazepam-related crimes; however, few reports have described the pharmacokinetics of diazepam and its metabolites in urine. OBJECTIVE: This study aimed to investigate the pharmacokinetics of diazepam and its metabolites, including glucuronide compounds, in the urine of Chinese participants. METHODS: A total of 28 volunteers were recruited and each participant ingested 5 mg of diazepam orally. Ten milliliters of urine were collected from each participant at post-consumption timepoints of prior (zero), 1, 2, 4, 8, 12, and 24 h and 2, 3, 6, 12, and 15 days. All samples were extracted by solid-phase extraction and analyzed using high-performance liquid chromatography-tandem mass spectrometry. Diazepam and its main metabolites, except for temazepam, were detected in the urine of volunteers. Pharmacokinetic parameters were analyzed using the pharmacokinetic software DAS according to the non-compartment model. RESULTS: Urinary diazepam peaked at 2.38 ng/mL (Cmax) and 1.93 h (Tmax). The urinary metabolite nordiazepam peaked at 1.17 ng/mL and 100.21 h; temazepam glucuronide (TG) peaked at 145.61 ng/mL and 41.14 h; and oxazepam glucuronide (OG) peaked at 101.57 ng/mL and 165.86 h. The elimination half-life (t½z) and clearance (CLz/F) for diazepam were 119.58 h and 65.77 L/h, respectively. The t½z of the metabolites nordiazepam, TG, and OG was 310.58 h, 200.17 h, and 536.44 h, respectively. Finally, this study found that both diazepam and its main metabolites in urine were detectable for at least 15 days, although there were individual differences. CONCLUSION: The results regarding diazepam pharmacokinetics in urine would be of great help in forensic science and drug screening.

Organ distribution of diclazepam, pyrazolam and 3-fluorophenmetrazine.

The organ distribution of 3-fluorophenmetrazine (3-FPM), pyrazolam, diclazepam as well as its main metabolites delorazepam, lormetazepam and lorazepam, was investigated. A solid phase extraction (SPE) and a QuEChERS (acronym for quick, easy, cheap, effective, rugged and safe) - approach were used for the extraction of the analytes from human tissues, body fluids and stomach contents. The detection was performed on a liquid chromatography-tandem mass spectrometry system (LCMS/MS). The analytes of interest were detected in all body fluids and tissues. Results showed femoral blood concentrations of 10 µg/L for 3-FPM, 28 µg/L for pyrazolam, 1 µg/L for diclazepam, 100 µg/L for delorazepam, 6 µg/L for lormetazepam, and 22 µg/L for lorazepam. Tissues (muscle, kidney and liver) and bile exhibited higher concentrations of the mentioned analytes than in blood. Additional positive findings in femoral blood were for 2-fluoroamphetamine (2-FA, approx. 89 µg/L), 2-flourometamphetamine (2-FMA, hint), methiopropamine (approx. 2.2 µg/L), amphetamine (approx. 21 µg/L) and caffeine (positive). Delorazepam showed the highest ratio of heart (C) and femoral blood (P) concentration (C/P ratio = 2.5), supported by the concentrations detected in psoas muscle (430 µg/kg) and stomach content (approx. 210 µg/L, absolute 84 µg). The C/P ratio indicates that delorazepam displays susceptibility for post-mortem redistribution (PMR), supported by the findings in muscle tissue. 3-FPM, pyrazolam, diclazepam, lorazepam and lormetazepam did apparently not exhibit any PMR. The cause of death, in conjunction with autopsy findings was concluded as a positional asphyxia promoted by poly-drug intoxication by arising from designer benzodiazepines and the presence of synthetic stimulants.

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.

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.

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.

Evaluation of plasma diazepam and nordiazepam concentrations following administration of diazepam intravenously or via suppository per rectum in dogs.

OBJECTIVE: To evaluate the pharmacokinetics of diazepam administered per rectum via compounded (ie, not commercially available) suppositories and determine whether a dose of 2 mg/kg in this formulation would result in plasma concentrations shown to be effective for control of status epilepticus or cluster seizures (ie, 150 to 300 ng/mL) in dogs within a clinically useful interval (10 to 15 minutes). ANIMALS: 6 healthy mixed-breed dogs. PROCEDURES: Dogs were randomly assigned to 2 groups of 3 dogs each in a crossover-design study. Diazepam (2 mg/kg) was administered IV or via suppository per rectum, and blood samples were collected at predetermined time points. Following a 6- or 7-day washout period, each group received the alternate treatment. Plasma concentrations of diazepam and nordiazepam were analyzed via reversed phase high-performance liquid chromatography. RESULTS: Plasma concentrations of diazepam and nordiazepam exceeded the targeted range ≤ 3 minutes after IV administration in all dogs. After suppository administration, targeted concentrations of diazepam were not detected in any dogs, and targeted concentrations of nordiazepam were detected after 90 minutes (n = 2 dogs) or 120 minutes (3) or were not achieved (1). CONCLUSIONS AND CLINICAL RELEVANCE: On the basis of these results, administration of 2 mg of diazepam/kg via the compounded suppositories used in the present study cannot be recommended for emergency treatment of seizures in dogs.

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.

Pharmacokinetics of diazepam administered intramuscularly by autoinjector versus rectal gel in healthy subjects: a phase I, randomized, open-label, single-dose, crossover, single-centre study.

BACKGROUND AND OBJECTIVE: Acute repetitive seizures (ARS) are a debilitating part of episodic seizure activity that can sometimes progress to status epilepticus. Currently approved treatment that can be administered by non-medical personnel to patients with ARS is a diazepam rectal gel. While effective, rectal administration can be difficult, inconvenient and objectionable. A diazepam autoinjector has been developed to deliver diazepam via an intramuscular (IM) injection. This study evaluated the dose proportionality of the diazepam autoinjector and the consequent diazepam bioavailability relative to an equivalent dose of diazepam administered rectally as a commercial gel. METHODS: This was a phase I, randomized, open-label, two-part, single-dose, crossover, single-centre pharmacokinetic study in 48 healthy young adult (aged 18-40 years) male and female subjects. Part I of the study (n = 24) evaluated the dose proportionality of three strengths of the diazepam autoinjector (5, 10 and 15 mg) administered into the mid-outer thigh via a deep IM injection. Part II (n = 24) assessed the relative bioavailability of the diazepam 10 mg autoinjector versus the diazepam 10 mg rectal gel. Parts I and II were run concurrently. Each subject completed screening up to 30 days prior to three (Part I) or two (Part II) dosing periods. Serial blood sampling for plasma diazepam and desmethyldiazepam (metabolite) concentrations, vital signs and adverse event (AE) assessments were performed at prespecified times. Treatments were separated by a 14-day washout period. RESULTS: In Part I, dose proportionality was demonstrated for the diazepam autoinjector at 5, 10 and 15 mg doses by increases in mean maximum plasma concentration (C(max)), mean area under the plasma concentration-time curve (AUC) from time zero to infinity (AUC(∞)), and mean AUC from time zero to time of last measurable concentration (AUC(last)). The median time to reach C(max) (t(max)) was consistent at 1 hour for each dose. In Part II of the study, IM administration via diazepam autoinjector (10 mg) resulted in plasma concentrations of both diazepam and desmethyldiazepam that were slightly higher and less variable than those observed following administration of diazepam rectal gel (10 mg). The geometric mean ratio (diazepam autoinjector/diazepam rectal gel) and 90% confidence intervals for diazepam C(max) and AUC(last) were 0.94 (0.84, 1.05) and 1.14 (1.08, 1.21), respectively, indicating that the overall bioavailability of the diazepam autoinjector was approximately 14% higher than that of diazepam rectal gel. Both treatments were generally well tolerated. Although the incidence of treatment-emergent AEs was higher with diazepam autoinjector compared with diazepam rectal gel (21.7% vs 13.6%), the difference can be attributed to injection site pain. Injection site pain also correlated with the diazepam autoinjector dose administered in Part I: 5 mg (4.3%), 10 mg (21.7%) and 15 mg (27.3%). However, no patients discontinued the trial due to injection site pain. No other AEs correlated with dose, and there was no evidence of respiratory depression with either administration. CONCLUSION: Results of the present study indicated that diazepam can be safely and reliably administered IM using a diazepam autoinjector.

Quantification of chlordesmethyldiazepam by liquid chromatography-tandem mass spectrometry: application to a cloxazolam bioequivalence study.

A rapid, sensitive and specific LC-MS/MS method was developed and validated for quantifying chlordesmethyldiazepam (CDDZ or delorazepam), the active metabolite of cloxazolam, in human plasma. In the analytical assay, bromazepam (internal standard) and CDDZ were extracted using a liquid-liquid extraction (diethyl-ether/hexane, 80/20, v/v) procedure. The LC-MS/MS method on a RP-C18 column had an overall run time of 5.0 min and was linear (1/x weighted) over the range 0.5-50 ng/mL (R > 0.999). The between-run precision was 8.0% (1.5 ng/mL), 7.6% (9 ng/mL), 7.4% (40 ng/mL), and 10.9% at the low limit of quantification-LLOQ (0.500 ng/mL). The between-run accuracies were 0.1, -1.5, -2.7 and 8.7% for the above mentioned concentrations, respectively. All current bioanalytical method validation requirements (FDA and ANVISA) were achieved and it was applied to the bioequivalence study (Cloxazolam -- test, Eurofarma Lab. Ltda and Olcadil -- reference, Novartis Biociências S/A). The relative bioavailability between both formulations was assessed by calculating individual test/reference ratios for Cmax, AUClast and AUC0-inf. The pharmacokinetic profiles indicated bioequivalence since all ratios were as proposed by FDA and ANVISA.

Cardiac and peripheral blood similarities in the comparison of nordiazepam and bromazepam blood concentrations.

Concomitant heart and peripheral blood determinations were performed on 40 fatal cases involving nordiazepam (20 cases) and bromazepam (20 cases). The heart blood concentration for the two drugs (588 ng/mL for nordiazepam and 802 ng/mL for bromazepam) does not differ from the corresponding peripheral blood concentration (587 ng/mL for nordiazepam and 883 ng/mL for bromazepam). The mean ratios for the heart and peripheral blood concentrations were 0.95 for nordiazepam and 0.86 for bromazepam. No postmortem redistribution was observed for these two benzodiazepines. The authors thus suggest that corresponding heart blood can be proposed in the quantitative analysis of these drugs when peripheral blood is unavailable. The present study also shows the stability of the two drugs after a year of storage.

Voriconazole and fluconazole increase the exposure to oral diazepam.

OBJECTIVE: We assessed the effect of voriconazole and fluconazole on the pharmacokinetics and pharmacodynamics of diazepam. METHODS: Twelve healthy volunteers took 5 mg of oral diazepam in a randomised order on three study sessions: without pretreatment, after oral voriconazole 400 mg twice daily on the first day and 200 mg twice daily on the second day, or after oral fluconazole 400 mg on the first day and 200 mg on the second day. Plasma concentrations of diazepam and N-desmethyldiazepam were determined for up to 48 h. Pharmacodynamic variables were measured for 12 h. RESULTS: In the voriconazole phase, the area under the plasma concentration time curve (AUC 0-infinity) of diazepam was increased (geometric mean ratio) 2.2-fold (p < 0.05; 90% confidence interval [CI] 1.56 to 2.82). This was associated with the prolongation of the mean elimination half-life (t(1/2)) from 31 h to 61 h (p < 0.01) after voriconazole. In the fluconazole phase, the AUC 0-infinity of diazepam was increased 2.5-fold (p < 0.01; 90% CI 1.94 to 3.40), and the t(1/2) was prolonged from 31 h to 73 h (p < 0.001). The peak plasma concentration of diazepam was practically unchanged by voriconazole and fluconazole. The pharmacodynamics of diazepam were changed only modestly. CONCLUSION: Both voriconazole and fluconazole considerably increase the exposure to diazepam. Recurrent administration of diazepam increases the risk of clinically significant interactions during voriconazole or fluconazole treatment, because the elimination of diazepam is impaired significantly.

Fast in vivo microextraction: a new tool for clinical analysis.

BACKGROUND: We sought to develop a technique with the potential to partly replace current methods of analysis based on blood draws. To achieve this goal, we developed an in vivo microextraction technique that is faster than conventional methods, interferes minimally with the investigated system, minimizes errors associated with sample preparation, and limits exposure to hazardous biological samples. METHODS: Solid-phase microextraction devices based on hydrophilic polypyrrole and polyethylene glycol coatings were used for direct extraction of drugs from the flowing blood of beagle dogs, over a period of 8 h. The drugs extracted on the probes were subsequently quantified by liquid chromatography coupled to tandem mass spectrometry. Two calibration strategies--external and standard on the fiber--were used to correlate the amount extracted with the in vivo concentration. RESULTS: Diazepam and its metabolites were successfully monitored over the course of a pharmacokinetic study, repeated 3 times on 3 beagles. The fast microextraction technique was validated by comparison with conventional plasma analysis, and a correlation factor of 0.99 was obtained. In addition to total concentrations, the method was useful for determining free drug concentrations. CONCLUSIONS: The proposed technique has several advantages and is suitable for fast clinical analyses. This approach could be used not only for drugs, but for any other endogenous or exogenous compounds.

Toxicological data and growth characteristics of single post-feeding larvae and puparia of Calliphora vicina (Diptera: Calliphoridae) obtained from a controlled nordiazepam study.

Larvae of the Calliphora vicina (Diptera: Calliphoridae) were reared on artificial food spiked with different concentrations of nordiazepam. The dynamics of the accumulation and conversion of nordiazepam to its metabolite oxazepam in post-feeding larvae and empty puparia were studied. Analysis was performed using a previously developed liquid chromatography-tandem mass spectrometry (LC-MS/MS) method. This method enabled the detection and quantitation of nordiazepam and oxazepam in single larvae and puparia. Both drugs could be detected in post-feeding larvae and empty puparia. In addition, the influence of nordiazepam on the development and growth of post-feeding larvae was studied. However, no major differences were observed for these parameters between the larvae fed on food containing nordiazepam and the control group. To our knowledge, this is the first report describing the presence of nordiazepam and its metabolite, oxazepam, in single Calliphora vicina larvae and puparia.

Effect of the gene dosage of CgammaP2C19 on diazepam metabolism in Chinese subjects.

OBJECTIVE: To determine whether the gene dosage of CYP2C19 affects the metabolism of diazepam and desmethyldiazepam in healthy Chinese subjects. SUBJECTS AND METHODS: Eighteen unrelated adult men were recruited for the study from a total of 101 healthy Chinese volunteers who had been screened for CYP2C19 phenotype and genotype. All subjects received a single oral dose (5 mg) of diazepam, and the pharmacokinetics of diazepam and desmethyldiazepam were compared in six ml homozygotes (ml/ml), six ml heterozygotes (wt/ml), and six wild-type homozygotes (wt/wt). RESULTS: The plasma elimination half-life values of diazepam (84.0 +/- 13.7 hours) and desmethyldiazepam (176.0 +/- 28.9 hours) in subjects of ml/ml were significantly longer than those (62.9 +/- 9.8 hours for diazepam; 132.1 +/- 24.9 hours for desmethyldiazepam; both P < .01) in subjects of wt/ml or those (20.0 +/- 10.8 hours for diazepam; 99.2.+/- 21.7 hours for desmethyldiazepam; both P < .01) in subjects of wt/wt. A significant difference in the corresponding half-life values existed between the wt/ml and wt/wt subjects (P < .01). As expected, the slowest mean clearance of diazepam was observed in the ml/ml subjects (2.8 +/- 0.9 mL/min) and the fastest in the wt/wt subjects (19.5 +/- 9.8 mL/min), with the wt/ml heterozygotes having an intermediate value (7.2 +/- 2.6 mL/min). CONCLUSION: The presence of a single-nucleotide polymorphism (G681A) of the CYP2C19 gene cosegregates with the impaired metabolism of diazepam and desmethyldiazepam among Chinese subjects in a gene-dosage effect manner.

Effect of sertraline on the pharmacokinetics and protein binding of diazepam in healthy volunteers.

A double-blind randomised placebo-controlled study was conducted in healthy male volunteers to determine the effects of sertraline on the pharmacokinetics of diazepam and its primary metabolite, N-demethyldiazepam. The effect of sertraline on the plasma protein binding of diazepam was also studied. Sertraline 50 mg/day titrated over a 10-day period to 200 mg/day or placebo was administered for 32 days. A single intravenous dose of diazepam 10 mg was given before the start, and after 21 days of sertraline or placebo treatment. The pharmacokinetic analyses were based on data from 20 individuals. The systemic clearance of diazepam decreased by 32% (-0.100 ml/min/kg) in the sertraline group compared with a 19% decrease (-0.054 ml/min/kg) in the placebo group (p = 0.0266). However, this small difference (13%) between the 2 groups was not considered meaningful. Other than a prolonged time to maximum plasma concentration for N-demethyldiazepam, no other pharmacokinetic parameters were significantly altered by sertraline. The plasma protein binding of diazepam was unchanged by concomitant administration of sertraline. These results suggest that sertraline at the maximum recommended dosage under steady-state conditions, and demethylsertraline, the principal metabolite of sertraline, are unlikely to exert significant inhibitory effects on the CYP2C19 and CYP3A3/4 hepatic isoenzymes responsible for the metabolism of diazepam. Therefore, it would be expected that sertraline would, similarly, have a minimal effect on the pharmacokinetic profile of other drugs metabolised by these hepatic isoenzymes.

Assessment of diazepam loading dose therapy of delirium tremens.

The efficacy of the diazepam loading dose method of treatment of delirium tremens was assessed in comparison with the traditional therapy. The experimental group and the control group comprised 51 and 45 patients respectively. The clinical institute withdrawal assessment for alcohol (CIWA-A) scale was applied to assess the intensity of the symptoms. Diazepam doses in the experimental group oscillated from 40 to 210 mg (mean 86.9 +/- 47.2 mg). The control group was receiving diazepam and other psychotropic drugs in divided doses. In the experimental group deliric symptoms were present from 2 to 24 h (mean 6.9 +/- 4.8 h), and in the control group from 2 to 123 h (mean 33.8 +/- 25.7 h). The results show a large efficacy of the loading dose method corresponding to substantial reduction of the psychosis duration (fivefold in comparison to the control group). The method proved to be safe, with no significant complications.

[Benzodiazepines in geriatrics--a case report on prolonged action]. / Benzodiazepine in der Geriatrie--ein kasuistischer Beitrag zum Effekt einer Wirkungsverlängerung.

Due to the age-dependent changes of pharmacodynamic and pharmcokinetic, the frequency of undesirable side-effects of benzodiazepines is higher in geriatric patients. An increased sensitivity to benzodiazepines and their metabolites can induce extremely prolonged duration of action leading to unconsciousness and respiratory insufficiency. Because of an assumed postoperative "psychosyndrome", a 72-year-old patient was treated with high doses of diazepam combined with single doses of tramal, clonidin and ranitidin. This treatment was followed by the development of respiratory insufficiency requiring intensive care with intubation for 8 days including assisted ventilation for 2 days. The serum concentrations of diazepam and its metabolites lay within the therapeutic range until the 7th day after the end of application. Therefore, the authors conclude that when using benzodiazepines in geriatric patients, the physiological peculiarities of this age group and possible interactions with other drugs leading to an increase in potency must be carefully considered.

Lymphatic bioavailability of diazepam and desmethyldiazepam in the rat.

The lymphatic bioavailability (FL) of diazepam (DZ) and its major metabolite desmethyldiazepam (DDZ) was studied. DZ was administered in intravenous and intraduodenal boluses, and in intravenous infusion in three groups of rats with different total lipid (TL) content in the central lymph. The effect of a) different lipophilicity of DZ and DDZ, b) lymphatic TL content, and c) route of DZ administration on FL was determined. It was found that a) FL values of DZ exceeded the FL values of DDZ and b) FL values of DZ increased with increasing TL content in the lymph (an opposite relation was found in DDZ), and c) the highest FL value of DZ + DDZ sum after intravenous bolus administration was attained contrary to the lowest one after intraduodenal bolus administration.

Flumazenil, diazepam, nordiazepam and oxazepam interactions on plasma protein binding.

The effect of flumazenil (FLU) on plasma protein binding of diazepam (DZ), nordiazepam (ND) and oxazepam (OX) was determined in plasma from drug-naive dogs to which graded concentrations of tested drugs alone and in combination were added. The results revealed that as the concentration of FLU added to plasma alone was increased its binding with plasma proteins decreased and that there were no significant binding interactions between FLU and OX, ND and DZ.

Flunitrazepam and nordiazepam slowly released from silastic capsules induce physical dependence in rat.

The rates of in vitro release of flunitrazepam (FN), nordiazepam (ND) and diazepam (DZ) from silastic capsules were compared and found to be in the following order: DZ > FN > ND. Rats that were implanted subcutaneously with capsules filled with FN or ND for 5 to 7 weeks before administering flumazenil (FLU) (40 mg/kg, i.v.) showed precipitated abstinence as measured by the Precipitated Abstinence Score (PAS) which included a rapid onset of clonic and tonic-clonic convulsions. Rats implanted with DZ also demonstrated significant PAS and seizures. Implantation of similar doses of DZ, FN and ND resulted in different plasma levels of parent benzodiazepines and their metabolites that corresponded with their in vitro release: DZ > FN > ND. These data indicate that, as for DZ, the capsule implantation is an effective method of producing physical dependence on FN and ND in the rat.