Interaction study between fluvoxamine and quazepam

It has been reported that fluvoxamine, an inhibitor of various cytochrome P450 enzymes, markedly inhibits the metabolism of several drugs. The purpose of the present study was to examine a possible interaction between fluvoxamine and quazepam. Twelve healthy male volunteers received fluvoxamine 50 mg/day or placebo for 14 days in a double-blind randomized crossover manner, and on the 4th day they received a single oral 20-mg dose of quazepam. Blood samplings and evaluation of psychomotor function by the Digit Symbol Substitution Test and Stanford Sleepiness Scale were conducted up to 240 hours after quazepam dosing. Plasma concentrations of quazepam and its active metabolites 2-oxoquazepam (OQ) and N-desalkyl-2-oxoquazepam (DOQ) were measured by high-performance liquid chromatography (HPLC). Fluvoxamine did not change plasma concentrations of quazepam but significantly decreased those of OQ from 6 to 12 hours and those of DOQ from 3 to 48 hours. The AUC ratio of OQ to quazepam was significantly lower in the fluvoxamine phase. Fluvoxamine did not affect psychomotor function at most of the time points. The present study suggests that fluvoxamine slightly inhibits the metabolism of quazepam to OQ, but this interaction appears to have minimal clinical significance.     

Effects of itraconazole on the plasma kinetics of quazepam and its two active metabolites after a single oral dose of the drug

The effects of itraconazole, a potent inhibitor of cytochrome P450 (CYP) 3A4, on the plasma kinetics of quazepam and its two active metabolites after a single oral dose of the drug were studied. Ten healthy male volunteers received itraconazole 100 mg/d or placebo for 14 days in a double-blind randomized crossover manner, and on the fourth day of the treatment they received a single oral 20-mg dose of quazepam. Blood samplings and evaluation of psychomotor function by the Digit Symbol Substitution Test and Stanford Sleepiness Scale were conducted up to 240 h after quazepam dosing. Itraconazole treatment did not change the plasma kinetics of quazepam but significantly decreased the peak plasma concentration and area under the plasma concentration-time curve of 2-oxoquazepam and N-desalkyl-2-oxoquazepam. Itraconazole treatment did not affect either of the psychomotor function parameters. The present study thus suggests that CYP 3A4 is partly involved in the metabolism of quazepam.     

Disposition and metabolic fate of 14C-quazepam in man

The absorption, metabolism, and excretion of quazepam, a new benzodiazepine hypnotic, was investigated in six normal male volunteers after oral administration of 25 mg 14C-quazepam in solution. Quazepam was well absorbed. Plasma radioactivity peaked (324.6 ng quazepam eq/ml) 1.75 hr postdose. Unchanged quazepam reached its maximum plasma level (148 ng/ml) at 1.5 hr with an apparent absorption half-life of 0.4 hr. Major plasma metabolites of quazepam were 2-oxoquazepam (OQ), obtained by replacement of S by O,N-desalkyl-2-oxoquazepam (DOQ), and 3-hydroxy-2-oxoquazepam (HOQ) glucuronide. Both OQ and DOQ are pharmacologically active. Plasma elimination half-lives for quazepam, OQ, DOQ, and radioactivity were 39, 40, 69, and 76 hr, respectively. The respective AUC (120 hr) values were 715, 438, 3323, and 11402 hr X ng/ml. Approximately 54% of the radioactive dose was excreted in the urine (31.3%) and feces (22.7%) over a 5-day period. HOQ glucuronide was the major urinary metabolite of quazepam. Other metabolites present in the urine in relatively large amounts were glucuronides of DOQ and HDOQ.     

Placental transfer of quazepam in mice

The disposition of 14C-quazepam following a single 5-mg/kg po dose was studied at the postembryonic period (day 12 of pregnancy) and near-term (day 18 of pregnancy). In both 12- and 18-day pregnant mice, radioactivity from the quazepam dose was widely distributed in the maternal tissues, with the highest levels in the liver and kidneys. At the time points analyzed (1, 5, and 24 hr post-dose), radioactivity levels in the fetus were consistently 44% of the maternal plasma levels in 12-day pregnant mice. In 18-day pregnant mice, fetal radioactivity levels at these time points were consistently equal to or slightly greater than maternal plasma levels. This indicates that radioactivity was taken up and eliminated from fetal tissues at rates that were reasonably similar to those in corresponding maternal tissues. No accumulation of radioactivity was observed in the fetus or in maternal tissues in either the 12-day or the 18-day pregnant mice. In 18-day pregnant mice, concentrations of quazepam and its metabolites were measured either by gas-liquid chromatography or thin layer radiochromatography. In the maternal plasma, concentrations of quazepam, its first-formed metabolite, 2-oxoquazepam, and 3-hydroxy-2-oxoquazepam were relatively low at all time points; levels of N-desalkyl-2-oxoquazepam and 3-hydroxy-N-desalkyl-2-oxoquazepam (HDOQ) were much higher. Fetal levels of unchanged drug and metabolites were generally less than or equal to maternal plasma levels, except for HDOQ levels, which were higher in the fetus.(ABSTRACT TRUNCATED AT 250 WORDS)     

In vitro metabolism of quazepam in human liver and intestine and assessment of drug interactions

The study was carried out to identify and characterize kinetically the cytochrome P450 (CYP) enzymes responsible for the major metabolite formation of quazepam. In in vitro studies using human liver and intestinal microsomes and cDNA-expressed human CYP and FMO isoenzymes, quazepam was rapidly metabolized mainly by CYP3A4 and to a minor extent by CYP2C9, CYP2C19 and FMO1 to 2-oxoquazepam (OQ), which was then further biotransformed to N-desalkyl-2-oxoquazepam (DOQ) and to 3-hydroxy-2-oxoquazepam (HOQ) mainly by CYP3A4 and CYP2C9. CYP3A4 is the enzyme predominantly responsible for all the metabolic pathways of quazepam. Itraconazole inhibited the formation of OQ from quazepam, HOQ from OQ and DOQ from OQ in human liver microsomes with Ki values of 8.40, 0.08 and 0.39 microM, respectively. However, the Ki for OQ formation was greater than the peak plasma itraconazole concentration following a clinically relevant 200-mg oral dose to healthy volunteers. In addition, CYP2C9 and CYP2C19 inhibitors failed to inhibit OQ formation from quazepam. In conclusion, clinically relevant drug interaction with CYP inhibitors seem unlikely for the major metabolic pathway of quazepam to OQ.     

Effect of dietary fat content in meals on pharmacokinetics of quazepam

Dietary fat content in meals has been reported to increase the absorption of several drugs proportionately. However, there is no information about the effects of dietary fat in meals on the sedative hypnotic agent quazepam, although limited data suggest that food intake alters quazepam absorption. Therefore, the authors measured and compared pharmacokinetic parameters of quazepam taken in a fasted state and taken 30 minutes after consuming meals containing different amounts of dietary fat. A three-arm randomized crossover study was conducted. Nine healthy male volunteers took a single oral 20-mg dose of quazepam under the following conditions: (1) after fasting overnight for at least 12 hours, (2) 30 minutes after consuming a low-fat meal (two slices of bread and 200 ml of apple juice), or (3) 30 minutes after consuming high-fat meal (two slices of bread with 30 gm of butter and 200 ml of apple juice). Plasma concentrations of quazepam and its metabolite, 2-oxoquazepam, were monitored up to 48 hours after the dosing. In comparison with corresponding plasma values for quazepam taken in a fasting state, the peak concentrations (Cmax) of quazepam taken 30 minutes after consuming a low-fat meal and high-fat meal were 243% (90% confidence interval [CI] = 161%-325%) and 272% (90% CI = 190%-355%), respectively. Area under the plasma concentration-time curve from 0 to 8 hours (AUC(0-8)) and 0 to 48 hours (AUC(0-48)) of quazepam was increased with the low-fat meal by 2-fold (90% CI = 1.5- to 2.7-fold) and 1.4-fold (90% CI = 1.0- to 1.7-fold), respectively, and with the high-fat meal by 2.2-fold (90% CI = 1.3- to 3-fold) and 1.5-fold (90% CI = 0.7- to 2.4-fold), respectively. The pharmacokinetic change in 2-oxoquazepam to the parent compound was similar. Quazepam was well tolerated, with no significant difference in the Stanford Sleepiness Scale between fasted and fed conditions. These findings show that food intake has an evident effect on quazepam absorption, but further studies are needed to clarify a determinant factor of this alteration (2.5-fold for Cmax and 2.1-fold for AUC(0-8), on average). It might not be necessary to do dose adjustment with meal content because quazepam is well tolerated.     

Single oral dose pharmacokinetics of quazepam is influenced by CYP2C19 activity

The effects of cytochrome P450 (CYP)2C19 activity and cigarette smoking on the single oral dose pharmacokinetics of quazepam were studied in 20 healthy Japanese volunteers. Twelve subjects were extensive metabolizers (EMs), and 8 subjects were poor metabolizers (PMs) by CYP2C19 as determined by the PCR-based genotyping. Nine subjects were smokers (>10 cigarettes/d), and 11 subjects were nonsmokers. The subjects received a single oral 20-mg dose of quazepam, and blood samplings and evaluation of psychomotor function were conducted up to 72 hours after dosing. Plasma concentrations of quazepam and its active metabolite 2-oxoquazepam (OQ) were measured by HPLC. There were significant differences between EMs and PMs in the peak plasma concentration (mean +/- SD: 34.5 +/- 16.6 versus 66.2 +/- 19.2 ng/mL, P < 0.01) and total area under the plasma concentration-time curve (490.1 +/- 277.5 vs 812.1 +/- 267.2 ng x h/mL, P < 0.05) of quazepam. The pharmacokinetic parameters of OQ and pharmacodynamic parameters were not different between the 2 groups. Smoking status did not affect the pharmacokinetic parameters of quazepam and OQ or pharmacodynamic parameters. The present study suggests that the single oral dose pharmacokinetics of quazepam are influenced by CYP2C19 activity but not by cigarette smoking.     

Time effects of food intake on the pharmacokinetics and pharmacodynamics of quazepam

AIMS: There is little information on interaction between food and the hypnotic agent quazepam. We therefore studied the effects of food and its time interval on the pharmacokinetics and pharmacodynamics of quazepam. METHODS: A randomized three-phase crossover study with 2-week intervals was conducted. Nine healthy male volunteers took a single oral 20 mg dose of quazepam under the following conditions: 1) after fasting overnight; 2) 30 min after eating standard meal; or 3) 3 h after eating the same meal. Plasma concentrations of quazepam and its metabolite, 2-oxoquazepam and psychomotor function using the Digit Symbol Substitute Test (DSST), Stanford Sleepiness Scale (SSS) and Visual Analogue Scale were measured up to 48 h. RESULTS: During the food treatments at 30 min and 3 h before dosing, the peak concentrations (Cmax) were 300% (95% CI 260, 340%; P < 0.001) and 250% (95% CI 210, 290%; P < 0.01) of the corresponding value during the fasting phase. For quazepam, the area under the plasma concentration-time curve from 0 to 8 h measured at 30 min and 3 h before dosing was significantly increased, with the food treatments by 2.4-fold (95% CI 2.0; 2.8-fold; P < 0.001) and 2.1-fold (95% CI 1.7; 2.4-fold; P < 0.01), respectively. In response to pharmacokinetic changes, some of the pharmacodynamics (DSST, P < 0.05; SSS, P < 0.05) differed significantly between fasted status and fed status. No difference was found in any pharmacokinetic or pharmacodynamic parameters between the two food treatment phases. CONCLUSIONS: A food effect on quazepam absorption is evident and continues at least until 3 h after food intake. The dosing of quazepam after a long period of ordinary fasting might reduce its efficacy because a 3 h interval between the timing of the evening meal and bedtime administration of hypnotics is regarded as normal in daily life.     

Liquid Chromatographic Assay and Pharmacokinetics of Quazepam and Its Metabolites Following Sublingual Administration of Quazepam

A reverse-phase liquid chromatographic method is described for simultaneous quantification of quazepam, and two of its metabolites, 2-oxoquazepam and N-desalkyl-2-oxoquazepam. The method uses a solid-phase extraction procedure to prepare plasma samples. After extraction, the methanolic extract is evaporated; the residue is then reconstituted in a small volume of mobile phase and chromatographed. The total chromatography time for a single sample is about 20 min. A sensitivity of 1 ng/ml for quazepam and its metabolites is attained when 1 ml of plasma is extracted. Analytical recovery of quazepam and its metabolites added to plasma ranged from 87 to 96%. The maximum within-day and day-to-day coefficients of variation for each compound at concentrations of 20 and 60 ng/ml were 7.6 and 11.2%, respectively. The method was applied to sublingual pharmacokinetic studies of quazepam in healthy volunteers.     

Quazepam: hypnotic efficacy and side effects

Quazepam is a benzodiazepine hypnotic that can be useful in the adjunctive pharmacologic treatment of insomnia. It is slowly eliminated due to the long elimination half-lives of the parent compound and its two active metabolites, 2-oxoquazepam and N-desalkyl-2-oxoquazepam. This drug is recommended in doses of 15 mg for adults and 7.5 mg for geriatric patients. Sleep laboratory studies and clinical trials have shown that the 15 mg dose is quite efficacious for inducing and maintaining sleep not only with initial and short-term use but also with continued use. The 7.5 mg dose which has been studied less extensively has also been shown to be effective for inducing and maintaining sleep. There is considerable evidence of carryover effectiveness both during drug administration and after withdrawal. Thus, rebound phenomena are not observed during administration (early morning insomnia and daytime anxiety) and after withdrawal (rebound insomnia). Furthermore, certain behavioral side effects that have occurred with certain benzodiazepines (triazolam) have not been reported with quazepam. The only notable side effect seen with quazepam is a variable degree of daytime sedation, which can be minimized by intermittent use of the 15 mg dose when necessary and use of the 7.5 mg dose in the elderly. In comparison to triazolam and temazepam, quazepam is more effective with short-term use, and with continued use it maintains its efficacy in contrast to both of these drugs which show rapid development of tolerance. Most important, quazepam lacks the frequent and severe side effects increasingly reported with triazolam use or following its withdrawal.     

Interaction between grapefruit juice and hypnotic drugs: comparison of triazolam and quazepam

Objective: Grapefruit juice (GFJ) inhibits cytochrome P450 (CYP) 3A4 in the gut wall and increases blood concentrations of CYP3A4 substrates by the enhancement of oral bioavailability. The effects of GFJ on two benzodiazepine hypnotics, triazolam (metabolized by CYP3A4) and quazepam (metabolized by CYP3A4 and CYP2C9), were determined in this study. Methods: The study consisted of four separate trials in which nine healthy subjects were administered 0.25 mg triazolam or 15 mg quazepam, with or without GFJ. Each trial was performed using an open, randomized, cross-over design with an interval of more than 2 weeks between trials. Blood samples were obtained during the 24-h period immediately following the administration of each dose. Pharmacodynamic effects were determined by the digit symbol substitution test (DSST) and utilizing a visual analog scale. Results GFJ increased the plasma concentrations of both triazolam and quazepam and of the active metabolite of quazepam, 2-oxoquazepam. The area under the curve (AUC)(0–24) of triazolam significantly increased by 96% (p<0.05). The AUC(0–24) of quazepam (+38%) and 2-oxoquazepam (+28%) also increased; however, these increases were not significantly different from those of triazolam. GFJ deteriorated the performance of the subjects in the DSST after the triazolam dose (−11 digits at 2 h after the dose, p<0.05), but not after the quazepam dose. Triazolam and quazepam produced similar sedative-like effects, none of which were enhanced by GFJ. Conclusion These results suggest that the effects of GFJ on the pharmacodynamics of triazolam are greater than those on quazepam. These GFJ-related different effects are partly explained by the fact that triazolam is presystemically metabolized by CYP3A4, while quazepam is presystemically metabolized by CYP3A4 and CYP2C9.     

Excretion of loratadine in human breast milk

The excretion of loratadine, a new nonsedating antihistamine, into human breast milk was studied in six lactating nonpregnant volunteers. Each volunteer received one 40-mg loratadine capsule. Milk and blood were collected before and at specified times (to 48 hours) after dosing. Plasma and milk loratadine concentrations were determined by a specific radioimmunoassay, and those of an active but minor metabolite, descarboethoxyloratadine, by high performance liquid chromatography (HPLC). Breast milk concentration-time curves of both loratadine and descarboethoxyloratadine paralleled the plasma concentration-time curves. For loratadine, the plasma Cmax was 30.5 ng/mL at 1.0 hour after dosing and the milk Cmax was 29.2 ng/mL in the 0 to 2 hour collection interval. Through 48 hours, the loratadine milk-plasma AUC ratio was 1.2 and 4.2 micrograms of loratadine was excreted in breast milk, which was 0.010% of the administered dose. For descarboethoxyloratadine, the plasma Cmax was 18.6 ng/mL at 2.2 hours after dosing, whereas the milk Cmax was 16.0 ng/mL, which was in the 4 to 8-hour collection interval. Through 48 hours, the mean milk-plasma descarboethoxyloratadine AUC ratio was 0.8 and a mean of 6.0 micrograms of descarboethoxyloratadine (7.5 micrograms loratadine equivalents) were excreted in the breast milk, or 0.019% of the administered loratadine dose. Thus, a total of 11.7 micrograms loratadine equivalents or 0.029% of the administered dose were excreted as loratadine and its active metabolite. A 4-kg infant ingesting the loratadine and descarboethoxyloratadine excreted would receive a dose equivalent to 0.46% of the loratadine dose received by the mother on a mg/kg basis.(ABSTRACT TRUNCATED AT 250 WORDS)     

In vitro metabolism of quazepam in human liver and intestine and assessment of drug interactions

1. The study was carried out to identify and characterize kinetically the cytochrome P450 (CYP) enzymes responsible for the major metabolite formation of quazepam.

2. In in vitro studies using human liver and intestinal microsomes and cDNA-expressed human CYP and FMO isoenzymes, quazepam was rapidly metabolized mainly by CYP3A4 and to a minor extent by CYP2C9, CYP2C19 and FMO1 to 2-oxoquazepam (OQ), which was then further biotransformed to N-desalkyl-2-oxoquazepam (DOQ) and to 3-hydroxy-2-oxoquazepam (HOQ) mainly by CYP3A4 and CYP2C9. CYP3A4 is the enzyme predominantly responsible for all the metabolic pathways of quazepam.

3. Itraconazole inhibited the formation of OQ from quazepam, HOQ from OQ and DOQ from OQ in human liver microsomes with K_i values of 8.40, 0.08 and 0.39?μM, respectively. However, the K_i for OQ formation was greater than the peak plasma itraconazole concentration following a clinically relevant 200-mg oral dose to healthy volunteers. In addition, CYP2C9 and CYP2C19 inhibitors failed to inhibit OQ formation from quazepam.

4. In conclusion, clinically relevant drug interaction with CYP inhibitors seem unlikely for the major metabolic pathway of quazepam to OQ.     

Drug interaction between St John's Wort and quazepam

AIM: St John's Wort (SJW) enhances CYP3A4 activity and decreases blood concentrations of CYP3A4 substrates. In this study, the effects of SJW on a benzodiazepine hypnotic, quazepam, which is metabolized by CYP3A4, were examined. METHODS: Thirteen healthy subjects took a single dose of quazepam 15 mg after treatment with SJW (900 mg day(-1)) or placebo for 14 days. The study was performed in a randomized, placebo-controlled, cross-over design with an interval of 4 weeks between the two treatments. Blood samples were obtained during a 48 h period and urine was collected for 24 h after each dose of quazepam. Pharmacodynamic effects were determined using visual analogue scales (VAS) and the digit symbol substitution test (DSST) on days 13 and 14. RESULTS: SJW decreased the plasma quazepam concentration. The Cmax and AUC(0-48) of quazepam after SJW were significantly lower than those after placebo [Cmax; -8.7 ng ml(-1) (95% confidence interval (CI) -17.1 to -0.2), AUC0-48; -55 ng h ml(-1) (95% CI -96 to -15)]. The urinary ratio of 6beta-hydroxycortisol to cortisol, which reflects CYP3A4 activity, also increased after dosing with SJW (ratio; 2.1 (95%CI 0.85-3.4)). Quazepam, but not SJW, produced sedative-like effects in the VAS test (drowsiness; P < 0.01, mental slowness; P < 0.01, calmness; P < 0.05, discontentment; P < 0.01). On the other hand, SJW, but not quazepam impaired psychomotor performance in the DSST test. SJW did not influence the pharmacodynamic profile of quazepam. CONCLUSIONS: These results suggest that SJW decreases plasma quazepam concentrations, probably by enhancing CYP3A4 activity, but does not influence the pharmacodynamic effects of the drug.     

The disposition and metabolism of a hypnotic benzodiazepine, quazepam, in the hamster and mouse

The disposition of 14C-quazepam (7-chloro-(2,2,2-trifluoroethyl) [5-14C]-5-o-fluorophenyl-1,3-dihydro-2H-1,4-benzodiazepin-2-thione), a new benzodiazepine hypnotic, was studied in hamsters and mice after iv and po dosing. In both species, quazepam was rapidly absorbed, as indicated by the plasma Cmax being reached within 1 hr of an oral dose (5 mg/kg). Also, radioactivity is essentially completely absorbed in both species, since the percentage of dose excreted in the urine was not dependent on the route of drug administration. Radioactivity was widely distributed in the tissues of both species; however, it was concentrated (relative to plasma) only in the liver and kidneys. In hamsters, 66-77% of the radioactivity was excreted within 48 hr, and 97% within 7 days of dosing (57% found in urine and 40% in feces after iv; 54% in urine and 43% in feces after po dosing). In mice, 86-88% of the radioactivity was excreted within 24 hr, and 98% within 4 days of dosing (43% in urine and 56% in feces after iv, 37% in urine and 61% in feces after po dosing). In both species, plasma levels of quazepam, measured by GLC, accounted for a very small percentage of plasma radioactivity and the elimination half-life was short (2.4 hr in hamster and 1.2 hr in mice), indicating extensive first pass metabolism for this drug. TLC analysis of plasma and urine extracts from both species showed biotransformation of quazepam involved substitution of oxygen for sulfur, followed by: (a) N-dealkylation, 3-hydroxylation, and conjugation or (b) 3-hydroxylation and conjugation.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effects of foods on the pharmacokinetics and clinical efficacy of quazepam.

The effects of foods on the pharmacokinetics and clinical efficacy of quazepam, a benzodiazepine derivative, in healthy persons were examined. Six healthy Japanese male subjects were randomly divided into three groups and each subject was treated with quazepam under the following three conditions by the crossover method. For the fasting state, subjects were administered 15 mg quazepam 11 hours after a meal. For the postprandial state, subjects were administered 15 mg or 30 mg quazepam 2 hours after a meal. Mean peak plasma concentration (Cmax) of quazepam was significantly higher [1.6-2.8 fold] with administration 2 hours after a meal than 11 hours after a meal. However, in regard to 15 mg of quazepam administration, the area under the curve (AUC) did not differ between administration 2 hours after a meal and 11 hours after a meal. In addition, differences were observed neither in other pharmacokinetic parameters or blood metabolite concentration under all of the study conditions, nor in clinical evaluation of subjective symptoms, complete blood count, or biochemical analyses between administrations 2 and 11 hrs after a meal. The present study showed that administration 2 hours after a meal did not affect subjective symptoms or physical functions so much; therefore it suggested favorable tolerance of this drug. However, it was also suggested that, in actual clinical use, it is important to evaluate the physical function including measurements of vital signs and hematological test results, carefully considering the effects of foods and daily life-style.     

Comparison of the effects of quazepam and triazolam on cognitive-neuromotor performance

The pharmacological activity of quazepam, a BZ₁ specific benzodiazepine, was compared to the effects of triazolam, a BZ₁, BZ₂ nonspecific benzodiazepine. Using a double-blind procedure, single oral doses of quazepam (15 or 30 mg), triazolam (0.5 or 1.0 mg) and placebo were administered to 21 healthy young men according to a random Latin square design balanced for order of drug administration. The drug effects on the performance of motor coordination and cognitive tasks were monitored for 7 h following drug ingestion. The results did not indicate any differential effects on cognitive-neuromotor performance for the BZ₁ specific quazepam and 2-oxoquazepam compared with the BZ₁, BZ₂ nonspecific N-desalkylflurazepam metabolite. The impairment magnitude for 30 mg quazepam was closer to that of 0.5 mg triazolam. The onset of the initial drug effect was considerably slower for quazepam than for triazolam. The time course of the impairment profiles for the tasks was compared to pharmacokinetic data from previous studies and suggested that published pharmacokinetic rate constants explain only a limited portion of the impairment time course. In particular, the performance scores were already showing recovery from peak impairment 2 h post-drug ingestion, although quazepam's potent N-desalkylflurazepam metabolite has been found to maintain a maximum plateau level from 2 to 24 h.     

Studies on the pharmacokinetics of BMY-28100 (II)

Studies were done in rats on placental transfer and excretion into milk of 14C-BMY-28100 upon single oral administration. Studies on absorption, distribution and excretion of 14C-BMY-28100 were also done upon multiple dosing. 1. Fetal tissue concentration of the drug reached a maximum at 6 hours after dosing on day 18 of gestation. The highest concentration observed was only 0.56 microgram equiv./g in fetal kidney; The transfer of radioactivity into the fetus was low. Similar results were obtained from whole body autoradiograms performed in rats on day 12 and day 18 of gestation. 2. Concentrations of radioactivity in milk reached a maximum of 0.60 microgram equiv./ml at 1 hour after administration, and gradually decreased thereafter. The maximum concentration in milk was 10% of the plasma concentration measured at the same time. 3. In the multiple oral administration study, 24 hours blood levels of radioactivity rose progressively with each dose, and reached a level 3.8 times higher than that observed with single dosing by the final (21st) administration. Tissue concentrations were relatively high in aorta, kidney and large intestine as were found upon single administration. However, the ratios of these levels between multiple and single dosing were lower than those observed in blood; 1.7, 3.6 and 2.9 for aorta, kidney and large intestine, respectively. Urinary and fecal excretion were constant after the 2nd administration.     

Effect of milk thistle on the pharmacokinetics of indinavir in healthy volunteers

STUDY OBJECTIVE: To characterize the pharmacokinetics of indinavir in the presence and absence of milk thistle and to determine the offset of any effect of milk thistle on indinavir disposition. DESIGN: Prospective open-label drug interaction study. SETTING: Outpatient clinic. SUBJECTS: Ten healthy volunteers. Intervention. Blood samples were collected over 8 hours after the volunteers took four doses of indinavir 800 mg every 8 hours on an empty stomach for baseline pharmacokinetics. This dosing and sampling were repeated after the subjects took milk thistle 175 mg (confirmed to contain silymarin 153 mg, the active ingredient) 3 times/day for 3 weeks. After an 11-day washout, indinavir dosing and blood sampling were repeated to evaluate the offset of any potential interaction. MEASUREMENTS AND MAIN RESULTS: Indinavir concentrations were measured by using a validated high-performance liquid chromatography method. The following pharmacokinetic parameters were determined: highest concentration (Cmax), hour-0 concentration, hour-8 concentration (C8), time to reach Cmax, and area under the plasma concentration-time curve over the 8-hour dosing interval (AUC8). Milk thistle did not alter significantly the overall exposure of indinavir, as evidenced by a 9% reduction in the indinavir AUC8 after 3 weeks of dosing with milk thistle, although the least squares mean trough level (C8) was significantly decreased by 25%. CONCLUSION: Milk thistle in commonly administered dosages should not interfere with indinavir therapy in patients infected with the human immunodeficiency virus.     

The sedative-hypnotic properties of quazepam, a new hypnotic agent

7-Chloro-1-(2,2,2-trifluoroethyl)-5-(o-fluorophenyl)-1,3-dihydro-2H-1, 4-benzodiazepine-2-thione (Sch 16134, quazepam) is a new hypnotic drug with demonstrated clinical efficacy. Quazepam has been shown in our laboratories to have potent hypnotic activity and fewer side effects at effective doses than flurazepam, which was studied concurrently. Hypnotic potency was estimated in mice via antagonism of electroshock-induced convulsions (ECS), potentiation of hexobarbital-induced sleeping time, and chlorprothixene potentiation. The respective oral ED50's (95% fiducial limits) in the 3 tests were 0.9 (0.4-2.0), 0.5 (0.3-0.8) and 0.05 (0.02-0.08) mg/kg for quazepam and 1.6 (1.1-2.3), 0.6 (0.4-1.0) and 0.11 (0.07-0.42) mg/kg for flurazepam. The duration of action of quazepam as measured by antagonism of ECS in mice was similar to that of flurazepam at equi-effective doses but quazepam had a faster onset. When potential tolerance to hypnotic efficacy was studied, quazepam did not show tolerance after dosing 20 mg/kg p.o. twice daily (b.i.d.) for 5 days, whereas tolerance was seen with flurazepam at equi-effective doses b.i.d. for 5 days. In conscious, unrestrained squirrel monkeys and cats, quazepam produced sedation with less ataxia and less evidence of CNS stimulant action than flurazepam. On the basis of the aforementioned studies, quazepam should be an effective hypnotic with less potential for ataxia, paradoxical excitation, and tolerance than flurazepam.