Induction of hepatic CYP3A4 expression by cholesterol and cholic acid: Alterations of gene expression, microsomal activity, and pharmacokinetics

Human cytochrome P450 3A4 (CYP3A4) is a drug-metabolizing enzyme that is abundantly expressed in the liver and intestine. It is an important issue whether compounds of interest affect the expression of CYP3A4 because more than 30% of commercially available drugs are metabolized by CYP3A4. In this study, we examined the effects of cholesterol and cholic acid on the expression level and activity of CYP3A4 in hCYP3A mice that have a human CYP3A gene cluster and show human-like regulation of the coding genes. A normal diet (ND, CE-2), CE-2 with 1% cholesterol and 0.5% cholic acid (HCD) or CE-2 with 0.5% cholic acid was given to the mice. The plasma concentrations of cholesterol, cholic acid and its metabolites in HCD mice were higher than those in ND mice. In this condition, the expression levels of hepatic CYP3A4 and the hydroxylation activities of triazolam, a typical CYP3A4 substrate, in liver microsomes of HCD mice were higher than those in liver microsomes of ND mice. Furthermore, plasma concentrations of triazolam in HCD mice were lower than those in ND mice. In conclusion, our study suggested that hepatic CYP3A4 expression and activity are influenced by the combination of cholesterol and cholic acid in vivo.

Kinetic analysis of sequential metabolism of triazolam and its extrapolation to humans using an entero-hepatic two-organ microphysiological system

The microphysiological system (MPS) is a promising tool for predicting drug disposition in humans, although limited information is available on the quantitative assessment of sequential drug metabolism in MPS and its extrapolation to humans. In the present study, we first constructed a mechanism-based pharmacokinetic model for triazolam (TRZ) and its metabolites in the entero-hepatic two-organ MPS, composed of intestinal Caco-2 and hepatic HepaRG cells, and attempted to extrapolate the kinetic information obtained with the MPS to the plasma concentration profiles in humans. In the two-organ MPS and HepaRG single culture systems, TRZ was found to be metabolized into α- and 4-hydroxytriazolam and their respective glucuronides. All these metabolites were almost completely reduced in the presence of a CYP3A inhibitor, itraconazole, confirming sequential phase I and II metabolism. Both pharmacokinetic model-dependent and -independent analyses were performed, providing consistent results regarding the metabolic activity of TRZ: clearance of glucuronidation metabolites in the two-organ MPS was higher than that in the single culture system. The plasma concentration profile of TRZ and its two hydroxy metabolites in humans was quantitatively simulated based on the pharmacokinetic model, by incorporating several scaling factors representing quantitative gaps between the MPS and humans. Thus, the present study provided the first quantitative extrapolation of sequential drug metabolism in humans by combining MPS and pharmacokinetic modeling.

Residual effects of zolpidem, triazolam, rilmazafone and placebo in healthy elderly subjects: a randomized double-blind study

With current hypnotic agents, next-day residual effects are a common problem. The purpose of the present study was to evaluate the residual effects of the commercially available hypnotics - zolpidem, triazolam, and rilmazafone - on the physical and cognitive functions of healthy elderly people in the early morning and the day following drug administration. In this study, the next-day residual effects of zolpidem, triazolam, and rilmazafone, following bedtime dosing in elderly subjects, were evaluated. Women (n = 11) and men (n = 2) aged 60-70 years received a single dose (at 23:00) of one of these, zolpidem 5 mg, triazolam 0.125 mg, rilmazafone 1 mg and placebo in a randomized, double-blind, crossover design. Measures of objective parameters and psychomotor performances (Timed up and Go test, Functional Reach Test, body sway test, critical flicker fusion test, simple discrimination reaction test, short-term memory test) and subjective ratings were obtained at 04:00, 07:00, and the next time of the day. All hypnotics were generally well tolerated; there were no serious adverse side effects and no subjects discontinued the evaluations. Compared to placebo, zolpidem and rilmazafone had good results on the Functional Reach Test. Although subjective assessments tended to be poor in the early morning, rilmazafone significantly improved the body sway test in the other hypnotics. A single dose of zolpidem 5 mg and triazolam 0.125 mg did not have any next-day residual effects on healthy elderly subjects. Residual effects appeared to be related to the compound's half-life and the dose used. Rilmazafone 1 mg exhibited steadiness in static and dynamic balance and seemed to be more favorable for the elderly with early morning awakening.

Impact of end-product inhibition on the determination ofin vitrometabolic clearance

End-product inhibition was explored as a mechanism for the lower clearance determination obtained from microsomes compared with hepatocytes. Triazolam, diazepam and phenytoin microsomal substrate depletion was reduced by 23, 34 and 39%, respectively, when incubated with their primary metabolites. Ki values of 28+/-6 and 11+/-1 microM were obtained when 4'-hydroxydiazepam and p-hydroxyphenytoin where incubated with diazepam and phenytoin, respectively. Alamethicin (a glucuronidation activator) was unsuccessful in alleviating these effects. IC50 values of 17, 32 and 18 microM for phenytoin and 83, 110 and 97 microM for diazepam were observed with salicylamide- (a glucuronidation inhibitor) treated hepatocytes, control hepatocytes and microsomes, respectively, when incubated with their primary metabolites. These differences suggest that metabolite concentrations in the vicinity of the enzyme are lower in hepatocytes compared with microsomes, reducing the likelihood of end-product inhibition in the former system. In conclusion, end-product inhibition may be more prominent in microsomes (in particular for substrate depletion assays where metabolism tends to be more extensive); results suggest that this phenomenon may contribute to the observed variations in metabolism characteristics and intrinsic clearance (CLint) between hepatocytes and microsomes.

Quantitative relationship between rifampicin exposure and induction of Cyp3a11 in SXR humanized mice: extrapolation to human CYP3A4 induction potential

The SXR humanized mouse model was used to quantitatively assess an in vivo induction response of the human PXR agonist, rifampicin. Three days of rifampicin treatment increased RNA expression and microsomal enzyme activity of CYP3A11, as well as significantly reduced triazolam plasma exposure. These results indicate that the humanized SXR mouse can be used as a model to predict human CYP3A4 induction and the resulting pharmacokinetic changes of CYP3A4 substrates in humans.

Maximum cumulative doses of sedation medications for in-office use

The AGD acknowledges that dentists may need an additional permit to perform the procedure described in this article. Many states require dental practitioners to have additional or advanced training in order to perform enteral sedation. In some states, practitioners must have an i.v./conscious sedation permit before they are allowed to titrate (dose) oral medication. The ADA does not believe that oral medication can be titrated (dosed) without an i.v. sedation license. The AGD has adopted and published a white paper on sedation issues, which appeared in the September-October 2006 issue of General Dentistry. The AGD encourages continuing education in sedation modalities for general dentists. Oral conscious sedation (OCS) is an increasingly common practice in dentistry and is at the forefront of evolving state regulations. At the center of the OCS controversy is the oral titration of medications. Most medications available for OCS are used in an "off-label" manner and have no determined maximum recommended dosage for that purpose. This article proposes cumulative maximum dosing guidelines for in-office OCS, with an emphasis on triazolam.

Theoretical calculation of triazolam hydroxylation and endogenous steroid inhibition in the active site of CYP3A4

CYP3A4 has unusual kinetic characteristics because it has a large active site. CYP3A4 produced more 4-hydroxytriazolam than alpha-hydroxytriazolam at concentrations of more than 60 muM triazolam, and different steroids had different inhibitory effects on the system. To clarify these interesting observations, the interactions between substrate and substrate/steroid were investigated by theoretical calculations. When two triazolam molecules were docked into the active site, the distance between the O-atom and the 4-hydroxylated site was less than the distance to the alpha-hydroxylated site because of interaction between the two triazolam molecules. Estradiol inhibited both alpha- and 4-hydroxytriazolam formation by 50%. Dehydroepiandrosterone (DHEA) inhibited alpha-hydroxylation more than 4-hydroxytriazolam formation, whereas aldosterone had no effect. When one triazolam molecule and one steroid molecule were simultaneously docked, estradiol increased the distance between the O-atom and the two hydroxylated sites, DHEA only increased the distance between the O-atom and alpha-hydroxylated site, and aldosterone did not change the distances. The relevant angles of Fe-O-C in the hydroxylated site of triazolam also widened, together with increased distance. These findings indicate that formation of a substrate and substrate/effector complex in the active site may be a factor for determining the enzyme kinetic parameters of CYP3A4.

Balancing efficacy and safety in the use of oral sedation in dental outpatients

BACKGROUND

Concerns about the safety of pediatric oral sedation and the incremental use of triazolam in adults prompted a workshop cosponsored by several professional organizations.

OVERVIEW

There is a strong need and demand for adult and pediatric sedation services. Using oral medication to achieve anxiolysis in adults appears to have a wide margin of safety. Mortality and serious morbidity, however, have been reported with oral conscious sedation, especially in young children. Most serious adverse events are related to potentially avoidable respiratory complications.

CONCLUSIONS

Clinical trials are needed to evaluate oral sedative drugs and combinations, as well as to develop discharge criteria with objective quantifiable measures of home readiness. Courses devoted to airway management should be developed for dentists who provide conscious sedation services. State regulation of enteral administration of sedatives to achieve conscious sedation is needed to ensure safety.

PRACTICE IMPLICATIONS

Safety in outpatient sedation is of paramount concern, with enteral administration of benzodiazepines appearing safe but poorly documented in the office setting. Conscious sedation by the enteral route, including incremental triazolam, necessitates careful patient evaluation, monitoring, documentation, facilities, equipment and personnel as described in American Dental Association and American Academy of Pediatric Dentistry guidelines.

Pharmacokinetics and clinical effects of multidose sublingual triazolam in healthy volunteers

Triazolam is increasing in popularity as a premedication prescribed by dentists to help their fearful and anxious patients tolerate the potentially aversive nature of some dental procedures. Recent anecdotal reports suggest that incremental sublingual dosing of triazolam may be an effective technique for producing conscious sedation in the dental setting. Although promising, no laboratory or clinical data have been available to evaluate the efficacy or safety of this approach. This study was designed to determine the pharmacokinetics and sedative effects of incremental sublingual dosing of triazolam (total, 1.0 mg) in healthy adults. Ten healthy adult volunteers received sublingual triazolam (0.25 mg) followed by additional doses after 60 (0.50 mg) and 90 (0.25 mg) minutes. Plasma triazolam concentrations, clinical effects (Observer's Assessment of Alertness/Sedation score), and processed electroencephalogram (bispectral index score) were measured intermittently for 3 hours. Plasma triazolam concentrations (mean +/- SD, 5.1 +/- 1.1 ng/mL) and drug effects (Observer's Assessment of Alertness/Sedation score, 2 +/- 1; and the bispectral index score, 62 +/- 16) were greatest in all subjects at the end of the 3-hour evaluation period. Eight of the subjects had Observer's Assessment of Alertness/Sedation scores consistent with the definition of deep sedation or general anesthesia (Observer's Assessment of Alertness/Sedation score, <3) at some of the later time points in the 180 minutes of data collection. In comparison, 4 of the subjects had bispectral index scores less than 60 during these later time points of data collection. Given the considerable intersubject variability in triazolam concentrations and effects, additional research is needed to assess this multidosing strategy before it can be endorsed as a useful and safe sedation technique for managing fearful and anxious patients in dental practice.

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.

Pharmocokinetics and pharmacodynamics of single-dose triazolam: electroencephalography compared with the Digit-Symbol Substitution Test

AIMS

To investigate whether the electroencephalogram (EEG) directly reflects the CNS effects of benzodiazepines by evaluating the relation of the EEG to plasma drug concentrations and to Digit-Symbol Substitution Test (DSST) scores after a single dose of triazolam, a representative benzodiazepine agonist.

METHODS

Thirteen healthy male subjects were given 0.375 mg triazolam or placebo in a double-blind crossover study. Plasma samples were collected during 8 h after dosage. Pharmacodynamic effects were measured by DSST and EEG at corresponding times.

RESULTS

Pharmacokinetic parameters for triazolam were consistent with established values. Compared with placebo, triazolam significantly impaired psychomotor performance on the DSST (P < 0.001) and increased beta amplitude on the EEG (P < 0.002). DSST and EEG changes both closely tracked changes in plasma concentrations over time. The changes for the two measures were highly correlated with each other (r =-0.94, P < 0.001) based on aggregate values at individual time points. However, the variations in area under the curve of pharmacodynamic effect vs. time (AUCeffect) measured by either method did not reflect the variations in plasma AUC across individuals. The individual variability in AUCeffect from the EEG was similar to that measured by the DSST.

CONCLUSIONS

Both the EEG and the DSST reflect the central benzodiazepine agonist effects of triazolam. Intrinsic variability in both measures is similar.

Urinary excretion of alpha-hydroxytriazolam following a single dose of halcion

As an approved medicinal product and reportedly an abused substance that have been associated with death and "considered to be a factor...of impaired driving, sexual assault, and other violent crimes", triazolam is controlled at the same level (Level III) as flunitrazepam in Taiwan. Alleged misuses of this substance have been associated with case specimens submitted to this laboratory. A sample preparation (with and without enzymatic hydrolysis) and gas chromatography-mass spectrometry protocols were evaluated and applied to the analysis of free and total alpha-hydroxytriazolam (the main metabolite of triazolam) in urine. Ions designated for TMS-derivatized alpha-hydroxytriazolam and alpha-hydroxytriazolam-d4 are m/z 415, 417, and 430 and 419, 421, and 434, respectively. The overall protocol achieved the following results when applied to the analysis of 2-mL drug-free urine specimens fortified with 10-200 ng/mL alpha-hydroxytriazolam: recovery, 95%; interday and intraday precision ranges, 1.50-3.52% and 0.93-4.71%, respectively; linearity, r2 > 0.99; and limits of detection and quantitation, 0.05 and 0.1 ng/mL, respectively. This protocol was applied to the analysis of case specimens and urine samples collected from two patients (A and B) taking one oral dose of Halcion (0.25 mg triazolam). Excretion profiles of free and total alpha-hydroxytriazolam show that free alpha-hydroxytriazolam is detectable, but at very low levels (< 5 ng/mL). Peak excretion of total alpha-hydroxytriazolam occurs at approximately 5-10 h following the drug intake. Total alpha-hydroxytriazolam is excreted at detectable levels approximately 2-35 h following an oral dose of 0.25 mg triazolam. Total free and conjugated alpha-hydroxytriazolam excreted by A and B are 0.61% and 31.6%; and 0.36% and 57.2% of the dose, respectively.

Electroencephalographic properties of zaleplon, a non-benzodiazepine sedative/hypnotic, in rats

The encephalographic (EEG) properties of zaleplon were investigated in comparison with those of other sedative hypnotics in conscious rats with chronically implanted electrodes. The oral administration of zaleplon (0.25-1.0 mg/kg), triazolam (0.0625-0.25 mg/kg), zopiclone (1.0-4.0 mg/kg), brotizolam (0.0625-0.25 mg/kg), and nitrazepam (0.125-0.5 mg/kg) lengthened the total sleep in a dose-dependent manner. On distribution of sleep-wakefulness stages, zaleplon, in particular, increased the slow wave deep sleep (SWDS), whereas triazolam, brotizolam, and nitrazepam increased the slow wave light sleep (SWLS) in a dose-dependent manner. Zopiclone significantly increased the SWDS at a dose of 2 mg/kg and both the SWLS and the SWDS at a dose of 4 mg/kg. All tested hypnotics caused no influence on fast wave sleep (FWS) at doses tested. The appearance of the sleep-inducing activity of zaleplon was more rapid than those of any compounds tested, and zaleplon significantly increased the relative EEG power density in the delta frequency band over that of triazolam at 20 and 30 min after the administration in the spectral analysis. Therefore, the present findings suggest that the non-benzodiazepine zaleplon can be expected to exhibit high practical potential as a hypnotic and is characterized by an increase in SWDS with rapid onset of hypnotic action.

Age and gender effects on the pharmacokinetics and pharmacodynamics of triazolam, a cytochrome P450 3A substrate

Sixty-one healthy men and women, aged 20 to 75 years, received single 0.25-mg doses of triazolam, a cytochrome P450 (CYP) 3A substrate benzodiazepine, and placebo in a double-blind crossover study. Among women, age had no significant effect on area under the triazolam plasma concentration curve (AUC) (Spearman r=0.14, P=.44) or clearance (r =-0.09, P=.62). Among men, AUC increased (r=0.43, P <.02) and clearance declined (r=-0.42, P <.02) with increasing age. Gender differences in triazolam kinetics were not apparent. Compared with placebo, triazolam impaired digit-symbol substitution test performance, increased observer-rated sedation, impaired delayed recall of information learned at 1.5 hours after dosing, and increased electroencephalographic beta amplitude. Among men, mean values of relative digit-symbol substitution test decrement (P <.002) and observer-rated sedation (P <.05) were significantly greater in elderly subjects compared with young subjects. Age-dependent differences among women reached significance for observer-rated sedation (P <.02). A combination of higher plasma levels and increased intrinsic sensitivity explained the greater pharmacodynamic effects of triazolam in elderly subjects. Although the findings are consistent with reduced clearance of triazolam in elderly men, individual variability was large and was not explained by identifiable demographic or environmental factors.

In vivo comparisons of constitutive cytochrome P450 3A activity assessed by alprazolam, triazolam, and midazolam

BACKGROUND

Previous studies have not demonstrated good correlations between various presumed phenotypic measures of in vivo cytochrome P450 (CYP) 3A activity. However, in reality, few have used appropriate and validated in vivo probes that consider the complexities of CYP3A. Accordingly, the disposition of 3 closely related benzodiazepines with extensive and similar CYP3A-mediated metabolism characteristics but different pharmacokinetics was investigated, and correlations between the drugs were examined.

METHODS

The single-dose oral clearances of alprazolam, midazolam, and triazolam and the systemic clearances of the latter 2 drugs were separately determined in 21 healthy subjects (10 men) according to a randomized experimental design with a minimum 1-week period between the individual studies. An erythromycin breath test was also performed.

RESULTS

After intravenous administration, systemic clearance varied 3-fold compared with a 6-fold range in clearance after an oral dose for all 3 drugs. However, mean values differed markedly between the drugs, with the systemic clearance of midazolam being almost double that of triazolam (383 +/- 73 mL/min versus 222 +/- 54 mL/min). Oral clearances were even more dissimilar: alprazolam, 75 +/- 36 mL/min; triazolam, 360 +/- 195 mL/min; and midazolam, 533 +/- 759 mL/min. Estimates of CYP3A-mediated extraction by the intestine and liver indicated approximately equal contributions by both organs but larger values for midazolam than for triazolam, and these differences accounted for the differences in oral bioavailability, 30% +/- 13% versus 55% +/- 20%, respectively. Statistically significant ( P = .001 to .004) correlations between the 3 drugs' oral clearances ranged from 0.60 to 0.68 ( r s value), whereas the correlation for the systemic clearances of midazolam and triazolam was 0.66 ( P = .001). No statistically significant relationships were observed between any of the clearance parameters and the erythromycin breath test.

CONCLUSION

Despite alprazolam, midazolam, and triazolam having markedly different pharmacokinetic characteristics, statistically significant correlations were present between the oral and systemic clearances of the 3 drugs, consistent with a major involvement of CYP3A in their metabolism and elimination. However, the magnitude of the coefficients of determination ( r s ) was such to suggest that an in vivo probe approach, even with the use of valid phenotypic trait values, will be unable to accurately and reliably predict the pharmacokinetic behavior of another CYP3A substrate, as determined by the enzyme's constitutive activity.

Postmortem changes in tissue concentrations of triazolam and diazepam in rats

The aim of this study was to investigate the postmortem changes of concentrations of triazolam and diazepam in the rat model and to confirm the factor causing the phenomenon. We administered triazolam or diazepam orally to rats and then sacrificed them 1 h after administration. Abdominal tissues including stomach content and small intestine, thigh muscle and heart blood were collected at 0, 12, 24 h after death, and postmortem changes of the two drug concentrations were compared. Drug concentrations in the samples were analyzed by a selected ion monitoring of gas chromatography/mass spectrometry. Gastrointestinal postmortem concentrations of triazolam and diazepam decreased. On the other hand, the drug concentrations in the liver and kidney increased markedly, and those in lung and heart blood increased slightly during postmortem periods by diffusion from the gastrointestinal tract. The patterns of both drug concentration changes were similar. However, the extent of the triazolam increase tended to be larger than that of diazepam. This difference may be accounted for by lower triazolam concentrations before death. The postmortem drug concentrations of thigh muscle did not change when administered with triazolam and diazepam. For both triazolam and diazepam, a significant correlation was observed in the drug concentration between the small intestine and the kidney at 24 h after death, indicating that major cause of the change in the drug concentration in the kidney was diffusion from the small intestine up to 24 h after death. The results in this study indicate that diazepam as well as triazolam diffuses from the gastrointestinal tract into the surrounding tissues after death and suggest that the diffusion is influenced by their pharmaceutical properties before death.

INTERACTION OF TRIAZOLAM AND KETOCONAZOLE IN P-GLYCOPROTEIN-DEFICIENT MICE

The role of P-glycoprotein (P-gp) on the distribution of the benzodiazepine triazolam (TRZ) and the azole antifungal agent ketoconazole (KET), and on the TRZ-KET interaction, was studied using mdr1a(-) or mdr1a/b(-/-) mice (P-gp-deficient mice) and matched controls. TRZ and KET also were studied in Caco-2 cells in Transwell culture. After single i.p. injections of TRZ or KET in separate groups of control mice, brain concentrations of TRZ exceeded those in serum [brain/serum area under the concentration curve (AUC) ratio, 5.0], whereas brain/serum AUC ratios for KET were approximately 0.5. On the basis of single time points, brain concentrations of TRZ, or brain/serum ratios, were similar in P-gp-deficient animals compared with controls, whereas P-gp-deficient animals had significantly higher KET brain concentrations and brain/serum ratios. Coadministration of KET with TRZ increased TRZ concentrations in serum, liver, and brain, both in controls and in P-gp-deficient animals, probably attributable to impairment by KET of CYP3A-mediated clearance of TRZ. However, KET did not increase brain/serum ratios of TRZ in either group. In Caco-2 cells, basal-to-apical flux of TRZ was higher than apical-to-basal flux. However, verapamil (100 microM) did not alter flux in either direction. KET inhibited basal-to-apical transport of rho-damine-123, with a 50% inhibitory concentration of 2.7 microM. Thus, TRZ does not appear to undergo measurable blood-brain barrier efflux transport by P-gp in this animal model. KET impairs clearance of TRZ but does not increase tissue uptake. However, KET itself may be a substrate for efflux transport at the blood-brain barrier.

Time course of recovery of cytochrome p450 3A function after single doses of grapefruit juice

BACKGROUND

Components of grapefruit juice may impair the activity of intestinal cytochrome P450 (CYP) 3A enzymes, sometimes resulting in clinically important drug interactions. The time course of recovery from CYP3A inhibition after a single exposure to grapefruit juice is not clearly established.

METHODS

Healthy volunteer subjects (N = 25) received a single 6-mg oral dose of the CYP3A substrate midazolam in the control condition without exposure to grapefruit juice. Two days later, midazolam was administered 2 hours after 300 mL of regular-strength grapefruit juice. Subjects were then randomly assigned to 3 different groups, receiving a third midazolam challenge at 26, 50, or 74 hours after exposure to grapefruit juice. The capacity of 6'7'-dihydroxybergamottin and bergamottin to inhibit human CYP3A was studied in vitro using human liver microsomes.

RESULTS

The area under the plasma concentration curve (AUC) for midazolam increased by a factor of 1.65 (ratio compared with control) when midazolam was given 2 hours after grapefruit juice. At 26, 50, and 74 hours after grapefruit juice, the AUC ratios (mean AUC value at the indicated time divided by the mean control AUC on day 1) were 1.29, 1.29, and 1.06, respectively. The relationship of time after grapefruit juice exposure versus AUC increase over control indicated a recovery half-life estimated at 23 hours. The midazolam elimination half-life did not change significantly from the control value at any time after grapefruit juice exposure. 6'7'-Dihydroxybergamottin inhibited midazolam alpha-hydroxylation in vitro, with a mean 50% inhibitory concentration of 4.7 micro mol/L; preincubation of microsomes with 6'7'-dihydroxybergamottin greatly reduced the 50% inhibitory concentration to 0.31 micro mol/L, consistent with mechanism-based inhibition. Bergamottin itself had much weaker inhibitory potency compared to 6'7'-dihydroxybergamottin.

CONCLUSIONS

A usual single exposure to grapefruit juice appears to impair the enteric, but not the hepatic, component of presystemic extraction of oral midazolam. Recovery is largely complete within 3 days, consistent with enzyme regeneration after mechanism-based inhibition. 6'7'-Dihydroxybergamottin was verified as a potent mechanism-based inhibitor of midazolam alpha-hydroxylation by CYP3A in vitro.

Disposition of triazolam in the rat by brain microdialysis and semi-micro column high-performance liquid chromatography with UV absorbance detection

A semi-micro column high-performance liquid chromatography with ultraviolet detection for the determination of triazolam is described. The method was applied to determine plasma and brain microdialysate concentrations of triazolam after single intravenous bolus of 2.5 mg/kg to rat. The separation was achieved on a 250 x 1.5 mm i.d. C(18) column and the column effluent was monitored at 222 nm. The detection limits at a signal-to-noise ratio of 3 obtained using spiked plasma and artificial cerebrospinal fluid were 2.1 and 0.7 ng/mL, respectively. The intra- and inter-day reproducibility of the present method were satisfactory with the highest relative standard deviation of 9.1 (n > or = 5). The present method was successfully applied to study the disposition of triazolam in rat (n = 5) by analyzing plasma and brain microdialysate samples.

Distribution of triazolam and alpha-hydroxytriazolam in a fatal intoxication case

The case of a 77-year-old woman who was found dead in her bathtub with her head clearly above the water line is presented. The decedent had a medical history of depression, liver disease, spinal stenosis, and diabetes mellitus. An empty medication bottle of triazolam was found in the trashcan. At autopsy, no injury or evidence of drowning was found. Toxicological analysis identified triazolam at a concentration of 0.12 mg/L in the heart blood. Triazolam and alpha-hydroxytriazolam were quantitated in the specimens received. The medical examiner ruled that the cause of death was triazolam intoxication and the manner of death was suicide.

Effect of modafinil on the pharmacokinetics of ethinyl estradiol and triazolam in healthy volunteers

BACKGROUND

Modafinil has been reported to produce a concentration-related induction of CYP3A4/5 activity in vitro in primary cultures of human hepatocytes.

OBJECTIVE

Our objective was to determine whether the pharmacokinetics of steady-state ethinyl estradiol (INN, ethinylestradiol) and single-dose triazolam were altered after 4 weeks of modafinil treatment in volunteers.

METHODS

This was a placebo-controlled, single-blind, single-period study in 41 female subjects who were receiving long-term treatment with an oral contraceptive that contained ethinyl estradiol (0.035 mg) and norgestimate (0.180-0.250 mg). Pharmacokinetic profiles for ethinyl estradiol and for a single oral dose of triazolam (0.125 mg) were obtained the day before initiation of treatment with modafinil (200 mg for 7 days, followed by 400 mg for 21 days) or placebo (28 days). A second dose of triazolam was administered with the final dose of modafinil, and pharmacokinetic profiling was repeated.

RESULTS

The modafinil treatment group had a marked decrease in maximum observed plasma concentrations and areas under the plasma concentration-time curve for triazolam relative to placebo, with a much smaller decrease in these parameters for ethinyl estradiol. The half-life of triazolam was also decreased, but the half-life of ethinyl estradiol did not appear to be affected by treatment with modafinil.

CONCLUSION

Modafinil induced CYP3A4/5 activity in humans in vivo, suggesting that there is potential for metabolic drug-drug interactions between modafinil and substrates of CYP3A4/5. However, the induction appeared to be more gastrointestinal than hepatic in nature. Therefore significant metabolic drug-drug interactions are most likely to occur with compounds (such as triazolam) that undergo significant gastrointestinal CYP3A4/5-mediated first-pass metabolism.

Effect of methylprednisolone on CYP3A4-mediated drug metabolism in vivo

OBJECTIVE

To study the effects of methylprednisolone on the pharmacokinetics and pharmacodynamics of triazolam.

METHODS

In this three-phase cross-over study, ten healthy subjects received 0.25 mg oral triazolam on three occasions: on day 1 (no pretreatment, control), on day 8 (1 h after a single dose of 32 mg oral methylprednisolone) and on day 18 (after further treatment with 8 mg oral methylprednisolone daily for 9 days). The plasma concentrations of triazolam were determined up to 10 h, and its effects were measured using four psychomotor tests up to 6 h.

RESULTS

The single dose of methylprednisolone showed no significant effects on the pharmacokinetics of triazolam. However, the Digit Symbol Substitution Test result was better (P < 0.05) during the single-dose methylprednisolone phase than during the control phase, the other three tests showing no differences between the phases. The multiple-dose treatment with methylprednisolone reduced the mean peak plasma concentration (Cmax) of triazolam by 30% (P < 0.05) but had no significant effects on the time to Cmax (tmax), elimination half-life (t 1/2), area under the plasma concentration-time curve from 0 h to 10 h (AUC(0-10 h)) and AUC(0-infinity) and did not alter the effects of triazolam.

CONCLUSION

A single, relatively high dose of methylprednisolone (32 mg) did not affect cytochrome P450 (CYP)3A4 activity, and treatment with 8 mg methylprednisolone daily for 9 days did not result in clinically significant induction of CYP3A4.

Effect of ranitidine on the pharmacokinetics of triazolam and alpha-hydroxytriazolam in both young (19-60 years) and older (61-78 years) people

OBJECTIVE

This study evaluated the effect of oral ranitidine (75 mg and 150 mg) on the pharmacokinetics of triazolam (0.25 mg) and its major metabolite, alpha-hydroxytriazolam, in both young and older people. Metabolite data were used to distinguish the mechanism of this interaction.

METHOD

This was a randomized, open-label, 3-way crossover study. Eighteen young (19-60 years) and 12 older (61-78 years) men and women were randomly assigned to receive evening doses of triazolam 0.25 mg (1) alone, (2) on the third day of dosing ranitidine 75 mg twice daily for 4 days, and (3) on the third day of dosing ranitidine 150 mg twice daily for 4 days.

RESULTS

In the young group, mean triazolam area under the concentration-time curve from time zero to infinity [AUC(0-infinity)] was 10% and 28% higher after treatment with 75 mg and 150 mg ranitidine, respectively. In the older group, mean triazolam AUC(0-infinity) was 31% and 28% higher after treatment with 75 mg and 150 mg ranitidine, respectively. There was no change in the alpha-hydroxytriazolam/triazolam AUC(0-infinity) ratio in either age group, indicating that neither formation nor elimination of alpha-hydroxytriazolam was affected by ranitidine. There were no changes in the half-life of triazolam or alpha-hydroxytriazolam.

CONCLUSION

Ranitidine increases oral absorption of triazolam in both young and older people. This effect is likely caused by elevation of gastrointestinal pH, allowing for greater absorption of acid-labile triazolam. The difference in this effect between age groups at the lower 75-mg dose of ranitidine suggests that older people may be more sensitive to the antisecretory effect of ranitidine.

Pharmacokinetics and clinical effects of sublingual triazolam in pediatric dental patients

The purpose of this investigation was to describe the pharmacokinetics of sublingual triazolam in children. Nine healthy children (64-98 months old) received 0.25 or 0.375 mg of sublingual triazolam before dental treatment. Plasma triazolam concentrations were measured by gas chromatography/mass spectrometry and analyzed by noncompartmental methods. The peak concentration was 4.9 +/- 2.0 ng/mL (mean +/- SD), time to peak was 75 +/- 32 minutes, the elimination half-life was 91 +/- 32 minutes, and apparent clearance was 17.6 +/- 8.8 mL x kg(-1) x min(-1). Children were tested for gait ataxia, amnesia, and diplopia during a screening session and again after triazolam. Ninety minutes after drug administration, seven of nine children demonstrated ataxia, and three of nine demonstrated amnesia. Peak triazolam concentrations were similar in children with or without ataxia, but they were significantly higher in children with amnesia compared with those without amnesia. Six children demonstrated diplopia 30 and 120 minutes after triazolam; however, peak triazolam concentrations were similar in both groups. Sublingual administration was an acceptable alternative route of triazolam delivery in children.

CYP3A inductive potential of the rifamycins, rifabutin and rifampin, in the rabbit

Rifabutin is effective in the treatment and prevention of Mycobacterium avium infection in people with HIV infection. Rifabutin is structurally related to another rifamycin, rifampin, a well-known inducer of the human P-450 isoform 3A. The rabbit isoform CYP3A6 and the human isoform CYP3A4 have similar P-450 predominance and substrate specificity and are both induced by rifampin. Our goal was to predict the CYP3A induction capacity of rifabutin and to determine if ex vivo CYP3A induction potential of rifamycins is predictive of that obtained in vivo. We determined the in vivo and ex vivo CYP3A6 induction by 4 days of treatment with rifabutin (100 mg/kg), rifampin (100 mg/kg), or vehicle (DMSO) in the rabbit. The ex vivo measures were CYP3A6 activity (N-demethylation of erythromycin and hydroxylation of triazolam) and CYP3A content in rabbit hepatic microsomes preparations. The in vivo measures were oral clearance of triazolam and its formation clearance to its hydroxylated metabolites, alpha-hydroxytriazolam and 4-hydroxytriazolam. Rifampin increased CYP3A6 activity by 2- to 3-fold in hepatic microsomes compared to vehicle. Rifabutin increased CYP3A content 1.7-fold, but did not significantly increase microsomal CYP3A6 activity. Oral triazolam clearance and formation clearances to the two hydroxylated metabolites were 2- to 3-fold greater in rabbits treated with rifampin. These clearances were unaffected by rifabutin administration. Ex vivo enzyme activities correlated with in vivo changes in clearance of triazolam and the formation clearance to its hydroxylated metabolites. Rifabutin is a weaker inducer of CYP3A6 than rifampin. These data suggest that ex vivo enzyme activity is a viable approach to predict in vivo inductive potential of CYP3A inducers.

Triazolam substrate inhibition: evidence of competition for heme-bound reactive oxygen within the CYP3A4 active site

In human liver microsomes, triazolam is principally metabolized by CYP3A4 to form two metabolites, 1'-hydroxytriazolam (1'OHTz) and 4-hydroxytriazolam (4OHTz). The velocity of 1'OHTz formation was found to decrease at higher triazolam concentrations (>200 microM), indicative of "substrate inhibition". Coincubation of [(14)C]triazolam with authentic metabolite standards of either 1'OHTz or 4OHTz up to 30 microM did not significantly inhibit the rate of [(14)C]1'OHTz formation. The effects of secondary compounds on triazolam oxidation were shown to be product-specific, producing either activation or inhibition depending on the triazolam metabolite monitored. When human liver microsomes were supplemented with exogenous human cytochrome b(5), it was observed that substrate inhibition was attenuated and the resulting increase in 1'OHTz formation, relative to control (nonsupplemented) incubations, corresponded to a decrease in the ratio of 4OHTz to 1'OHTz. In contrast, when cofactor (e.g., 100 microM NADPH) was rate limiting, the metabolite ratio (4OHTz/1'OHTz) was markedly increased over the entire substrate concentration range (0.5-1000 microM). To explain these kinetic observations, a two-site binding model is proposed in which triazolam is hypothesized to bind within the CYP3A4 active site in spatially distinct orientations, which may lead to the formation of either the 1'-hydroxytriazolam or 4-hydroxytriazolam. Differential inhibition/activation is consistent with this two-site model and substrate inhibition is hypothesized to result from competition between the two sites for reactive oxygen.

Effect of grapefruit juice dose on grapefruit juice-triazolam interaction: repeated consumption prolongs triazolam half-life

OBJECTIVE

Grapefruit juice inhibits CYP3A4-mediated metabolism of several drugs during first pass. In this study, the effect of grapefruit juice dose on the extent of grapefruit juice-triazolam interaction was investigated.

METHODS

In a randomised, four-phase, crossover study, 12 healthy volunteers received 0.25 mg triazolam with water, with 200 ml normal-strength or double-strength grapefruit juice or, on the third day of multiple-dose [three times daily (t.i.d.)] administration of double-strength grapefruit juice. Timed blood samples were collected up to 23 h after dosing, and the effects of triazolam were measured with four psychomotor tests up to 10 h after dosing.

RESULTS

The area under the plasma triazolam concentration time curve (AUC(0-infinity)) was increased by 53% (P < 0.01), 49% (P < 0.01) and 143% (P < 0.001) by a single dose of normal-strength, a single dose of double-strength and multiple-dose administration of double-strength grapefruit juice, respectively. The peak plasma concentration (Cmax) of triazolam was increased by about 40% by a single dose of normal-strength grapefruit juice (P < 0.01) and multiple-dose grapefruit juice (P < 0.01) and by 25% by a single dose of double-strength grapefruit juice (P < 0.05). The elimination half-life (t(1/2)) of triazolam was prolonged by 54% during the multiple-dose grapefruit juice phase (P < 0.001). A significant increase in the pharmacodynamic effects of triazolam was seen during the multiple-dose grapefruit juice phase in the digit symbol substitution test (DSST, P < 0.05), in subjective overall drug effect (P < 0.05) and in subjective drowsiness (P < 0.05).

CONCLUSIONS

Even one glass of grapefruit juice increases plasma triazolam concentrations, but repeated consumption of grapefruit juice produces a significantly greater increase in triazolam concentrations than one glass of juice. The t(1/2) of triazolam is prolonged by repeated consumption of grapefruit juice, probably due to inhibition of hepatic CYP3A4 activity.

Lack of interaction between citalopram and the CYP3A4 substrate triazolam

STUDY OBJECTIVES

To determine the effect of the selective serotonin reuptake inhibitor citalopram on plasma levels of triazolam, and to determine the effect of a single dose of triazolam on steady-state levels of citalopram and its major metabolites.

DESIGN

Open-label, multidose study.

SETTING

Clinical Studies, Ltd., Fort Lauderdale, Florida.

PARTICIPANTS

Eighteen healthy male and female volunteers.

INTERVENTIONS

Subjects received triazolam 0.25 mg alone and another 0.25-mg dose after 4 weeks of citalopram 20 mg/day for 1 week, followed by 3 weeks of citalopram 40 mg/day

MEASUREMENTS AND MAIN RESULTS

Pharmacokinetic parameters were determined after single-dose administration of triazolam alone, after administration of citalopram alone at steady state, and after coadministration of the drugs. The pharmacokinetics of triazolam and its metabolite alpha-hydroxytriazolam were unchanged by citalopram coadministration. Triazolam appeared to be absorbed slightly more quickly during coadministration. Citalopram kinetics were unaffected by coadministration.

CONCLUSION

No pharmacokinetic interaction between the drugs was observed, suggesting that triazolam and other cytochrome P450 3A4 substrates can be coadministered safely with citalopram.

The influence of the menstrual cycle on triazolam and indocyanine green pharmacokinetics

The aim of this study was to investigate the effects of the menstrual cycle phase on the pharmacokinetics of two high-clearance agents, triazolam and indocyanine green (ICG). Eleven nonsmoking, healthy, eumenorrheic women were enrolled in this study. Triazolam (0.25 mg) was administered orally, and indocyanine green was administered as an i.v. bolus (0.5 mg/kg) during the follicular, ovulatory, and luteal phases of a single menstrual cycle. Blood samples were collected over 10 hours for triazolam and over 30 minutes for ICG. Triazolam and indocyanine green concentrations were quantitated by electron capture gas chromatography and spectrophotometry, respectively. Noncompartmental analysis was used to determine relevant pharmacokinetics parameters, which were statistically assessed using two-way ANOVA (p < 0.05). No statistical differences for triazolam were observed. Vd/F was lower in the luteal phase (107 L) as compared to the follicular (138 L) and ovulatory (133 L) phases. Clearance of triazolam was comparable in the follicular (583 ml/min), ovulatory (565 ml/min), and luteal (538 ml/min) phases. ICG also revealed no significant differences across the phases. These results suggest that the phases of the menstrual cycle do not influence triazolam or ICG pharmacokinetics.

Differential impairment of triazolam and zolpidem clearance by ritonavir

BACKGROUND

The viral protease inhibitor ritonavir has the capacity to inhibit and induce the activity of cytochrome P450-3A (CYP3A) isoforms, leading to drug interactions that may influence the efficacy and toxicity of other antiretroviral therapies, as well as pharmacologic treatments of coincident or complicating diseases.

METHODS

The inhibitory effect of ritonavir on the biotransformation of the hypnotic agents triazolam and zolpidem was tested in vitro using human liver microsomes. In a double-blind clinical study, volunteer study subjects received 0.125 mg triazolam or 5.0 mg zolpidem concurrent with low-dose ritonavir (four doses of 200 mg), or with placebo.

RESULTS

Ritonavir was a potent in vitro inhibitor of triazolam hydroxylation but was less potent as an inhibitor of zolpidem hydroxylation. In the clinical study, ritonavir reduced triazolam clearance to < 4% of control values (p < .005), prolonged elimination half-life (41 versus 3 hours; p < .005), and magnified benzodiazepine agonist effects such as sedation and performance impairment. In contrast, ritonavir reduced zolpidem clearance to 78% of control values (p < .08), and slightly prolonged elimination half-life (2.4 versus 2.0 hours; NS). Benzodiazepine agonist effects of zolpidem were not altered by ritonavir.

CONCLUSION

Short-term low-dose administration of ritonavir produces a large and significant impairment of triazolam clearance and enhancement of clinical effects. In contrast, ritonavir produced small and clinically unimportant reductions in zolpidem clearance. The findings are consistent with the complete dependence of triazolam clearance on CYP3A activity, compared with the partial dependence of zolpidem clearance on CYP3A.

Comparative kinetics and response to the benzodiazepine agonists triazolam and zolpidem: evaluation of sex-dependent differences

Eighteen healthy volunteers (10 men and 8 women) participated in a single-dose, double-blind, three-way crossover pharmacokinetic and pharmacodynamic study. Treatment conditions were 0.25 mg of triazolam, a full-agonist benzodiazepine ligand; 10 mg of zolpidem, an imidazopyridine having relative selectivity for the type 1 benzodiazepine receptor subtype; and placebo. Weight-normalized clearance of triazolam was higher in women than in men (8.7 versus 5. 5 ml/min/kg), but the difference was not significant. In contrast, zolpidem clearance was lower in women than in men (3.5 versus 6.7 ml/min/kg, P <.06). Compared to placebo, both active medications produced significant benzodiazepine agonist-like pharmacodynamic effects: sedation, impaired psychomotor performance, impaired information recall, and increased electroencephalographic beta-amplitude. Effects of triazolam and zolpidem in general were comparable and less than 8 h in duration. There was no evidence of a substantial or consistent sex difference in pharmacodynamic effects or in the kinetic-dynamic relationship, although subtle differences could not be ruled out due to low statistical power. The complete dependence of triazolam clearance on CYP3A activity, as opposed to the mixed CYP participation in zolpidem clearance, may explain the differing sex effects on clearance of the two compounds.

Midazolam and triazolam biotransformation in mouse and human liver microsomes: relative contribution of CYP3A and CYP2C isoforms

Midazolam (MDZ) and triazolam (TRZ) hydroxylation, reactions considered to be cytochrome P-4503A (CYP3A)-mediated in humans, were examined in mouse and human liver microsomes. In both species, alpha- and 4-hydroxy metabolites were the principal products. Western blotting with anti-CYP3A1 antibody detected a single band of immunoreactive protein in both human and mouse samples: 0.45 +/- 0. 12 and 2.02 +/- 0.24 pmol/mg protein (mean +/- S.E., n = 3), respectively. Ketoconazole potently inhibited MDZ and TRZ metabolite formation in human liver microsomes (IC(50) range, 0.038-0.049 microM). Ketoconazole also inhibited the formation of both TRZ metabolites and of 4-OH-MDZ formation in mouse liver microsomes (IC(50) range, 0.0076-0.025 microM). However, ketoconazole (10 microM) did not produce 50% inhibition of alpha-OH-MDZ formation in mouse liver microsomes. Anti-CYP3A1 antibodies produced concentration-dependent inhibition of MDZ and TRZ metabolite formation in human liver microsomes and of TRZ metabolite and 4-OH-MDZ formation in mouse liver microsomes to less than 20% of control values but reduced alpha-OH-MDZ formation to only 66% of control values in mouse liver microsomes. Anti-CYP2C11 antibodies inhibited alpha-OH-MDZ metabolite formation in a concentration-dependent manner to 58% of control values in mouse liver microsomes but did not inhibit 4-OH-MDZ formation. Thus, TRZ hydroxylation appears to be CYP3A specific in mice and humans. alpha-Hydroxylation of MDZ has a major CYP2C component in addition to CYP3A in mice, demonstrating that metabolic profiles of drugs in animals cannot be assumed to reflect human metabolic patterns, even with closely related substrates.

Effects of acute and chronic triazolam treatments on brain GABA levels in albino rats

The present study investigated the effects of acute and chronic intraperitoneal administration of Triazolam on g-aminobutyric acid (GABA) levels in different brain areas of albino rats. Three experiments were conducted. In the first, five groups of rats were acutely treated with different doses of Triazolam (0.25 mg/kg-4.0 mg/kg). In the second experiment, rats were treated chronically with a single daily dose of Triazolam (started with 0.25 mg/kg and increased by time to 1.0 mg/kg) for 5 weeks, simulating clinical use. In the third, rats were treated chronically with three daily doses of Triazolam (started with 0.25 mg/kg and increased by time to 0.5 mg/kg) for 20 days, representing a form of drug abuse. Brain levels of GABA and plasma levels of Triazolam were measured using high performance liquid chromatography (HPLC). The acute Triazolam administration produced an increase in GABA levels in all brain areas studied. The chronic administration of single daily dose of Triazolam produced normal GABA levels in all brain areas except brain stem where the levels were significantly decreased; this indicates the development of tolerance to Triazolam action on increasing GABA content. The chronic administration of three daily doses of Triazolam produced a decrease in GABA levels in all brain regions studied. In conclusion, chronic single daily dose treatment (representing normal use) produces tolerance to Triazolam effects on brain GABA levels, while chronic three daily doses administration (akin to drug abuse) causes a fall in GABA levels.

Pharmacokinetic and pharmacodynamic consequences of metabolism-based drug interactions with alprazolam, midazolam, and triazolam

This review was conducted to identify the current data on drug interactions with alprazolam, midazolam, and triazolam to guide practitioners in the use of these drugs. The Medline electronic database from 1966 through 1998 was used to identify clinical studies of the pharmacokinetic effect of drugs on these three benzodiazepines. Of a total of 491 literature reports identified, 59 prospective studies met our selection criteria. The pharmacokinetic parameters of AUC, Cmax, t1/2, and tmax were evaluated for changes following an interaction. To allow comparison between studies, changes in the parameters were normalized relative to the control values. Pharmacodynamic effects and measures, when reported in the original studies as statistically significant, were classified as a strong interaction, and when the interaction was present but not statistically significant, they were classified as mild in this review. As a result, clinically significant drug interactions were noted for all three benzodiazepines, although it is clear that statistically significant pharmacokinetic changes do not always translate into clinically significant pharmacodynamic consequences. All three benzodiazepines were susceptible to drug interactions, but oral dosing of midazolam and triazolam resulted in greater alterations in the pharmacokinetic parameters than alprazolam due to their larger presystemic extraction. Ketoconazole and itraconazole were found to be the most potent metabolic inhibitors that prolonged the duration of or intensified the magnitude of the dynamic response produced by the three benzodiazepines. Rifampin, carbamazepine, and phenytoin were noted to be potent metabolic inducers, and their treatments result in loss of benzodiazepine therapeutic efficacy. In conclusion, potent metabolic inhibitors and inducers can either significantly prolong or diminish the dynamic effects of benzodiazepines via their influence on the pharmacokinetics of benzodiazepines.

Effects of triazolam at three phases of the menstrual cycle

This study investigated the subjective and behavioral effects of a commonly used benzodiazepine, triazolam, in healthy women at three phases of the menstrual cycle: follicular, periovulatory, and luteal. Ovarian hormones or their metabolites have direct and indirect actions on neuronal receptors, which may affect responses to psychoactive drugs acting on the same central nervous system receptors. This study explored the effect of menstrual cycle phase on the mood-altering and performance effects of a single oral dose of the benzodiazepine triazolam. Twenty women received triazolam (0.25 mg orally) or placebo at the follicular, periovulatory, and luteal phases of their menstrual cycles in a within-subject design. Dependent measures included self-reported mood states, psychomotor performance, and plasma levels of triazolam, estradiol, progesterone, and allopregnanolone. After administration of triazolam, most subjects reported the expected increases in fatigue and decreases in arousal and psychomotor performance. Neither plasma levels nor mood and performance effects of triazolam differed across the three phases. This study illustrates a useful methodology for assessing responses to psychoactive drugs in normally cycling women and shows that the effects of this drug were highly stable across the cycle.

Mibefradil but not isradipine substantially elevates the plasma concentrations of the CYP3A4 substrate triazolam

BACKGROUND

The calcium channel blockers mibefradil and isradipine inhibit CYP3A4 in vitro. However, their in vivo inhibitory effects on CYP3A4 are not known in detail, although mibefradil was recently withdrawn from the market because of serious drug interactions.

METHODS

The effects of mibefradil and isradipine on the pharmacokinetics and pharmacodynamics of oral triazolam, a model substrate of CYP3A4, were studied in a randomized, double-blind crossover study with three phases. Nine healthy subjects took 50 mg mibefradil, 5 mg isradipine, or placebo orally once a day for 3 days. On day 3, each subject received a single 0.25 mg oral dose of triazolam. Thereafter, blood samples were collected up to 18 hours, and pharmacodynamic effects of triazolam were measured up to 8 hours.

RESULTS

Mibefradil increased the total area under the plasma triazolam concentration-time curve [AUC(0 - infinity)] 9-fold compared with placebo (P < .001). The peak plasma concentration of triazolam was increased 1.8-fold (3.4+/-0.1 ng/mL versus 1.8+/-0.2 ng/mL [mean +/- SEM]; P < .001), and the elimination half-life (t 1/2) was increased 4.9-fold (18.5+/-1.9 hours versus 4.0+/-0.5 hours; P < .001) by mibefradil. In addition, mibefradil was associated with increased pharmacodynamic effects of triazolam. In contrast to mibefradil, isradipine reduced the AUC(0 - infinity) and t 1/2 of triazolam by about 20% (P < .05) and had no significant effects on the pharmacodynamics of triazolam.

CONCLUSION

Mibefradil but not isradipine markedly increases the plasma concentrations of triazolam and thereby enhances and prolongs its pharmacodynamic effects, consistent with potent inhibition of CYP3A4.

Zaleplon and triazolam in humans: acute behavioral effects and abuse potential

Zaleplon, a pyrazolopyrimidine that is under development as a hypnotic, produces its pharmacological effects at the benzodiazepine-recognition site on the GABA(A) benzodiazepine-receptor complex. Unlike most benzodiazepines, zaleplon binds selectively to the BZ1 (omega1) subtype of the benzodiazepine receptor. The present study compared the acute subject-rated effects, performance-impairing effects, and abuse potential of zaleplon and triazolam, a triazolobenzodiazepine hypnotic, in 14 healthy volunteers with histories of drug abuse. Zaleplon (25, 50, and 75 mg), triazolam (0.25, 0.5, and 0.75 mg) and placebo were administered orally in this double-blind, crossover study. Zaleplon and triazolam produced comparable dose-related effects on several subject-rated drug-effect questionnaires. Zaleplon and triazolam also produced comparable dose-dependent decrements on several performance tasks including balance, circular lights, digit-enter and recall, DSST, picture recall/recognition and repeated acquisition. Same-day and next-day subject-rated measures reflecting abuse potential (e.g., drug liking, good effects, and monetary street value) also suggest that zaleplon and triazolam were comparable. The only notable between-drug difference observed in the present study was that the time-action function of zaleplon differed from that of triazolam. The onset time, time to maximum drug effect, and duration of action were shorter with zaleplon than triazolam. Thus, despite its non-benzodiazepine structure and unique benzodiazepine-receptor binding profile, the behavioral pharmacological profile of zaleplon is similar to that of triazolam.

Cytochrome P450 3A4 in vivo ketoconazole competitive inhibition: determination of Ki and dangers associated with high clearance drugs in general

Assuming complete hepatic substrate metabolism and system linearity, quantitative effects of in vivo competitive inhibition are investigated. Following oral administration of a substrate in the presence of a competitive inhibitor, determination of the inhibition constant (Ki) is possible when plasma concentration-time profiles of both substrate and inhibitor are available. When triazolam is the P450 3A4 substrate and ketoconazole the competitive inhibitor, Ki approximately 1.2 microg/mL in humans. The effects of competitive inhibition can be divided into two components: first-pass hepatic metabolism and systemic metabolism. For drugs with high hepatic extraction ratios, the impact of competitive inhibition on hepatic first-pass metabolism can be particularly dramatic. For example, human terfenadine hepatic extraction goes from 95% in the absence of a competitive inhibitor to 35% in the presence of one (ketoconazole, 200 mg po Q 12 h dosed to steady-state). First-pass extraction therefore goes from 5% in the absence of the inhibitor to 65% in its presence. The combined effect on first-pass and systemic metabolism produces an approximate 37 fold increase in terfenadine area under the plasma concentration-time curve. Assuming intact drug is active and/or toxic, development of metabolized drugs with extensive first-pass metabolism should be avoided if possible, since inhibition of metabolism may lead to profound increases in exposure.

Inhibition of triazolam clearance by macrolide antimicrobial agents: in vitro correlates and dynamic consequences

BACKGROUND

Macrolide antimicrobial agents may impair hepatic clearance of drugs metabolized by cytochrome P4503A isoforms. Potential interactions of triazolam, a substrate metabolized almost entirely by cytochrome P4503A in humans, with 3 commonly prescribed macrolides were identified using an in vitro metabolic model. The actual interactions, and their pharmacodynamic consequences, were verified in a controlled clinical study.

METHODS

In an in vitro model using human liver microsomes, 250 mumol/L triazolam was incubated with ascending concentrations (0 to 250 mumol/L of troleandomycin, azithromycin, erythromycin, and clarithromycin. In a randomized, double-blind, 5-trial clinical pharmacokinetic-pharmacodynamic study, 12 volunteers received 0.125 mg triazolam orally, together with placebo, azithromycin, erythromycin, or clarithromycin. In a fifth trial they received placebo plus placebo.

RESULTS

Mean 50% inhibitory concentrations versus 4-hydroxytriazolam formation in vitro were as follows: 3.3 mumol/L troleandomycin, 27.3 mumol/L erythromycin, 25.2 mumol/L clarithromycin, and greater than 250 mumol/L azithromycin. Apparent oral clearance of triazolam when given with placebo or azithromycin was nearly identical (413 and 416 mL/min), as were peak plasma concentrations (1.25 and 1.32 ng/mL) and elimination half-life (2.7 and 2.6 hours). Apparent oral clearance was significantly reduced (P < .05) during erythromycin and clarithromycin trials (146 and 95 mL/min). Peak plasma concentration was correspondingly increased, and elimination half-life was prolonged. The effects of triazolam on dynamic measures were nearly identical when triazolam was given with placebo or azithromycin, but benzodiazepine agonist effects were enhanced during erythromycin and clarithromycin trials.

CONCLUSION

The in vitro model identifies macrolides that may impair triazolam clearance. Anticipated interactions, and their pharmacodynamic consequences in volunteer subjects, were verified in vivo.

The effect of dexamethasone on the pharmacokinetics of triazolam

The effects of short-term use of a small dose of dexamethasone on the pharmacokinetics and pharmacodynamics of the CYP3A4 substrate, triazolam, were examined. In a randomized, double-blind cross-over study with two phases, ten healthy volunteers were given either 1.5 mg dexamethasone or placebo once a day for 4 days. On the 5th day, 0.5 mg triazolam was administered orally. Plasma triazolam concentrations and effects of triazolam were measured for 10 hr. Dexamethasone did not have statistically significant effects on the pharmacokinetics of triazolam. The mean total area under the plasma triazolam concentration-time curve was, however, 19% smaller during the dexamethasone phase than during the placebo phase (11.4 +/- 5.7 ng ml-1 hr versus 14.1 +/- 8.8 ng ml-1 hr (mean +/- S.D.); P = 0.09). The four psychomotor tests employed did not show significant differences in the effects of triazolam between the phases. Although dexamethasone had only small effects on the pharmacokinetics and pharmacodynamics of triazolam in the present study, higher doses or prolonged use of dexamethasone might cause a more pronounced induction of CYP3A4. Further studies on the effects of dexamethasone on the pharmacokinetics of CYP3A4 substrates in man are needed.

Ketoconazole inhibition of triazolam and alprazolam clearance: differential kinetic and dynamic consequences

BACKGROUND

Kinetic and dynamic consequences of metabolic inhibition were evaluated in a study of the interaction of ketoconazole, a P4503A inhibitor, with alprazolam and triazolam, two 3A substrate drugs with different kinetic profiles.

METHODS

In a double-blind, 5-way crossover study, healthy volunteers received (A) ketoconazole placebo plus 1.0 mg alprazolam orally, (B) 200 mg ketoconazole twice a day plus 1.0 mg alprazolam, (C) ketoconazole placebo plus 0.25 mg triazolam orally, (D) 200 mg ketoconazole twice a day plus 0.25 mg triazolam, and (E) 200 mg ketoconazole twice a day plus benzodiazepine placebo. Plasma concentrations and pharmacodynamic parameters were measured after each dose.

RESULTS

For trial B versus trial A, alprazolam clearance was reduced (27 versus 86 mL/min; P < .002) and apparent elimination half-life (t1/2) prolonged (59 versus 15 hours; P < .03), whereas peak plasma concentration (Cmax) was only slightly increased (16.1 versus 14.7 ng/mL). The 8-hour pharmacodynamic effect areas for electroencephalographic (EEG) beta activity were increased by a factor of 1.35, and those for digit-symbol substitution test (DSST) decrement were increased by 2.29 for trial B versus trial A. For trial D versus trial C, triazolam clearance was reduced (40 versus 444 mL/min; P < .002), t1/2 was prolonged (18.3 versus 3.0 hours; P < .01), and Cmax was increased (2.6 versus 5.4 ng/mL; P < .001). The 8-hour effect area for EEG was increased by a factor of 2.51, and that for DSST decrement was increased by 4.33. Observed in vivo clearance decrements due to ketoconazole were consistent with those anticipated on the basis of an in vitro model, together with in vivo plasma concentrations of ketoconazole.

CONCLUSION

For triazolam, an intermediate-extraction compound, impaired clearance by ketoconazole has more profound clinical consequences than those for alprazolam, a low extraction compound.

Effects of ketoconazole on triazolam pharmacokinetics, pharmacodynamics and benzodiazepine receptor binding in mice

We previously demonstrated that ketoconazole is a potent inhibitor of triazolam biotransformation in vitro and in vivo. Despite significant elevations in triazolam plasma levels with coadministration of ketoconazole, the pharmacodynamic enhancement was lower than predicted based on plasma levels of triazolam. The present study examines the effects of ketoconazole on benzodiazepine receptor binding in vitro as well as on open-field behavior in male CD-1 mice. Triazolam alone inhibited [3H]flunitrazepam binding with an IC50 value of 0.85 nM and a Ki value of 0.50 nM. Ketoconazole alone also competitively antagonized [3H]flunitrazepam binding in a concentration-dependent manner with an IC50 value of 1.56 microM and a Ki value of 1.17 microM. In the presence of 1, 3 or 9 microM ketoconazole, the IC50 value of triazolam was increased to 1.11, 1. 58 and 5.73 nM, respectively, whereas maximal binding was reduced by 36%, 69% and 89%. Coadministration of 50 mg/kg ketoconazole and triazolam (0.1-0.3 mg/kg) to intact animals significantly elevated plasma and brain triazolam levels. Ketoconazole could be measured in mouse brain at levels averaging 31% of those in plasma. Ketoconazole alone had minimal or no effect on open field activity, but it significantly potentiated the decreased activity seen with triazolam administration. The ability of ketoconazole to inhibit triazolam displacement of [3H]flunitrazepam binding may explain the muted pharmacodynamic effect of this benzodiazepine in the presence of ketoconazole. Based on these results, it is likely that ketoconazole acts as a neutral ligand at the benzodiazepine receptor.

Single-dose pharmacokinetics and pharmacodynamics of oral triazolam in relation to cytochrome P4502C19 (CYP2C19) activity

Previous studies have suggested that triazolam is at least partly metabolized by cytochrome P4503A4 (CYP3A4). However, no study has examined the relationship between the metabolism of triazolam and CYP2C19, which is involved in the metabolism of diazepam. Therefore, the single-dose pharmacokinetics and pharmacodynamics of oral triazolam were studied in relation to the CYP2C19 status assessed by the S-mephenytoin 4-hydroxylation capacity in 12 healthy male volunteers, consisting of seven extensive metabolizers (EMs) and five poor metabolizers (PMs) of S-mephenytoin 4-hydroxylation. Each subject was administered a single oral dose of 0.5 mg of triazolam, and blood was sampled up to 12 hours after the dosing. Psychomotor function was assessed by the Digit-Symbol Substitution test, Visual Analogue Scale, and Udvalg for Kliniske Undersøgelser (UKU) scale. Plasma triazolam concentrations were measured by high-performance liquid chromatography. There were no significant differences in plasma concentrations from 20 minutes to 6 hours after the dosing nor in pharmacokinetic parameters of triazolam between the EM and PM groups. No significant difference was found in psychomotor function between the EM and PM groups. These results suggest that CYP2C19 is not involved in the metabolism of triazolam and that CYP2C19 status is not a pharmacodynamic determinant of this triazolobenzodiazepine.

Comparison of sublingually and orally administered triazolam for premedication before oral surgery

OBJECTIVES

This study evaluated sublingual administration of triazolam for preoperative sedation in dental outpatients.

STUDY DESIGN

A double-blind, placebo-controlled study compared 0.25 mg sublingual triazolam, 0.25 mg oral triazolam, and placebo administered 1 hour before oral surgery.

RESULTS

Sublingual triazolam resulted in significantly less anxiety and pain at 15 minutes intraoperatively than both oral triazolam and placebo (p < 0.05). Patients' global evaluation of the efficacy of sedation ranked sublingual triazolam as significantly more efficacious than placebo (p < 0.05) with oral triazolam intermediate between the two. No difference was demonstrated in the rate of recovery or incidence of side effects between the two drug groups. Plasma triazolam levels were higher after sublingual administration during and after the surgical procedure.

CONCLUSIONS

These results indicate that sublingual triazolam results in greater anxiolytic activity and less pain perception than oral administration as a result of greater plasma drug levels and may be useful as an alternative for nonparenteral outpatient sedation.

Pharmacokinetics of oral triazolam in children

The purpose of this study was to determine the pharmacokinetic behavior of triazolam in children. Nine healthy children, aged 6 to 9 years, received oral triazolam (0.025 mg/kg suspended in Kool-Aid, Kraft General Foods, Chicago, IL) before dental treatment. Plasma triazolam concentrations were measured by gas chromatography/mass spectrophotometry at approximately 5, 15, 30, 45, 60, 90, 120, 180, and 240 minutes. A one-compartment model with first-order absorption and varying parameters was used, and estimated concentration curves were obtained for each subject. The observed peak plasma concentration was 8.5 +/- 3.0 ng/mL (mean +/- SD). The observed time to peak plasma concentration was 74 +/- 25 minutes. Elimination half-life was 213 +/- 144 minutes. Substantial recovery from signs and symptoms of clinical sedation required 180 to 240 minutes. The long duration of effect and relatively slow elimination should be noted by clinicians concerned with patient safety.

Relationship between single oral dose pharmacokinetics of alprazolam and triazolam

The relationship between the single oral dose pharmacokinetics of alprazolam and triazolam was studied in 10 healthy male volunteers. Each subject took single oral doses of alprazolam 0.8 mg and triazolam 0.5 mg with at least a 2 week interval between each dose. Blood samplings were performed up to 48 h after alprazolam dosing and up to 12 h after triazolam dosing. Plasma concentrations of both drugs were measured by high-performance liquid chromatography. The means +/- standard deviation of the peak plasma concentration, the total area under the plasma concentration-time curve and the elimination half-life of alprazolam were 11.3 +/- 3.1 ng/ml, 232.4 +/- 59.2 ng/h/ml and 16.5 +/- 4.6 h, respectively, and those of triazolam were 3.2 +/- 1.0 ng/ml, 11.8 +/- 5.2 ng/h/ml and 2.5 +/- 1.1 h, respectively. There was no significant correlation between the two drugs in any pharmacokinetic parameters (r = 0.35, 0.25 and 0.50). The present study thus suggests that the single oral dose pharmacokinetics of alprazolam and triazolam do not correlate well in individuals.