Rapid determination of benzodiazepines, zolpidem and their metabolites in urine using direct injection liquid chromatography-tandem mass spectrometry.

Benzodiazepines and zolpidem are generally prescribed as sedative, hypnotics, anxiolytics or anticonvulsants. These drugs, however, are frequently misused in drug-facilitated crime. Therefore, a rapid and simple liquid chromatography-tandem mass spectrometric (LC-MS/MS) method was developed for identification and quantification of benzodiazepines, zolpidem and their metabolites in urine using deuterium labeled internal standards (IS). Urine samples (120 µL) mixed with 80 µL of the IS solution were centrifuged. An aliquot (5 µL) of the sample solution was directly injected into the LC-MS/MS system for analysis. The mobile phases consisted of water and acetonitrile containing 2mM ammonium trifluoroacetate and 0.2% acetic acid. The analytical column was a Zorbax SB-C18 (100 mm × 2.1 mm i.d., 3.5 µm, Agilent). The separation and detection of 18 analytes were achieved within 10 min. Calibration curves were linear over the concentration ranges of 0.5-20 ng/mL (zolpidem), 1.0-40 ng/mL (flurazepam and temazepam), 2.5-100 ng/mL (7-aminoclonazepam, 1-hydroxymidazolam, midazolam, flunitrazepam and alprazolam), 5.0-200 ng/mL (zolpidem phenyl-4-carboxylic acid, α-hydroxyalprazolam, oxazepam, nordiazepam, triazolam, diazepam and α-hydroxytriazolam), 10-400 ng/mL (lorazepam and desalkylflurazepam) and 10-100 ng/mL (N-desmethylflunitrazepam) with the coefficients of determination (r(2)) above 0.9971. The dilution integrity of the analytes was examined for supplementation of short linear range. Dilution precision and accuracy were tested using two, four and ten-folds dilutions and they ranged from 3.7 to 14.4% and -12.8 to 12.5%, respectively. The process efficiency for this method was 63.0-104.6%. Intra- and inter-day precisions were less than 11.8% and 9.1%, while intra- and inter-day accuracies were less than -10.0 to 8.2%, respectively. The lower limits of quantification were lower than 10 ng/mL for each analyte. The applicability of the developed method was successfully verified with human urine samples from drug users (n=21). Direct urine sample injection and optimized mobile phases were introduced for simple sample preparation and high-sensitivity with the desired separation.

Analysis of quazepam and its metabolites in human urine by gas chromatography-mass spectrometry: application to a forensic case.

A sensitive method for the simultaneous determination of quazepam and two of its metabolites, 2-oxoquazepam and 3-hydroxy-2-oxoquazepam, in human urine was developed using gas chromatography-mass spectrometry (GC/MS) with an Rtx-5MS capillary column. The quazepam and its metabolites were extracted from human urine using a simple solid-phase extraction Oasis(®) HLB cartridge column, and the 3-hydroxy-2-oxoquazepam was derivatised using BSTFA/1%TMCS and pyridine at 60 °C for 30 min. The mass spectrometric detection of the analytes was performed in the full scan mode, m/z 60-480, and selected ion monitoring (SIM) mode, m/z 386, for quazepam; m/z 342, for 2-oxoquazepam; m/z 429, for 3-hydroxy-2-oxoquazepam-TMS; and m/z 284, for alprazolam-d5 (internal standard), by electron ionization. The calibration curves of quazepam and its metabolites in urine showed good linearity in the concentration range of 2.5-500 ng/0.2 ml of urine. The average recoveries of quazepam and its metabolites from 0.2 ml of urine containing 500 ng and 50 ng of each drug were 71-83% and 88-90%, respectively. The limits of detection of quazepam, 2-oxoquazepam and 3-hydroxy-2-quazepam in urine by the selected ion monitoring mode were 0.096-0.37 ng/ml. This method would be applicable to other forensic biological materials containing low concentrations of quazepam and its metabolites.

Sensitive UPLC-MS-MS assay for 21 benzodiazepine drugs and metabolites, zolpidem and zopiclone in serum or plasma.

This paper reports an ultra-performance liquid chromatography-tandem mass spectrometry (UPLC-MS-MS) method to quantitate 21 benzodiazepines, zolpidem and zopiclone in serum and plasma. After liquid-liquid extraction, an Acquity UPLC with a TQ Detector and BEH C18 column was used (Waters, Milford, MA). The injection-to-injection run time was 7.5 min. Forty-eight authentic serum and plasma patient specimens were analyzed and results compared to those obtained using a previously published method. Average r(2) values for linearity (1 to 1,000 ng/mL over five days) were all above 0.995, except α-hydroxytriazolam (0.993). Intra-day and inter-day relative standard deviation values were within ± 15% and the percent deviation from the expected concentrations were within ± 11%. Recovery ranged from 62 to 89%. Matrix effects ranged from -28% to +6%. The limits of detection were 1 ng/mL, except for lorazepam, nordiazepam, oxazepam and temazepam (5 ng/mL). Ion ratios were ± 15% for all analytes. For authentic patient specimens (n = 48, 76 positive results), there was excellent correlation between the UPLC-MS-MS results and the previous method. The best least-squares fit had an equation of y = 1.0708x + 1.6521, r(2) = 0.9822. This UPLC-MS-MS method is suitable for the quantification of benzodiazepines and hypnotics in serum and plasma, and offers fast, reliable and sensitive results.

Acute intoxication caused by overdose of flunitrazepam and triazolam: high concentration of metabolites detected at autopsy examination.

A 52-year-old woman was found dead on the floor of the living room on the first floor of a house, which belonged to the man with whom she shared the house. On visiting the site, her clothes were found to be undisturbed. Packages of flunitrazepam (Silece, 2 mg/tablet) and triazolam (Halcion, 0.25 mg/tablet) were found strewn around the victim. Toxicological analysis was performed, and the concentrations of flunitrazepam, triazolam, and their metabolites in the victim's blood and urine were measured by high-performance liquid chromatography coupled with photodiode array and mass spectrometry. A high blood concentration of 7-aminoflunitrazepam was detected (1,270 ng/g), and further metabolites such as 7-acetamidoflunitrazepam, 7-acetamidodesmethylflunitrazepam, and 7-aminodesmethylflunitrazepam were detected in the blood and urine samples. In addition, 4-hydroxytriazolam and α-hydroxytriazolam were detected in her urine at a concentration of 950 and 12,100 ng/mL, respectively.On the basis of the autopsy findings and toxicology results of high concentrations of both flunitrazepam and triazolam derivatives, the cause of death was determined to be acute intoxication from flunitrazepam and triazolam.

A drug rape case involving triazolam detected in hair and urine.

In recent years, there has been heightened awareness regarding the use of drugs to modify a person's behavior to facilitate crime. A drug rape case involving the potent, short-acting sedative triazolam will be presented. On three occasions, the victim consumed green tea and chocolate before being massaged and ultimately sexually abused. Screening for alcohol, commonly used drugs and illicit substances in blood and urine sampled during the forensic examination 20 h after the last incident, was negative. Consequently, hair samples for chemical analysis were taken from the assaulted individual 34 days after the last incidents. The hair was cut into three 2-cm segments (0-6 cm) that were washed, dissolved in extraction solvent and screened and verified by ultra performance liquid chromatography coupled with time of flight mass spectrometry (UPLC-TOF-MS) and with tandem mass spectrometry (UPLC-MS/MS), respectively. In the 2-cm hair segment corresponding to the period of the alleged assaults, the presence of the sedative triazolam was revealed at a concentration of 1.0 pg/mg hair. The preserved urine sample, taken 20 h after the last incident, was reanalyzed by UPLC-MS/MS for metabolites of triazolam, and 39 µg/l α-hydroxytriazolam was detected in the hydrolyzed urine. This case illustrates that hair is a valuable forensic specimen in situations where natural processes have eliminated the drug from typical biological specimens due to delays in the crime being reported. Furthermore, it was possible to verify the hair finding with a urine sample by detection of a metabolite of triazolam.

Simultaneous quantification of triazolam and its metabolites in human urine by liquid chromatography-tandem mass spectrometry.

A simple, simultaneous, sensitive and selective liquid chromatography-tandem mass spectrometry (LC-MS-MS) method for the determination of triazolam and its metabolites, α-hydroxytriazolam (α-OHTRZ) and 4-hydroxytriazolam (4-OHTRZ), in human urine was developed and validated. Triazolam-d4 was used as the internal standard (IS). This analysis was carried out on a Thermo(®) C(18) column, and the mobile phase was composed of acetonitrile/H(2)O/formic acid (35:65:0.2, v/v/v). Detection was performed on a triple-quadrupole tandem MS using positive ion mode electrospray ionization, and quantification was performed by multiple reaction monitoring mode. The MS-MS ion transitions monitored were m/z 343.1 → 308.3, 359.0 → 331.0, 359.0 → 111.2, and 347.0 → 312.0 for triazolam, α-OHTRZ, 4-OHTRZ, and triazolam-d(4), respectively. The lower limits of quantification of the analytical method were 0.5 ng/mL for triazolam, 5 ng/mL for α-OHTRZ, and 0.5 ng/mL for 4-OHTRZ. The within- and between-run precisions were less than 15%, and accuracy was -12.33% to 9.76%. The method was proved to be accurate and specific, and it was applied to a urinary excretion study of triazolam in healthy Chinese volunteers.

Determination of triazolam and alpha-hydroxytriazolam in guinea pig hair after a single dose.

A sensitive liquid chromatography-tandem mass spectrometry method is presented for determination of triazolam and alpha-hydroxytriazolam in guinea pig hair after a single dose of triazolam. Eighteen guinea pigs were divided into three dosage groups (10, 100, and 500 microg/kg) and administrated a single dose of triazolam intragastrically. Before administration, drug-free hair was shaved from their back. Newly grown hair in shaved area was collected every seven days after administration. About 20 mg of decontaminated hair was cut into small segments and incubated in 2 mL of phosphate buffer (pH 8.4) at 45 degrees C overnight. Triazolam-d(4) and alpha-hydroxytriazolam-d(4) were used as internal standards, and liquid-liquid extraction was performed with 3 mL of ethyl ether. The sample was separated on an Allure propyl PFP column with a mobile phase of acetonitrile/20 mM ammonium acetate (7:3, v/v). Detection was implemented with multiple reaction monitoring mode by an API4000 triple-quadrupole tandem mass spectrometer. Limits of detection for triazolam and alpha-hydroxytriazolam were 1 and 5 pg/mg, respectively. Triazolam and alpha-hydroxytriazolam could only be detected in the first week, and 100 microg/kg was the minimal dosage detectable in guinea pig hair. The concentration of triazolam in hair was related with administration dosage and hair color. alpha-Hydroxytriazolam has a higher concentration than triazolam in guinea pig hair.

Quantitation of benzodiazepines in blood and urine using gas chromatography-mass spectrometry (GC-MS).

The benzodiazepine assay utilizes gas chromatography-mass spectrometry (GC-MS) for the analysis of diazepam, nordiazepam, oxazepam, temazepam, lorazepam, alpha-hydroxyalprazolam, and alpha-hydroxytriazolam in blood and urine. A separate assay is employed for the analysis of alprazolam. Prior to solid phase extraction, urine specimens are subjected to enzyme hydrolysis. The specimens are fortified with deuterated internal standard and a five-point calibration curve is constructed. Specimens are extracted by mixed-mode solid phase extraction. The benzodiazepine extracts are derivatized with N-methyl-N-(tert-butyldimethylsilyl)trifluoroacetamide (MTBSFTA) producing tert-butyldimethyl silyl derivatives; the alprazolam extracts are reconstituted in methanol without derivatization. The final extracts are then analyzed using selected ion monitoring GC-MS.

LC-MS/MS analysis of 13 benzodiazepines and metabolites in urine, serum, plasma, and meconium.

We describe a single method for the detection and quantitation of 13 commonly prescribed benzodiazepines and metabolites: alpha-hydroxyalprazolam, alpha-hydroxyethylflurazepam, alpha-hydroxytriazolam, alprazolam, desalkylflurazepam, diazepam, lorazepam, midazolam, nordiazepam, oxazepam, temazepam, clonazepam and 7-aminoclonazepam in urine, serum, plasma, and meconium. The urine and meconium specimens undergo enzyme hydrolysis to convert the compounds of interest to their free form. All specimens are prepared for analysis using solid-phase extraction (SPE), analyzed using liquid chromatography coupled to tandem mass spectrometry (LC-MS/MS), and quantified using a three-point calibration curve. Deuterated analogs of all 13 analytes are included as internal standards. The instrument is operated in multiple reaction-monitoring (MRM) mode with an electrospray ionization (ESI) source in positive ionization mode. Urine and meconium specimens have matrix-matched calibrators and controls. The serum and plasma specimens are quantified using the urine calibrators but employing plasma-based controls. Oxazepam glucuronide is used as a hydrolysis control.

Pomegranate juice does not impair clearance of oral or intravenous midazolam, a probe for cytochrome P450-3A activity: comparison with grapefruit juice.

The effect of pomegranate juice (PJ) or grapefruit juice (GFJ) on CYP3A activity was studied in vitro and in healthy human volunteers. In human liver microsomes, the mean 50% inhibitory concentrations (IC(50)) for PJ and GFJ versus CYP3A (triazolam alpha-hydroxylation) were 0.61% and 0.55%, (v/v) respectively, without preincubation of inhibitor with microsomes. After preincubation, the IC(50) for PJ increased to 0.97% (P < .05), whereas the IC(50) for GFJ decreased to 0.41% (P < .05), suggesting mechanism-based inhibition by GFJ but not PJ. Pretreatment of volunteer subjects (n = 13) with PJ (8 oz) did not alter the elimination half-life, volume of distribution, or clearance of intravenous midazolam (2 mg). Administration of PJ also did not affect C(max), total area under the curve (AUC), or clearance of oral midazolam (6 mg). However, GFJ (8 oz) increased midazolam C(max) and AUC by a factor of 1.3 and 1.5, respectively, and reduced oral clearance to 72% of control values. Thus, PJ does not alter clearance of intravenous or oral midazolam, whereas GFJ impairs clearance and elevates plasma levels of oral midazolam.

A study of the in vitro interaction between ethanol, and triazolam and its two metabolites using human liver microsomes.

AIM: Triazolam is widely used as an ultrashort-acting anxiolytic drug and hypnosedatives and its effect appears at very low doses. Ethanol is used as a social drug worldwide. Sometimes, toxic interactions occur following combined administration of these two drugs. In this study, we have investigated the interaction between alcohol and triazolam in vitro. METHODS: The interaction effects between alcohol and triazolam were examined by a mixed-function oxidation reaction using a human liver microsomal preparation. Triazolam and its two metabolites (alpha-hydroxytriazolam: alpha-OH triazolam, 4-hydroxytriazolam: 4-OH triazolam) were measured by HPLC/UV. RESULTS: The production of alpha-OH triazolam and 4-OH triazolam was shown to be weakly inhibited by 13-29% (p < 0.05) and 8-14%,respectively, by ethanol (20-80 mM). CONCLUSIONS: These results using a human liver microsomal preparation show that the formation of both metabolites of triazolam is weakly inhibited by ethanol. Toxic levels may be reached by simultaneous administration of ethanol and triazolam.

Urinary excretion profiles of two major triazolam metabolites, alpha-hydroxytriazolam and 4-hydroxytriazolam.

The objective of this study was to examine urinary excretion profiles of two major triazolam metabolites, alpha-hydroxytriazolam (alpha-OHTRZ) and 4-hydroxytriazolam (4-OHTRZ) in humans. Urine samples were collected from three healthy male volunteers who had been previously administered single 0.25- and 0.5-mg doses of triazolam 24 h and 48 h, respectively, before sample collection. After enzymatic hydrolysis and extraction, each sample was analyzed by liquid chromatography-mass spectrometry. alpha-OHTRZ was rapidly excreted, with the maximum concentrations appearing in the first or second sample collected after ingestion, with the majority of the drug being excreted within 12 h. Meanwhile, 4-OHTRZ was excreted more slowly than alpha-OHTRZ. The alpha-OHTRZ/4-OHTRZ ratios were initially greater than 19.7, then decreased rapidly, reaching a nearly constant value for times in excess of 12 h.

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.

A case of fatal triazolam overdose.

A 57-year-old man was found dead lying down in a bamboo thicket. Moderate to severe petechiae were present on his conjunctivae, buccal mucosa, and laryngeal mucosa at autopsy. Cardiac chambers contained a normal volume of fluid blood. Moderate atherosclerosis and fatty liver were observed. No remarkable changes, other than congestion in other organs, were observed. Gas chromatographic screening of the stomach contents, blood and urine was positive for triazolam and alpha-hydroxytriazolam that were confirmed by gas chromatography-mass spectrometry. Blood concentrations of triazolam and free alpha-hydroxytriazolam were 62-251 and 10-66 ng/ml, respectively. A substantial amount of triazolam was detected in bile (1130 ng/ml), but not in urine. Free and total alpha-hydroxytriazolam concentrations were 3920 and 7050 ng/ml, respectively, in the bile and 3710 and 9670 ng/ml, respectively, in urine. Organs contained 216-583 ng/g triazolam. The concentration of free alpha-hydroxytriazolam in the kidney (246 ng/g) was higher than in any other organ. Free alpha-hydroxytriazolam was not detected in the liver. The concentrations of total alpha-hydroxytriazolam in the liver and kidney were 784 and 381 ng/g, respectively. Free to total ratios of alpha-hydroxytriazolam were 0.14-0.56 in fluid samples and 0.56-0.92 in tissue samples, except for the liver. A large quantity of triazolam (8.4 mg) remained in the stomach. The victim probably died of postural asphyxia caused by triazolam poisoning.

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 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.

Comparative evaluation of five immunoassays for the analysis of alprazolam and triazolam metabolites in urine: effect of lowering the screening and GC-MS cut-off values.

This study included evaluation of five commercially available immunoassays for the detection of alprazolam and triazolam metabolites in urine following single oral doses of these drugs. The products investigated were the EMIT d.a.u. assay, EMIT II assay, Abbott TDx (FPIA) assay, Bio Site TRIAGE device, and the Boehringer Mannheim/Microgenics CEDIA assay for urinary benzodiazepines. Urine specimens were also analyzed quantitatively by gas chromatography-mass spectrometry. Percent cross-reactivity was assessed by analysis of drug free urine containing drug standards at concentrations ranging from 100 to 10,000 ng/mL. The drug standards analyzed were alpha-OH-alprazolam, alpha-OH-triazolam, and alpha-OH-alprazolam glucuronide. The effect of lowering the screening cut-off value to 100 ng/mL, lowering the confirmation cut-off value to 50 and 25 ng/mL and the use of beta-glucuronidase hydrolysis prior to analysis was also studied. Lowering the screening cut-off value and using enzymatic hydrolysis prior to screening increased the positive detection rate for benzodiazepines with the EMIT d.a.u. assay and fluorescence polarization immunoassay (FPIA). The TRIAGE device gave the lowest percent cross-reactivity in the analysis of the drug standards and gave negative results in all urine specimens analyzed following ingestion of alprazolam and triazolam.

Urinary screening for alpha-OH triazolam by FPIA and EIA with confirmation by GC/MS.

Triazolam is a very short-acting triazolobenzodiazepine with sedative-hypnotic properties. Approximately 2% of an oral dose is excreted unchanged in the urine. The major urinary metabolite is alpha-hydroxytriazolam glucuronide (70% of the dose). The objective of this study was to characterize the reactivity of alpha-hydroxytriazolam in the urine benzodiazepine assay by fluorescence polarization immunoassay (FPIA; Abbott TDx) in comparison with enzyme immunoassay (EIA; Syva EMIT d.a.u. benzodiazepine assay). alpha-OH triazolam at 300 ng/mL gave a response equivalent to the 200-ng/mL nordiazepam Abbott calibrator. In the EMIT assay, alpha-OH triazolam gave a response equivalent to the 300-ng/mL calibrator (Syva) at 100-200 ng/mL. Both immunoassays gave positive results in 9 out of 9 urine specimens collected from individuals receiving triazolam. Confirmation was performed by analyzing for alpha-OH triazolam after enzymatic hydrolysis and formation of a TMS derivative for GC/MS. All urine specimens were positive for alpha-OH triazolam. In conclusion, both the FPIA and EIA immunoassay screening assays are acceptable for detecting the presence of alpha-OH triazolam in the urine of patients receiving therapeutic doses of triazolam.

Urinalysis of alpha-hydroxyalprazolam, alpha-hydroxytriazolam, and other benzodiazepine compounds by GC/EIMS.

This procedure was developed as an overall benzodiazepine confirmation scheme and includes the detection of the most important urinary analytes encountered by clinical toxicology laboratories in North America: alpha-hydroxyalprazolam, alpha-hydroxytriazolam, 2-hydroxyethylflurazepam, oxazepam, temazepam, and lorazepam. Desmethyldiazepam (nordiazepam) was not targeted because it is metabolized to oxazepam. This procedure takes advantage of beta-glucuronidase hydrolysis for analysis of intact benzodiazepine molecules, oxazepam-2H5 as an internal standard, a newly developed extraction solvent, and a silylating moiety that may be more sensitive than trimethylsilyl (-TMS) derivatives, the tertbutyldimethylsilyl (-TBDMS) derivative. For all compounds the extraction efficiency was greater than 90% and the limit of quantitation (LOQ at a S/N of 10) was less than 10 ng/mL. Coefficients of variation for a 200-ng/mL control were less than 5% and less than or equal to 11% for within-run and between-run trials, respectively. Of 13 human specimens screened by EMIT and most with self-reported histories, alpha-hydroxyalprazolam was found in seven (range 49-1264 ng/mL), oxazepam was found in five (72-3897 ng/mL), and lorazepam (476 ng/mL), 2-hydroxyethylflurazepam (2301 ng/mL), and alpha-hydroxytriazolam (106 ng/mL) in one each.