Application of Empore C-8 extraction disks for screening urine in systematic toxicological analysis.

Solid-phase extraction (SPE) by means of disposable columns has become a widely accepted technique for sample pretreatment in toxicology, both for directed analyses and for screening analyses. However, the sample capacity in SPE is usually limited to a few millilitres. Therefore, we have investigated to what extent these problems can be overcome by using Empore extraction disks, consisting of chemically modified C-8 reversed-phase silica, embedded in an inert polytetrafluoroethylene (PTFE) matrix. Human urine was selected as the matrix and dexetimide and mepyramine were initially used as test drugs because these drugs were available in tritiated form. Additional drugs investigated included codeine, hexobarbital, imipramine, methamphetamine, and nitrazepam. In these investigations, the sample capacity for untreated urine was at least 25 mL, and analyte quantities up to 250 micrograms could be retained by these filters. Washing with water/methanol mixtures was successful in removing substantial amounts of endogenous interferences, and methanol proved to be an acceptable eluent. Thus, these disks seem to have interesting potential for toxicological analysis in that sample concentration and cleanup can be achieved at the same time.

Enantiospecific quantification of hexobarbital and its metabolites in biological fluids by gas chromatography/electron capture negative ion chemical ionization mass spectrometry.

A highly sensitive and specific assay based on gas chromatography/electron capture negative ion chemical ionization mass spectrometry has been developed for the analysis of the enantiomers of hexobarbital and its major metabolites in human urine and plasma. S-(+)-(5-2H3)hexobarbital and R-(-)-(5-2H3)hexobarbital were synthesized for clinical studies along with (+/-)-(1,5-2H6)hexobarbital and the deuterated major metabolites for use as internal and reference standards. Hexobarbital enantiomers and their metabolites were analyzed after pentafluorobenzyl and trimethylsilyl derivatization, following solid-phase extraction from plasma and urine. Intense negative ion spectra were observed for all of the derivatives. The base peak in the spectra corresponded to the M-pentafluorobenzyl anion [M-PFB]- except for 1,5-dimethylbarbituric acid, where M-. was the most abundant ion. The applicability of the method was demonstrated by following the plasma concentration-time profiles and urinary excretion in a male extensive metabolizer of mephenytoin who was given a pseudoracemic oral dose of hexobarbital containing equal 50 mg amounts of S-(+)-2(H0)hexobarbital and R-(-)-(2H3)hexobarbital. Marked stereoselective disposition was observed, with the R-(-)-enantiomer being more efficiently metabolized, primarily by alicyclic oxidation and ring cleavage.

Disposition of allylic oxidation pathway metabolites of racemic hexobarbital in the rat.

The pharmacokinetics in blood of the major metabolites of hexobarbital (HB), 3'-hydroxyhexobarbital (OH-HB) and 3'-ketohexobarbital (K-HB) were studied in rats. In addition urinary excretion of OH-HB and K-HB and 1,5-dimethylbarbituric acid (DMBA) was determined. Half-lives of OH-HB and K-HB were slightly longer than that of the parent drug. Urinary recovery of OH-HB, K-HB and DMBA following i.a. administration of OH-HB (75%) was more complete than the recovery following i.a. administration of K-HB (52%). Most probably further metabolism of K-HB takes place. Of K-HB, 41% was excreted renally, and 3.4% of K-HB reverted back to OH-HB. Of OH-HB, about 45% was excreted renally, following p.o. or i.a. administration. Since about 10% of both OH-HB and K-HB was converted to DMBA, it seems that the epoxide-diol pathway as proposed for HB also plays a minor role in the metabolism of OH-HB and K-HB. It is further concluded that measuring allylic pathway oxidation metabolites of HB does not improve the usefulness of HB as a model compound in the assessment of the activity of oxidative drug metabolizing activity.

Selected ion monitoring analysis of pseudoracemic hexobarbital and its major metabolites in blood and urine of rats.

A stereospecific synthesis of N1-(2H3)-labelled R(-)-hexobarbital is described. A sensitive and rapid selected ion monitoring assay procedure for pseudoracemic hexobarbital, consisting of equal amounts of S(+)-hexobarbital (1a) and (2H3)-R(-)-hexobarbital (1b) in 100 microliters blood samples of rats was developed. Both the parent enantiomers in blood and three major metabolites excreted in urine were quantified. An application of the method in rats is described, and the results are compared to previously obtained data of separately administered enantiomers.

Disposition of hexobarbitone in healthy man: kinetics of parent drug and metabolites following oral administration.

1 Hexobarbitone plasma kinetics were determined in six healthy volunteers, who received 500 mg hexobarbitone orally. In addition urinary excretion rate and cumulative excretion were measured of its three major metabolites: 3'-hydroxyhexobarbitone, 3'-ketohexobarbitone and 1,5-dimethylbarbituric acid. 2 The mean plasma elimination half-life of hexobarbitone was 3.7 +/- 0.9 h (n = 6). Assuming complete absorption, the volume of distribution and the metabolic clearance were 81.3 +/- 20.5 1 and 16.4 +/- 2.9 1/h, respectively. The mean maximal plasma concentration was 7.1 +/- 2.1 micrograms/ml and was reached 1.2 +/- 0.4 h after drug administration. 3 3'-Hydroxyhexobarbitone and 3'-ketohexobarbitone, which are products of allylic side-chain oxidation of hexobarbitone, were excreted in 24 h to the extent of 4.7 +/- 1.3 and 32.1 +/- 11.9% of the dose, respectively. In the same period, 1,5-dimethylbarbituric acid, which is the end product of the epoxide-diol pathway, was excreted to 18.0 +/- 7.8% of the dose. The ratio of the sum of 3'-hydroxy- and 3'-ketohexobarbitone vs 1,5-dimethylbarbituric acid excreted varied with time and amounted ultimately in 24 h urine to 2.3 +/- 1.0. 4 The half-lives of 3'-hydroxyhexobarbitone and 1,5-dimethylbarbituric acid, calculated from their renal excretion rate curves, amounted 5.2 +/- 0.9 and 6.6 +/- 1.3 h and were significantly longer than the half-life of hexobarbitone in plasma. The half-life of 3'-ketohexobarbitone was 4.2 +/- 0.8 h. The maximum excretion rate of 1,5-dimethylbarbituric acid was reached at 7.7 +/- 1.0 h after administration of hexobarbitone. 3'-Hydroxy- and 3'-ketohexobarbitone were excreted with a maximal rate at 2.2 +/- 0.8 and 2.8 +/- 0.4 h respectively.

Stereoselective formation of glucuronides in metabolism of hexobarbital enantiomers in vivo: isolation and quantitation of glucuronides in rabbit urine.

An improved column-chromatographic method was described for isolation and purification on preparative scale of a glucuronide from urine of rabbits administered (RS)-hexobarbital. The analytically pure preparation obtained was found to be a mixture of two glucuronides of diastereomeric 3'-hydroxyhexobarbitals. Rates of hydrolysis of the glucuronides were dependent on the enzyme preparations used as well as on the configuration of the substrate. For quantitative determination, the glucuronides were hydrolyzed completely by beta-glucuronidases from either Escherichia coli or abalone entrails under the conditions used. In vivo studies on the metabolism of (R)-(-)- and (S)-(+)-hexobarbital in the rabbit showed that the glucuronides excreted in 24-hr urine accounted for about 30% of the dose of each enantiomer, and that conjugation of the hydroxy isomers with glucuronic acid was so stereoselective that the isomers with S-configuration at the 3'-position were preferentially conjugated. There were almost no differences in the urinary metabolite profile between normal an PB-treated rabbits; however, a noticeable change was observed in recovery of unchanged (S)-hexobarbital after phenobarbital treatment.

Alternative transport pathways of cholephilic 14C-hexobarbital metabolites in rats with experimental hepatitis and cholestasis.

Object of the investigation was to find out whether otherwise cholephilic metabolites are excreted via an alternative pathway into urine in experimental liver disease. Intraduodenal application of 14C-labelled hexobarbital in rats is followed by an immediate biliary excretion of metabolites in the range of 400 microgram/100 g bw/h. Using TLC these metabolites can be separated into a polar fraction (about 80% of total) and a non-polar fraction. Phenobarbital treatment leads to a decrease of the total biliary excretion of metabolites to about 200 microgram/100 g bw/h, the metabolite pattern remaining unchanged. Animals with a mild form of GalN-hepatitis had a moderate reduction of bile flow and a total metabolite output of 40 microgram/100/gbw/h. The metabolite pattern showed a decrease mainly of the polar fraction. In animals with an early stage of ANIT cholestasis a 50% reduction of bile flow was associated with a total metabolite excretion of only 20 microgram/100 g bw/h and polar metabolites were nearly absent. In both types of experimental liver disease in corresponding urine samples otherwise cholephilic metabolites appeared. The results obtained show that clinically moderate stages of experimental liver disease lead to a significantly diminished output especially of polar 14C-hexobarbital-metabolites into the bile, which can, therefore, appear in the urine instead.

[Circadian fluctuations of pharmacokinetic parameters after oral administration of hexobarbital (author's transl)]. / Zirkadiane Schwankungen pharmakokinetischer Parameter nach oraler Gabe von Hexobarbital.

To 4 male and 2 female subjects hexobarbital was applied orally at different times of the day: 2, 10, 18 h. Serum concentrations of hexobarbital were determined by HPLC procedure and the resulting pharmacokinetic parameters in a rotating iterative program. Application at 18 h resulted in a shorter invasion time, a higher maximum concentration and a delayed elimination; in addition, the AUC was elevated in relation to application at 2 or 10 h. In the 2 female subjects a different pattern was observed. The results lead to the assumption that application of hexobarbital is more effective in the evening than in the morning.

The effect of a low-protein diet on some pharmacokinetic parameters of hexobarbital in the rat.

Hexobarbital, given at a dose of 100 mg/kg iv crosses the tissue barriers more rapidly, and is more quickly eliminated from the body of rats kept for a long period of time on a low-protein diet, D-III, than from the control rats.

Pharmacokinetics of hexobarbital in acute hepatitis and after apparent recovery.

The pharmacokinetics of hexobarbital were studied in 13 patients with acute hepatitis. Hexobarbital sodium was administered by zero order intravenous (iv) infusion, and plasma concentrations were determined regularly by gas chromatography. For each patient the data were fitted according to 2-compartment kinetics. The results were compared to those obtained for 14 healthy volunteers. The elimination half-life of hexobarbital was 490 +/- 186 min in the hepatitis patients and 261 +/- 69 min in the control group. Clearance was significantly reduced in the hepatitis group, whereas the volume of distribution at steady state was not significantly altered. For some patients the initial distribution volume was reduced. In 6 patients the experiment with hexobarbital was repeated after apparent recovery from hepatitis as judged by normal transaminase and bilirubin levels. Generally the half-life of hexobarbital was shorter and the clearance value was higher than during the acute illness, but the values had not yet returned to normal. Clinical recovery from liver disease is not accompanied by corresponding recovery of drug-metabolizing capability.