Identification of the diastereomers of pentobarbital N-glucosides excreted in human urine.

A study was undertaken to determine if humans excreted pentobarbital N-glucosides as urinary metabolites following oral administration of pentobarbital. (1'RS,5RS)-1-(beta-D-Glucopyranosyl)pentobarbital ((1'RS,5RS)-PTBG) was isolated from the urine of one subject. The two diastereomers, (1'RS,5R)-PTBG and (1'RS,5S)-PTBG were separated and found to be identical to synthetic standards when compared using HPLC retention times coupled with UV (with and without post-column ionization) and mass spectrometry (HPLC/MS). A HPLC method was developed for detecting and quantifying (1'RS,5R)-PTBG, (1'RS,5S)-PTBG and pentobarbital in urine. Following a single oral dose of sodium pentobarbital to male subjects (n = 6), 1.6-6.2% of the pentobarbital dose was excreted as (1'RS,5S)-PTBG over 60 hours. (1'RS,5R)-PTBG was also detected in one subject and accounted for 0.3% of the pentobarbital dose. Using a modified HPLC system, the four pentobarbital N-glucosides were resolved and analysis of a partially purified pentobarbital N-glucoside extract from one subject indicated that only (1'R,5R)-PTBG and (1'S,5S)-PTBG could be detected as urinary excretion products. These results indicate that the side chain chirality of pentobarbital may influence the observed enantioselectivity for the formation and/or urinary excretion of the pentobarbital N-glucosides.

Identification of phenobarbital N-glucosides as urinary metabolites of phenobarbital in mice.

Previously, the N-glucosylation of phenobarbital had been observed only in humans. The results of a species screen (mouse, rat, guinea pig, rabbit, cat, dog, pig, and monkey) found that only mice excreted the N-glucosides of phenobarbital in urine after ip administration of sodium phenobarbital. The major diastereomer excreted by the mouse had the R configuration at the C-5 position of the barbiturate ring. The N-glucoside metabolites accounted for a small percentage of the dose (approximately 0.5%). Following ip dosing of the mouse with the phenobarbital N-glucosides, free phenobarbital could be detected in the urine. Upon ip or intercerebroventricular (icv) injection of the phenobarbital N-glucosides, minimal CNS activity was observed in the mouse.

Barbital N-glucoside is not detected as a urinary excretion product of barbital in humans.

A study was undertaken to determine if humans excreted barbital N-glucoside as a urinary metabolite following oral administration of barbital. A liquid chromatography method using gradient elution was developed for detecting and quantifying barbital N-glucoside and barbital in urine. Following a single oral dose of barbital to male caucasian and oriental subjects that had previously been shown to excrete amobarbital and phenobarbital N-glucosides, no barbital N-glucoside conjugate was observed in the urine. This result indicates that N-glucosylation of barbiturates is not a general pathway for the biodisposition of barbiturates in man.

Stereochemical characterization of the diastereomers of the phenobarbital N-beta-D-glucose conjugate excreted in human urine.

The absolute configuration of the N-beta-D-glucoside metabolites of phenobarbital was determined by methylation of the diastereomers to make mephobarbital N-beta-D-glucosides, followed by oxidative removal of glucose to give the optical isomers of mephobarbital. Following a single oral dose of phenobarbital to two male subjects, both phenobarbital N-beta-D-glucosides were excreted in the urine. The absolute configuration (C-5 position) of the major phenobarbital N-beta-D-glucoside excreted in the urine was the S form. A pronounced stereoselective formation and/or urinary excretion occurs for the N-glucoside conjugates of phenobarbital in humans.

LC determination of the diastereomers of 1-(beta-D-glucopyranosyl)phenobarbital in human urine.

The "product enantioselectivity" associated with the urinary excretion of the phenobarbital N-glucoside conjugates has not been determined previously. A liquid chromatography method using gradient elution was developed for quantifying both phenobarbital N-glucoside conjugates, phenobarbital, and p-hydroxyphenobarbital. Following a single oral dose of phenobarbital to male Caucasian and Oriental subjects, both phenobarbital N-glucoside conjugates were observed in the urine. In seven subjects, 3.3-10.6% of the phenobarbital dose was detected as a single phenobarbital N-glucoside (S configuration at the C-5 position of the barbiturate ring). The other phenobarbital N-glucoside diastereomer accounted for less than 1.5% of the phenobarbital dose. The urinary excretion of the major phenobarbital N-glucoside diastereomer paralleled the urinary excretion of phenobarbital and was comparable in both Caucasian and Oriental subjects. These results indicate a pronounced selectivity for the formation and/or urinary excretion of the phenobarbital N-glucosides.

Synthesis of N-beta-D-glucopyranosyl derivatives of barbital, phenobarbital, metharbital, and mephobarbital.

The condensation of per(trimethyl)silylbarbital and -phenobarbital with 1,2,3,4,6-penta-O-acetyl-beta-D-glucopyranose in the presence of stannic chloride in dichloroethane gave moderate yields of the beta-coupled barbiturate N-D-glucopyranosyl derivatives. Reaction of metharbital and mephobarbital under the same conditions was unsuccessful. The homologous N-methylglucosides were prepared by reaction of the barbital and phenobarbital N-glucosyl derivatives with diazomethane. The diastereomers of the phenobarbital and mephobarbital derivatives were resolved by use of C-18 reverse-phase h.p.l.c. 1H- and 13C-n.m.r. spectroscopy, and thermospray 1.c.-m.s. proved to be the most useful methods for characterizing the barbiturate glucosides.