Determination of urinary 18β-glycyrrhetinic acid by gas chromatography and its clinical application in man

A sensitive and quantitative gas chromatographic assay for the determination of 18β-glycyrrhetinic acid (18β-GA), the main metabolite of glycyrrhizin after oral licorice consumption in human urine, has been developed and validated. For the extraction of 18β-GA from urine two Sep-Pak C₁₈ extractions, hydrolysis with Helix pomatia and three liquid–liquid extractions were performed, using 18α-glycyrrhetinic acid (18α-GA) as internal standard. Both 18β-GA and internal standard were converted into their pentafluorobenzyl-ester/trimethylsilyl-ether derivatives and detected by flame ionization detection using a WCOT-fused-silica capillary column. Good quality control data were obtained in precision and accuracy tests. The detection limit of the gas chromatographic method was 10 μg/l with a urine volume of 10 ml. A detection limit of 3 μg/l was obtained by performing GC–MS. The GC method was used to monitor the urinary excretion of 18β-GA after licorice consumption by two healthy volunteers and a patient suspected of licorice abuse. Furthermore, it was shown that this GC assay enables to detect other metabolites related to licorice consumption.     

Studies on the metabolism of 2,4′-isobutylphenylpropionic acid (ibuprofen) by gas chromatography and mass spectrometry : Dialysis fluid, a convenient medium for studies on drug metabolism

2,4′-Isobutylphenylpropionic acid (ibuprofen) has previously been demonstrated to yield four urinary metabolites, formed by ω1-, ω2- and ω3-hydroxylation and by a further oxidation of the primary alcohol of the ω1-hydroxylated metabolite to a carboxyl group. By synthesis and gas chromatography—mass spectrometry the suggested structure of the ω3-hydroxylated metabolite was verified in the present study. Moreover, a new metabolite, 2,4′-carboxyphenylpropionic acid, was demonstrated to be present in substantial amounts in dialysis fluid from a nephrectomized patient. In such patients ingested drugs cannot be excreted in the urine, but are metabolized to end products. Thus, dialysis fluid may be a convenient medium for studies on drug metabolism.     

In vivo formation of β-oxidized metabolites of leukotriene E4 in the rat

Intraperitoneal administration of [³H]-leukotriene E₄ in the rat resulted in the appearance of radiolabel in urine and feces. Separation of polar urinary metabolites and chromatographic comparison of synthetic metabolites indicated the in vivo formation of ω-oxidized metabolites of LTE₄ with sequential β-oxidation. Futhermore, the metabolite identified as 16-carboxy-17,18,19,20-tetranor-14,15-dihydro-N-acetyl-LTE₄ substantiates the biochemical patheway of β-oxidation in vivo involving the 2,4-dienoyl CoA reductase as an integral step. These results substantiate β-oxidation of sulfidopeptide leukotrienes in vivo and these metabolites account for some of the major urinary metabolites of this class of lipid mediator.     

Determination of pethidine and its major metabolites in human urine by gas chromatography

Procedures based on gas chromatography were established to determine pethidine and its major metabolites in human urine. The chromatographic system consisted of a glass column packed with 3% (w/w) SP2250 on Chromosorb W (80–100 mesh) linked to a nitrogen—phosphorus detector. Diethyl ether was used as the extraction solvent. Pethidinic and norpethidinic acids, and their conjugated metabolites (after β-glucuronidase treatment) were determined after conversion into pethidine and norpethidine by acid-catalysed esterification. The retention times of pethidine, norpethidine and chlorpheniramine (internal standard) were 3.3, 4.5 and 7.5 min, respectively. The amount of unchanged drugs and metabolites excreted varied considerably among the subjects. The mean 24-h urinary recoveries in eight patients of pethidine, norpethidine, pethidinic acid, norpethidinic acid, and the glucuronides of pethidinic and norpethidinic acids were 6.62 ± 5.05, 4.33 ± 1.19, 18.9 ± 6.29, 9.10 ± 4.26, 15.1 ± 3.02 and 7.57 ± 2.28%, respectively. This indicates that the major metyabolic pathways of pethidine in the eight patients were hydrolysis followed by conjugation. Over 60% of the dose was accounted for in 24 h after intramuscular administration of 1 mg/kg pethidine.     

High-performance chromatographic assay for the sulphoxide metabolite of 2′-deoxy-3′-thiacytidine in human urine

A high-performance liquid chromatographic method is described for the determination in human urine of GI138870X, the sulphoxide metabolite of a novel dideoxynucleoside analogue, 2′-deoxy-3′-thiacytidine (lamivudine). GI138870X was extracted from human urine using Empore SDB RPS solid-phase extraction disks prior to reversed-phase chromatography with UV detection. The method has shown to be valid over the concentration range 0.5–100 μg/ml using a 0.5-ml sample volume.     

Metabolic studies on retinoic acid in the rat

The nature of metabolites in the urine arising from differentially labelled retinoic acid was investigated after injection of physiological doses into retinol-deficient rats. Distribution of radioactivity after partition of urine into ether-soluble, acidic and water-soluble fractions revealed that there were at least six metabolites in urine. Of these, the major metabolite(s) was one lacking both C-14 and C-15 of retinoic acid. Enzymic or alkaline hydrolysis of acidic and water-soluble fractions did not release any retinoic acid, thus indicating that retinoyl beta-glucuronide was not present in urine in significant amounts.     

The relative amounts and identification of some 2,4-dichlorophenoxyacetic Acid metabolites isolated from soybean cotyledon callus cultures

Soybean (Glycine max L.) cotyledon callus grown on radioactive 2,4-dichlorophenoxyacetic acid (2,4-D-1-¹⁴C) as an auxin produced 2,4-D metabolites, which qualitatively and quantitatively changed with time. Water soluble fractions from the tissue exhibited a steady increase in radioactivity during the course of 24 days. Following β-glucosidase treatment, at least eight aglycones were obtained from the water soluble fraction of the tissue after 8 days. The metabolite, 4-hydroxy-2,5-dichlorophenoxyacetic acid was the most abundant aglycone during the entire 32 day growth period while 4-hydroxy-2,3-dichlorophenoxyacetic acid was detected as a minor metabolite. Radioactivity in the ether soluble acidic fractions reached a maximum of 82% of the total in the tissue after 2 days. The level then decreased to 44% by the end of 24 days. A total of seven ether soluble components were detected. In addition to 2,4-D glutamic acid, which was detected in high amounts after 24 hours, 2,4-D aspartic acid was found to be the most abundant ether soluble metabolite after longer time periods. Mass spectral data and a fragmentation pattern are presented for 2,4-D aspartic acid.     

Analysis of some metabolites of organic solvents in urine by high-performance liquid chromatography with β-cyclodextrin

Chromatographic separation of the metabolites derived from toluene, ethylbenzene, styrene and xylene was carried out on untreated urine samples from factory workers. The elution sequence was as follows: phenylglyoxilic acid, 3-hydroxy-2-butanone, hippuric acid, o-methylhippuric acid, p-methylhippuric acid, m-methylhippuric acid, p-cresol, m-cresol and o-cresol. The stability constants (K_G) of cresol and methylhippuric acid derivatives were evaluated. The capacity factor (k′), selectivity factor (α) and resolution (R_s) are described with a variety of mobile phases containing β-cyclodextrin (β-CD). The optimum concentration ratio of ethanol–water–acetic acid–β-CD was determined to be 20:80:0.3:1.4%. Under these conditions, k′ values of the five metabolites were 2<k′<6, and all α values were greater than 1.5. Simultaneous determinations of the metabolites were carried out in real urine samples from factory workers using the standard addition method. Validation of the method and the detection limit are described under the optimum conditions attained in this experiment.     

Determination of the anti-platelet-activating factor BN-50727 and metabolites in human urine by high-performance liquid chromatography using solid-phase extraction

A sensitive and selective HPLC solid-phase extraction procedure was developed for the determination of platelet-activating factor antagonist BN-50727 and its metabolites in human urine. The procedure consisted in a double solid-phase extraction of the urine samples on cyanopropyl and silica cartridges, followed by an automated solid-phase extraction of the drug and metabolites on CBA cartridges and posterior elution on-line to the chromatographic system for its separation. The method allowed quantitation in the concentration range 10–2400 ng/ml urine for both BN-50727 and the main metabolite, the O-demethylated BN-50727 product. The limit of quantitation for both compounds was 10 ng/ml. The inter-assay precision of the method, expressed as relative standard deviation, ranged from 1.9 to 4.5% for BN-50727 and from 2.5 to 9.0% for the metabolite. The accuracy, expressed as relative error, ranged from −2.4 to 4.2% and from 0.2 to 6.2%, respectively. This paper describes the validation of the analytical methodology for the determination of BN-50727 in human urine and also for its metabolites. The method has been used to follow the time course of BN-50727 and its metabolites in human urine after single-dose administration.     

Determination of the urinary aglycone metabolites of vitamin K by HPLC with redox-mode electrochemical detection

We describe a method for the determination of the two major urinary metabolites of vitamin K as the methyl esters of their aglycone structures, 2-methyl-3-(3'-3'-carboxymethylpropyl)-1,4-naphthoquinone (5C-aglycone) and 2-methyl-3-(5'-carboxy-3'-methyl-2'-pentenyl)-1,4-naphthoquinone (7C-aglycone), by HPLC with electrochemical detection (ECD) in the redox mode. Urinary salts were removed by reversed-phase (C18) solid-phase extraction (SPE), and the predominantly conjugated vitamin K metabolites were hydrolyzed with methanolic HCl. The resulting carboxylic acid aglycones were quantitatively methylated with diazomethane and fractionated by normal-phase (silica) SPE. Final analysis was by reversed-phase (C18) HPLC with a methanol-aqueous mobile phase. Metabolites were detected by amperometric, oxidative ECD of their quinol forms, which were generated by postcolumn coulometric reduction at an upstream electrode. The assay gave excellent linearity (typically, r2 > or = 0.999) and high sensitivity with an on-column detection limit of < 3.5 fmol (< 1 pg). The interassay precision was typically 10%. Metabolite recovery was compared with that of an internal standard [2-methyl-3-(7'-carboxy-heptyl)-1,4-naphthoquinone] added to urine samples just before analysis. Using this methodology, we confirmed that the 5C- and 7C-aglycones were major catabolites of both phylloquinone (vitamin K1) and menaquinones (vitamin K2) in humans. We propose that the measurement of urinary vitamin K metabolite excretion is a candidate noninvasive marker of total vitamin K status.     

Identification of new urinary metabolites of trimeprazine in rats by gas chromatography—mass spectrometry

The metabolites of trimeprazine were identified in urine of rats by gas chromatography—mass spectrometry. After the oral administration of trimeprazine, the urinary metabolites were extracted with diethyl ether before or after hydrolysis with β-glucuronidase. The identified metabolites were N-demethyltrimeprazine, 3-hydroxytrimeprazine, N-demethyl-3-hydroxytrimeprazine and trimeprazine sulphoxide.     

Metabolism of testosterone sulfate in the rat: analysis of biliary metabolites.

Following intraperitoneal injection of a mixture of testosterone-7-3-H-17-sulfate and testosterone-4-14-C into male and female rats with bile fistulas, biliary metabolites were separated and purified by a combination of column chromatography, enzymic hydrolysis or solvolysis of the conjugate fractions and identification of the liberated aglycones. The injected steroids were extensively metabolized and excreted predominantly in the bile. The major portion of the 3H was excreted in the disulfate fraction in both sexes. Solvolysis of the disulfate revealed the sex-specific aglycone pattern: 5alpha-Androstane-3beta,17beta-diol was the major metabolite in the male rat, whereas 5alpha-androstane-3alpha,17beta-diol and polar steroids were found in the female. In marked contrast, testosterone was metabolized in a different way than testosterone sulfate. 14-C radioactivity was distributed in monoglucosiduronate, monosulfate, and diconjugate fractions. Analysis of the aglycones showed that polar steroids were the main metabolites in the male. In the female, testosterone was metabolized to polar steroids, androsterone, and 5alpha-androstane-3alpha,17beta-diol.     

Metabolic products of arachidonic acid in rats

The pattern of eicosanoid metabolites appearing in urine and feces following oral administration of radioactive arachidonic acid was investigated using rats deficient in essential fatty acids. About 70–80% of the radioactivity in the urine during the first day after feeding was adsorbed to XAD-2 resin and he represented eicosanoid metabolites, whereas the rest of the radioactivity was mainly ³H₂O. The eicosanoid metabolites were fractioned into different polarity classes using reverse phase Sep-Pak C₁₈ cartridges. Gas chromatographic analysis of the urinary metabolites following their derivatization into methyl ester-methoxime- -butyl-dimethylsilyl ethers revealed that nearly one-half of the metabolites had ECL values less than 22 and represented metabolites more oxidized than commonly described. Only 30% of the metabolites had ECL values between 26 to 32, corresponding to the values for the metabolites that originate from exogenously infused prostaglandins. A large portion of the eicosanoid metabolites was also excreted with the feces. The isotropic patterns from the reverse phase chromatography indicated that many of the fecal metabolites may be similar to those in urine although some metabolites in feces were not present in urine. Based on the specific radioactivity of the administered arachidonic acid, it appeared that at least 6 to 8 mg of eicosanoid metabolites were excreted through urine and feces within 24 hrs following an oral bolus of 60 mg arachidonic acid. The rapid increase and subsequent decrease in eicosanoid metabolite excretion after oral administration of arachidonate indicates that the dietary intake of polyunsaturated fatty acids may have a more rapid effect upon the endogenous production of eicosanoids than is generally recognized.     

In vitro and in vivo metabolism of myristicin in the rat

Myristicin [5-allyl-1-methoxy-2,3-(methylenedioxy)benzene] is a flavoring plant constituent and has been known to produce significant psychopharmacological responses as well as insecticidal activity. From in vitro and in vivo metabolism of myristicin, the two metabolites 5-allyl-1-methoxy-2,3-dihydroxybenzene and 1′-hydroxymyristicin were identified using GC–MS after derivatization of sample matrices with a mixture of BSTFA–TMCS. Those metabolites from in vitro study were also confirmed in urine after an oral administration of myrisitcin to rats, and enzymatic hydrolysis of urine suggested that these metabolites were excreted as conjugated forms as well.     

The levels of main urinary metabolite of prostaglandin F1α and F2α in human subjects measured by radioimmunoassay

Radioimmunoassay technique for measuring 5α,7α-dihydroxy-11-keto-tetranorprosta-1,16-dioic acid, the main urinary metabolite of PGF₁α and PGF₂α (PGF₂α-MUM), was further improved.It was postulated based on some experimental data that the PGF₂α-MUM exists in the urine mostly as dioic acid form, not as δ-lactone formThe daily excretion of PGF₂α-MUM in men ranged from 14.43 μg to 36.14 μg and in women from 5.21 μg to 14.25 μg.     

A novel assay of glucuronidation of C- and N-hydroxylated metabolites of the carcinogen N-2-fluorenylacetamide

A method for the assay of glucuronidation of C- and N-hydroxylated metabolites of the carcinogen N-2-fluorenylacetamide is described. The method employs UDP-[U-14C ))glucuronic acid and Baker C18 extraction columns for separation of the glucuronides from their aglycones and from the glucuronic acid. The 14C-labeled glucuronides, generated by rat liver microsomes, are eluted from the columns with 30% (v/v) methanol after prewashing the columns and elution of the radioactivity of 14C-glucuronic acid with 1 mM ammonium acetate, pH 6.9. The radioactivity of the eluates is measured by scintillation counting. The method is modified for assays of glucuronidation of alpha-naphthol and p-nitrophenol in that 1 mM phosphoric acid is used instead of 1 mM ammonium acetate, and the method is potentially adaptable to other aglycones. By monitoring radioactivity or uv absorbance of the column eluates, it is shown that all aglycones, except p-nitrophenol, are retained on the columns during elution of their glucuronides with 30% (v/v) methanol and are eluted only when absolute methanol is used. The identity of the glucuronides is shown by their response to hydrolysis by beta-glucuronidase in the presence and absence of D-saccharic acid-1,4-lactone and, in some instances, by chromatographic and spectral analyses of the released aglycones.     

Interconversions of aglycone and host-selective toxin from Helminthosporium sacchari

Helminthosporium sacchari, a fungus that causes disease in sugarcane, produces oligosaccharide-sesquiterpene toxins (HS toxins A, B, and C) that are required for infection and disease development. Two free sesquiterpenes were isolated from mycelium but not from culture fluids of the fungus. One sesquiterpene was identified by HPLC and mass spectrometry as an aglycone of HS toxin C and could be obtained by enzymatic hydrolysis of this toxin. The other sesquiterpene appeared to be the 2-keto form of the first compound. The aglycone from toxin C hydrolysis was labelled with tritium by successive treatments with active manganese dioxide, sodium boro[³H]hydride, and lithium aluminium hydride. The labelled compound was fed to cultures of H. sacchari, radioactivity was incorporated into HS toxin C and into lower molecular weight homologues. The results suggest a metabolic route (aglycone → metabolite Y, → HS toxin → metabolite X) for the biosynthesis of HS toxin; metabolites X and Y are lower molecular weight homologues of the toxin.     

Metabolism and pharmacokinetic studies of propionylpromazine in horses

The propionylpromazine concentrations in plasma after intramuscular administration to horses were determined using gas chromatography with nitrogen-phosphorus detection. After hydrolysis by β-glucuronidase/arylsulphatase, the parent drug and three metabolites were detected in urine. The metabolites were identified as 2-(1-hydroxypropyl)promazine, 2-(1-propenyl)promazine and 7-hydroxypropionylpromazine by gas chromatography-mass spectrometry. No N-demethylated or sulphoxidated metabolites of propionylpromazine were observed in the horse urine.     

Determination of oxpentifylline and a metabolite, 1-(5′-hydroxyhexyl)-3,7-dimethylxanthine, by gas—liquid chromatography using a nitrogen-selective detector

A gas chromatographic method for the determination of oxpentifylline and a metabolite, 1-(5′-hydroxyhexyl)-3,7-dimethylxanthine is described. Oxpentifylline, metabolite and internal standard are extracted from basified plasma into dichloromethane, then the metabolite and internal standard are converted to their O-trifluoroacetates. Analysis by gas—liquid chromatography using a nitrogen-selective detector allows quantification of oxpentifylline and 1-(5′-hydroxyhexyl)-3,7-dimethylxanthine down to levels of 3 ng/ml and 3–10 ng/ml, respectively. The assay had been applied to plasma samples from volunteers after both intravenous and oral administration of oxpentifylline. The need to separate plasma from erythrocytes immediately after venipuncture sampling to prevent further metabolism of oxpentifylline is emphasized.     

Determination of the major metabolite of phentolamine in human plasma and urine by high-performance liquid chromatography

A reversed-phase, high-performance liquid chromatographic method using UV detection is described for the assay of the major metabolite of phentolamine in plasma and urine before or after enzymatic hydrolysis. Plasma is deproteinized with methanol. The sensitivity limit is 200 ng/ml using 150-μl samples. Urine is either diluted with water or purified after enzymatic hydrolysis. Concentrations down to 2–3 μg/ml could be quantified with acceptable precision. This method was applied to plasma and urine samples from subjects given phentolamine.