Determination of metyrapone and the enantiomers of its chiral metabolite metyrapol in human plasma and urine using coupled achiral-chiral liquid chromatography

A coupled achiral-chiral liquid chromatographic assay has been developed to determine the concentrations of metyrapone and the enantiomers of its chiral metabolite metyrapol in plasma and urine. The chromatographic system consisted of a silica precolumn (75 × 4.6 mm I.D.) coupled in-line to a 250 × 4.6 mm I.D. column containing cellulose tris(4-methylbenzoate) coated on silica gel (Chiralcel OJ-CSP). When plasma samples were analyzed, the mobile phase was hexane-ethanol (92:8, v/v) modified with 0.1% diethylamine and when urine samples were analyzed the mobile phase was hexane-ethanol (94:6, v/v) modified with 0.2% diethylamine. Under these chromatographic conditions the chromatographic retentions [expressed as capacity factors (k′)] for metyrapone were k′ = 2.35 (plasma) and 2.52 (urine); for (−)-metyrapol k′ = 4.22 (plasma) and 4.62 (urine); for (+)-metyrapone k′ = 5.16 (plasma) and 5.86 (urine); enantioselectivities (α) were 1.09 (plasma) and 1.13 (urine). The assay has been validated for use in metabolic studies. The analyses of plasma and urine samples from one subject following oral administration of 750 mg of metyrapone indicated that the enzymatic reduction of myterapone by aldo-keto reductase was enantiospecific.     

Determination of the enantiomers of zopiclone and its two chiral metabolites in urine using an automated coupled achiral—chiral chromatographic system

The enantiomers of zopiclone and its two chiral N-desmethyl and N-oxide metabolites were determined in urine using a coupled achiral—chiral liquid chromatographic method. After liquid—liquid extraction, zopiclone and its two metabolites were quantified on a cyanopropyl column. After fluorimetric detection on the achiral system, the eluent was switched through a silica precolumn in order to trap and concentrate the analytes. Each fraction was then backflushed separately onto a carbamate cellulose chiral stationary phase in order to determine the enantiomeric ratios. The coupled system was automated with an autosampler and a switching valve programmed by an integrator. The method was validated, and a first trial was performed on urine samples of a volunteer treated with 15 mg of racemic zopiclone.     

Determination of salbutamol enantiomers in human plasma and urine by chiral high-performance liquid chromatography

Enantiomers of salbutamol were directly separated (R_s=1.16) and quantitated at therapeutic concentrations after solid-phase extraction from human plasma and urine by normal-phase high-performance liquid chromatography on a chiral column with fluorescence detection. The assay was linear for each enantiomer between 1.25 and 500 ng ml⁻¹ and had a minimum limit of detection of 250 pg ml⁻¹. A 3-ml plasma or 1-ml urine sample was required for quantitation at therapeutic doses. Inter-day variation was 50% for S-(+)- and 6.5% for R-(−)-salbutamol. The assay was used to compare enantioselective disposition after single doses of racemate by the intravenous, oral and rectal routes.     

Determination of esmolol and metabolite enantiomers within human plasma using chiral column chromatography

A high performance liquid chromatography–tandem mass spectrometry (LC–MS/MS) method has been developed for the simultaneous determination of each of esmolol's enantiomers at the 25–1000 ng/ml concentrations observed in human plasma upon intravenous administration of this rapidly metabolized beta-adrenergic receptor blocking agent. Alternatively, a high performance liquid chromatography (HPLC) UV detection method has been developed for the simultaneous determination of each of the enantiomers for esmolol's metabolite which, in turn, achieve 2.5–50 μg/ml concentrations in human plasma. Utilizing chiral columns, these methods do not require a precolumn asymmetric derivatization step. Linearity in all cases was >0.99. Precision and accuracy at all but the lowest concentrations were within ±6% for the esmolol enantiomers and within ±2.5% for the esmolol metabolite enantiomers. These values should be suitable for performing thorough pharmacokinetic studies for all of the stereoisomers of this prototypical soft drug and its corresponding metabolite.     

Determination of the enantiomers of metoprolol and its major acidic metabolite in human urine by high-performance liquid chromatography with fluorescence detection

Enantiomers of metoprolol and its acidic metabolite H 117/04 were determined in human urine by high-performance liquid chromatography (HPLC) with fluorometric detection after chiral derivatization. The carboxyl functional group of the major metabolite was blocked by esterification after solid-phase extraction, which helped to quantitate this compound from interfering substances. The assay method was validated. The recovery of (−)- and (+)-metoprolol from urine was 86.3–90.5%; and the recovery of the (−)- and (+)-acidic metabolite H 117/04 from urine was 74.4–83.9% at different concentrations.     

Analysis of the enantiomers of citalopram and its demethylated metabolites using chiral liquid chromatography

A procedure using a chirobiotic V column is presented which allows separation of the enantiomers of citalopram and its two N-demethylated metabolites, and of the internal standard, alprenolol, in human plasma. Citalopram, demethylcitalopram and didemethylcitalopram, as well as the internal standard, were recovered from plasma by liquid–liquid extraction. The limits of quantification were found to be 5 ng/ml for each enantiomer of citalopram and demethylcitalopram, and 7.5 ng/ml for each enantiomer of didemethylcitalopram. Inter- and intra-day coefficients of variation varied from 2.4% to 8.6% for S- and R-citalopram, from 2.9% to 7.4% for S- and R-demethylcitalopram, and from 5.6% to 12.4% for S- and R-didemethylcitalopram. No interference was observed from endogenous compounds following the extraction of plasma samples from 10 different patients treated with citalopram. This method allows accurate quantification for each enantiomer and is, therefore, well suited for pharmacokinetic and drug interaction investigations. The presented method replaces a previously described highly sensitive and selective high-performance liquid chromatography procedure using an acetylated β-cyclobond column which, because of manufactural problems, is no longer usable for the separation of the enantiomers of citalopram and its demethylated metabolites.     

Determination of nicotine and its main metabolites in urine by high-performance liquid chromatography

Nicotine and its main metabolites (cotinine, trans-3'-hydroxycotinine, trans-3'-hydroxycotinine glucuronide, nicotine-1'-N-oxide and 3-pyridylcarbinol) were analysed in urine after liquid—liquid extraction by high-performance liquid chromatography using norephedrine as internal standard, ultraviolet detection at 260 nm and scanning ultraviolet spectra with a photodiode-array detector. The conjugated trans-3'-hydroxycotinine was determined after enzymatic hydrolysis. Specific determination of 3-pyridylcarbinol was also carried out. Owing to its good selectivity, sensitivity and reproducibility, the method was applied to the analysis of urine samples from smokers and non-smokers. The results obtained suggest that the urinary markers used to assess active smoking or exposure to environmental tobacco smoke must be not only nicotine and cotinine, but also their main free and conjugated metabolites.     

Determination of methotrexate and its main metabolite 7-hydroxymethotrexate in human urine by high-performance liquid chromatography with normal solid-phase extraction

A practical and sensitive high-performance liquid chromatographic method using normal solid-phase extraction has been developed for the determination of methotrexate (MTX) and its main metabolite 7-hydroxymethotrexate (7-OH-MTX) in human urine. A urine specimen followed by the addition of pH 5.0 acetate buffer was purified by solid-phase extraction on a Sep-Pak silica cartridge. The analyte was chromatographed on a reversed-phase Inertsil ODS-2 column using phosphate buffer-acetonitrile at pH 5.3 as the mobile phase, and the effluent from the column was monitored at 303 nm. A good linear relationship between peak height and concentration was found for both of MTX and 7-OH-MTX in the range 5 to 1000 ng/ml of human urine. The inter-day coefficients of variation for the assay (n=5) were 8.8% (5 ng/ml), 3.4% (50 ng/ml) and 2.0% (500 ng/ml) for MTX, and 7.2, 2.7 and 2.3% for 7-OH-MTX in urine, respectively. The present method should prove useful for the evaluation of urinary drug excretion in patients undergoing MTX low-dose therapy.     

Determination of zopiclone enantiomers in plasma by liquid chromatography using a chiral cellulose carbamate column

The enantiomers of zopiclone were determined in human plasma using a sequential achiral—chiral liquid chromatographic method. Zopiclone was separated from the biological matrix and quantified on an achiral silica column. The limit of detection was 5 ng/ml. The eluent fraction containing zopiclone was collected, evaporated, reconstituted with the mobile phase and injected onto a chiral cellulose carbamate column where the enantiomeric ratio was calculated. This validated method, applied to a pilot study, suggests that pharmacokinetics of zopiclone is stereoselective.     

Solid-phase extraction–high-perfomance liquid chromatography determination of verapamil and norverapamil enantiomers in urine

A simple, rapid, sensitive and selective method has been developed for the stereospecific determination of verapamil and its metabolite, norverapamil in urine. For sample preparation we utilized a membrane-based solid-phase extraction (SPE) disk consisting of a thin, particle-loaded membrane inserted in a plastic syringe-like barrel. The particles, which may be C₈ or C₁₈ bonded phase (C₈ in this work), are embedded within a matrix of PTFE (Teflon) fibrils. Overall analyte recoveries were above 85%, even at low concentration of 3.0 ng/ml with reproducibilities (C.V. values) below 13.1%. This method of extraction has the advantage of speed and considerable reduction in solvent volumes compared to conventional SPE and solvent extraction. The separation of all the enantiomers was achieved using a single chiral stationary phase column, the cellulose-based reversed-phase, Chiralcel OD-R. Analyte concentrations of less than 3.0 ng/ml could be quantitated with C.V. values below 14%. Calibration curves were linear in the range 2.5–300 ng/ml. Intra-day and inter-day reproducibilities were 10.5–14.2% at 3 ng/ml, 4.8–9.3% at 138.5 ng/ml and 7.8–10.1% at 280 ng/ml level, respectively, for all the enantiomers.     

Determination of acyclovir and its metabolite 9-carboxymethoxymethylguanine in serum and urine using solid-phase extraction and high-performance liquid chromatography

A reversed-phase ion-pair high-performance liquid chromatography method for the determination of acyclovir and its metabolite 9-carboxymethoxymethylguanine is described. The samples are purified by reversed-phase solid-phase extraction. The components are separated on a C₁₈ column with a mobile phase containing 18% acetonitrile, 5 mM dodecyl sulphate and 30 mM phosphate buffer, pH 2.1, and measured by fluorescence detection using an excitation wavelength of 285 nm and an emission wavelenght of 380 nm. Detection limits are 0.12 μM (plasma)) and 0.60 μM (urine) for acyclovir, and 0.26 μM (plasma) and 1.3 μM (urine) for metabolite. Correlation coefficients that were better than 0.998 were obtained normally. This analytical method, which enables simultaneous measurement of parent compound and metabolite, has been used in kinetics studies and for therapeutic drug monitoring in different patient groups with variable degrees of renal dysfunction.     

Determination of pyrazinamide and its main metabolites in rat urine by high-performance liquid chromatography

A new high-performance liquid chromatograhic procedure for simultaneous determination of pyrazinamide (PZA) and its three metabolites 5-hydroxypyrazinamide (5-OH-PZA), pyrazinoic acid (PA), and 5-hydroxypyrazinoic acid (5-OH-PA), in rat urine was developed. 5-OH-PZA and 5-OH-PA standards were obtained by enzymatic synthesis (xanthine oxidase) and checked by HPLC and GC–MS. Chromatographic separation was achieved in 0.01 M KH₂PO₄ (pH 5.2), circulating at 0.9 ml/min, on a C₁₈ silica column, at 22°C. The limits of detection were 300 μg/l for PZA, 125 μg/l for PA, 90 μg/l for 5-OH-PZA and 70 μg/l for 5-OH-PA. Good linearity (r²>0.99) was observed within the calibration ranges studied: 0.375–7.50 mg/l for PZA, 0.416–3.33 mg/l for PA, 0.830–6.64 mg/l for 5-OH-PZA and 2.83–22.6 mg/l for 5-OHPA. Accuracy was always lower than ±10.8%. Precision was in the range 0.33–5.7%. The method will constitute a useful tool for studies on the influence of drug interactions in tuberculosis treatment.     

Determination of pindolol enantiomers in human plasma and urine by simple liquid–liquid extraction and high-performance liquid chromatography

A simple method for the measurement of pindolol enantiomers by HPLC is presented. Alkalinized serum or urine is extracted with ethyl acetate and the residue remaining after evaporation of the organic layer is then derivatised with (S)-(−)-α-methylbenzyl isocyanate. The diastereoisomers of derivatised pindolol and metoprolol (internal standard) are separated by high-performance liquid chromatography (HPLC) using a C₁₈ silica column and detected using fluorescence (excitation λ: 215 nm, emission λ: 320 nm). The assay displays reproducible linearity for pindolol enantiomers with a correlation coefficient of r²≥0.998 over the concentration range 8–100 ng ml⁻¹ for plasma and 0.1–2.5 μg ml⁻¹ for urine. The coefficient of variation for accuracy and precision of the quality control samples for both plasma and urine are consistently <10%. Assay parameters are similar to those of previously published assays for pindolol enantiomers, however this assay is significantly easier and cheaper to run. Clinically relevant concentrations of each pindolol enantiomer can readily be measured.     

Enantioselective determination of metoprolol acidic metabolite in plasma and urine using liquid chromatography chiral columns: applications to pharmacokinetics

Enantioselective separations on chiral stationary phases with or without derivatization were developed and compared for the HPLC analysis of (+)-(R)- and (-)-(S)-metoprolol acidic metabolite in human plasma and urine. The enantiomers were analysed in plasma and urine without derivatization on a Chiralcel OD-R column, and in urine after derivatization using methanol in acidic medium on a Chiralcel OD-H column. The quantitation limits were 17 ng of each enantiomer/ml plasma and 0.5 microgram of each enantiomer/ml urine using both methods. The confident limits show that the methods are compatible with pharmacokinetic investigations of the enantioselective metabolism of metoprolol. The methods were employed in a metabolism study of racemic metoprolol administered to a patient phenotyped as an extensive metabolizer of debrisoquine. The enantiomeric ratio (+)-(R)/(-)-(S)-acid metabolite was 1.1 for plasma and 1.2 for urine. Clearances were 0.41 and 0.25 l/h/kg, respectively, for the (+)-(R)- and (-)-(S)-enantiomers. The correlation coefficients between the urine concentrations of the acid metabolite enantiomers obtained by the two methods were >0.99. The two methods demonstrated interchangeable application to pharmacokinetics.     

Determination of mycophenolic acid and its phenol glucuronide metabolite in human plasma and urine by high-performance liquid chromatography

Simultaneous determination of mycophenolic acid (MPA) and mycophenolate phenol glucuronide (MPAG) in plasma and urine was accomplished by isocratic HPLC with UV detection. Plasma was simply deproteinated with acetonitrile and concentrated, whereas urine was diluted prior to analysis. Linearity was observed from 0.2 to 50 μg/ml for both MPA and MPAG in plasma and from 1 to 50 μg/ml of MPA and 5 to 2000 μg/ml MPAG in urine with extraction recovery from plasma greater than 70%. Detection limits using 0.25 ml plasma were 0.080 and 0.20 μg/ml for MPA and MPAG, respectively. The method is more rapid and simple than previous assays for MPA and MPAG in biological fluids from patients.     

Determination of the enantiomers of nisoldipine in human plasma using high-performance liquid chromatography on a chiral stationary phase and gas chromatography with mass-selective detection

A method is described that combines chiral HPLC and off-line GC with mass-selective detection for the quantitation of the enantiomers of nisoldipine [(±)-I] in human plasma. An isotope-labelled internal standard [nine-fold deuterated (±)-I] is used throughout the assay. The limit of quantification is 0.1 μg/l for each enantiomer. Data on the precision, accuracy and selectivity of the method are presented. Enantioselective analysis was performed in subjects receiving the racemic drug in tablet form. In healthy volunteers the maximum concentration and the area under the curve of the pharmacologically more active (+)-enantiomer were greater by 9-fold and 13-fold, respectively, compared to those of the (−)-enantiomer. In elderly hypertensive patients plasma concentrations of (+)-I were ca. five times as high as those of the (−)-enantiomer. Stereoselectivity was not affected by hepatic impairment. After intravenous administration of (±)-I there were no relevant differences between the plasma concentrations of the enantiomers.     

Determination of serum thyroxine enantiomers in patients by liquid chromatography with a chiral mobile phase

A chromatographic method for the separation and determination of D- and L-thyroxine enantiomers (D-, and L-T4) in human serum with a chiral ligand ion-exchange system using a chiral mobile phase additive and a silica column was established. An aqueous eluent containing L-proline (L-pro) sufficiently complexed copper II ions and triethylamine (TEA) was used. It was monitored with a UV detector. The separation was completed in 12 min. The method has acceptable sensitivity, precision and accuracy for analysis. The limit of detection and the limit of quantitation for both D- and L-T4 were 0.1 microg/ml and 0.8 microg/ml, respectively. Calibration curves were linear within 1-100 microg/ml; the mean correlation coefficients were r(D-T4)=0.9986 for D-T4 and r(L-T4)=0.9978 for L-T4. T4 enantiomers were separated on baseline under the optimum condition. L-T4 eluted before D-T4. The concentration of D-T4 and L-T4 in 45 thyroid patients serum (hyperthyroid, hypothyroid, thyroidectomy, goitre or thyroiditis) using HPLC was determined, those results showed that D,L-T4 concentration varied in different thyroid patient. Attention should be paid to this result in treating thyroid disease in the clinic.     

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.     

Determination of azosemide and its metabolite in plasma, blood, urine and tissue homogenates by high-performance liquid chromatography

High-performance liquid chromatographic methods were developed for the determination of azosemide and its metabolite, M1, in human plasma and urine and rabbit blood and tissue homogenates. The methods involved deproteinization of the biological samples: 2.5 volumes of acetonitrile were used for the determination of azosemide and 1 volume of saturated Ba(OH)₂ and ZnSO₄ for that of M1. A 50-μl aliquot of the supernatant was injected onto a C₁₈ reversed-phase column in each instance. The mobile phases employed were 0.03 M phosphoric acid—acetonitrile (50:40, v/v) for azosemide and 0.03 M phosphoric acid/0.2 M acetic acid—acetonitrile (83:17, v/v) for M1. The flow-rate was 1.5 ml/min in both instances. The column effluent was monitored by ultraviolet detection at 240 and 236 nm for azosemide and M1, respectively. The retention times for azosemide and M1 were 6.0 and 8.3 min, respectively. The detection limits for both azosemide and M1 in both human plasma and urine were 50 ng/ml. The coefficients of variation of the assay were generally low (below 11.0%) for plasma, urine, blood and tissue homogenates. No interferences from endogenous substances or other diuretics tested were observed.