Determination of phenylbutazone and oxyphenbutazone in plasma and urine samples of horses by high-performance liquid chromatography and gas chromatography-mass spectrometry

A method is described for the qualiitative and quantitative determination of phenylbutazone and oxyphenbutazone in horse urine and plasma samples viewing antidoping control. A horse was administered intravenously with 3 g of phenylbutazone. For the qualitative determination, a screening by HPLC was performed after acidic extraction of the urine samples and the confirmation process was realized by GC-MS. Using the proposed method it was possible to detect phenylbutazone and oxyphenbutazone in urine for up to 48 and 120 h, respectively. For the quantitation of these drugs the plasma was deproteinized with acetonitrile and 20 gml were injected directly into the HPLC system equipped with a UV detector and LiChrospher RP-18 column. The mobile phase used was 0.01 M acetic acid in methanol (45:55, v/v). The limit of detection was 0.5 μg/ml for phenylbutazone and oxyphenbutazone and the limit of quantitation was 1.0 μg/ml for both drugs. Using the proposed method it was possible to quantify phenylbutazone up to 30 h and oxyphenbutazone up to 39 h after administration.     

Measurement of allantoin in urine and plasma by high-performance liquid chromatography with pre-column derivatization

A method is reported for determination of allantoin in urine and plasma based on high-performance liquid chromatography (HPLC) and pre-column derivatization. In the derivatization procedure, allantoin is converted to glyoxylic acid which forms a hydrazone with 2,4-dinitrophenylhydrazine. The hydrazone appears as syn and anti isomers at a constant ratio. These derivatives are separated by HPLC using a reversed-phase C₁₈ column from hydrazones of other keto acids possibly present in urine and plasma and then monitored at 360 nm. All components were completely resolved in 15 min. Both the reagents and derivatization products are stable. Recovery of allantoin added to urine and plasma was 95 ± 3.7% (n = 45) and 100 ± 7.5% (n = 64), respectively. The lowest allantoin concentration that gave a reproducible integration was 5 μmol/l. The between-assay and within-day coefficients of variation were 2.8 and 0.6%, respectively.     

Determination of cibenzoline in plasma and urine by high-performance liquid chromatography

A rapid, sensitive and selective high-performance liquid chromatographic (HPLC) assay was developed for the determination of cibenzoline (Cipralan ^TM) in human plasma and urine. The assay involves the extraction of the compound into benzene from plasma or urine buffered to pH 11 and HPLC analysis of the residue dissolved in acetonitrile---phosphate buffer (0.015 mol/1, pH 6.0) (80:20). A 10-μ ion-exchange (sulfonate) column was used with acetonitrile—phosphate buffer (0.015 mol/1, pH 6.0) (80:20) as the mobile phase. UV detection at 214 nm was used for quantitation with the di-p-methyl analogue of cibenzoline as the internal standard.The recovery of cibenzoline in the assay ranged from 60 to 70% and was validated in human plasma and urine in the concentration range of 10–1000 ng/ml and 50–5000 ng/ml, respectively. A normal-phase HPLC assay was developed for the determination of the imidazole metabolite of cibenzoline. The assays were applied to the determination of plasma and urine concentrations of cibenzoline and trace amounts of its imidazole metabolite following oral administration of cibenzoline succinate to two human subjects.     

Simultaneous quantitative determination of the major phase I and II metabolites of ibuprofen in biological fluids by high-performance liquid chromatography on dynamically modified silica

Ibuprofen has previously, after ingestion by man, been demonstrated to yield four major phase I metabolites, which are excreted in the urine partly as glucuronic acid conjugates. However, in previous investigations the quantitative determinations of the conjugates were performed by indirect methods. The purpose of the present investigation was to develop a high-performance liquid chromatographic (HPLC) system for the simultaneous determination of the major phase I and II metabolites of ibuprofen in biological fluids. The separation was performed using bare silica dynamically modified with N-cetyl-N,N,N-trimethylammonium hydroxide ions contained in the mobile phase. The separation of the metabolites of ibuprofen is greatly improved with this system compared to other published reversed-phase HPLC systems intended for the same purpose. The method developed makes it possible to simultaneously determine the intact glucuronic acid conjugates of ibuprofen as well as its phase I metabolites in human urine. In a study involving four healthy volunteers, a total recovery in urine of the dose given was found to be 58–86% within 8 h. This may be compared to an average of 67% earlier reported in the literature.     

Internal standard high-performance liquid chromatography method for the determination of obidoxime in urine of organophosphate-poisoned patients

Obidoxime is an antidote approved for reactivation of inhibited acetylcholinesterase in organophosphate poisoning. HPLC methods were described for its determination in blood or aqueous solutions but not for the determination in urine. Since data for renal obidoxime excretion ranged from 2.2 to 84% of administered dose in healthy volunteers depending on the route of administration and little is known about pharmacokinetics of obidoxime in severely intoxicated patients we developed an internal standard (HI 6) reversed-phase HPLC method for determining obidoxime in urine. The mobile phase consisted of methanol, the counter ion 1-heptane sulfonic acid and tetrabutylammonium phosphate, the stationary phase involved a 5 μm reversed-phase column (125×4 mm). Obidoxime was detected spectrophotometrically at 288 nm. The limit of quantification (LOQ) was 1 μM, the limit of detection (LOD) 0.5 μM. Linear calibration curves were obtained in a concentration range from 1 to 1000 μM. Intra- and inter-day precision C.V.s were below 4%. Accuracy was 95.9% in the LOQ range. Using this method, we were able to quantify obidoxime in urine of an organophosphate poisoned patient. Based on this data we calculated that 58% of the administered dose was excreted in the urine.     

Determination of endogenous thiols and thiol drugs in urine by HPLC with ultraviolet detection

Analysis of urine for endogenous thiols and thiol drugs content by HPLC with ultraviolet detection is addressed. Other methodologies for detection and determination of thiols in urine are only mentioned. Outline of metabolism, role of main biological thiols in physiological and pathological processes and their reference concentrations in urine are presented. In particular, urine sample preparation procedures, including reduction of thiol disulfides, chemical derivatization and reversed-phase HPLC separation steps are discussed. Some experimental details of analytical procedures for determination of endogenous thiols cysteine, cysteinylglycine, homocysteine, N-acetylcysteine, thioglycolic acid; and thiol drugs cysteamine, tiopronin, d-penicillamine, captopril, mesna, methimazole, propylthiouracil and thioguanine are reviewed.     

Determination of indomethacin and mefenamic acid in plasma by high-performance liquid chromatography

Indomethacin and mefenamic acid are widely used clinically as non-steroidal anti-inflammatory agents. Both drugs have also been found effective to produce closure of patent ductus arteriosus in premature neonates. A simple, rapid, sensitive and reliable HPLC method is described for the determination of indomethacin and mefenamic acid in human plasma. As these drugs are not applied together, the compounds are alternately used as analyte and internal standard. Plasma was deproteinized with acetonitrile, the supernatant fraction was evaporated to dryness and the resulting residue was reconstituted in the mobile phase and injected into the HPLC system. The chromatographic separation was performed on a C₁₈ column (250 × 4.6 mm I.D.) using 10 mM phosphoric acid—acetonitrile (40:60, v/v) as the mobile phase and both drugs were detected at 280 nm. The calibration graphs were linear with a correlation coefficient (r) of 0.999 or better from 0.1 to 10 μg/ml and the detection limits were 0.06 μg/ml for indomethacin and 0.08 μg/ml for mefenamic acid, for 50μl plasma samples. The method was not interfered with by other plasma components and has been found particularly useful for paediatric use. The within-day precision and accuracy of the method were evaluated for three concentrations in spiked plasma samples. The coefficients of variation were less than 5% and the accuracy was nearly 100% for both drugs.     

Oral platelet aggregation inhibitor Ro 48-3657: Determination of the active metabolite and its prodrug in plasma and urine by high-performance liquid chromatography using automated column switching

A sensitive and highly automated high-performance liquid chromatography (HPLC) column-switching method has been developed for the simultaneous determination of the active metabolite III and its prodrug II, both derivatives of the oral platelet inhibitor Ro 48-3657 (I), in plasma and urine of man and dog. Plasma samples were deproteinated with perchloric acid (0.5 M), while urine samples could be processed directly after dilution with phosphate buffer. The prepared samples were injected onto a pre-column of a HPLC column switching system. Polar plasma or urine components were removed by flushing the precolumn with phosphate buffer (0.1 M, pH 3.5). Retained compounds (including II and III) were backflushed onto the analytical column, separated by gradient elution and detected by means of UV detection at 240 nm. The limit of quantification for both compounds was 1 ng/ml (500 μl of plasma) and 25 ng/ml (50 μl of urine) for plasma and urine, respectively. The practicability of the new method was demonstrated by the analysis of about 6000 plasma and 1300 urine samples from various toxicokinetic studies in dogs and phase 1 studies in man.     

Fluorometric determination of plasma adenosine concentrations using high-performance liquid chromatography

Methods are described for the fluorometric determination of plasma adenosine concentrations, using HPLC. Plasma obtained from blood of dogs treated with erythro-(2-hydroxy-3-nonyl)adenine hydrochloride and dipyridamole was deproteinized with perchloric acid and the neutralized sample was put sequentially onto a SepPak C18 and boronic acid affinity column. Subsequently, adenosine in the final elution was converted to 1,N6-ethenoadenosine and was quantitated by HPLC with a fluorescence detector. The percentage recovery of adenosine added to the deproteinized plasma was nearly 100%. In the adenosine deaminase treated plasma, the increase in adenosine concentration of even 4 nM can be accurately determined. The control renal venous plasma concentrations of adenosine in anesthetized dogs were 19.9 +/- 1.9 nM, a significantly higher value than the corresponding arterial concentrations (12.7 +/- 1.1 nM), thereby suggesting the renal release of adenosine. This release was markedly enhanced following the removal of the renal arterial occlusion. Thus, taken together with the in vivo results, the present method is sensitive, hence most useful for the determination of plasma adenosine concentrations.     

Rapid, quantitative high-performance liquid column chromatography of pseudouridine

A rapid, precise, and accurate chromatographic method for the determination of pseudo-uridine (ψ) in urine by high-performance liquid chromatography (HPLC) has been developed. The ribonucleosides were first isolated with an affinity gel containing immobilized phenylboronic acid. The response for ψ was linear well above and below the range necessary to determine urinary ψ. Good precision was obtained for both matrix-dependent and matrix-independent samples. Supporting experimental data are presented on precision, recovery, chromatographic methods, sample cleanup and application to the analysis of urine samples from normal males and females, and patients with advanced colon cancer. In a comparison of 40 normals with 10 colon cancer patients, 9 of the 10 patients had a ψ: creatinine (Cr) ratio greater than + 2σ for the normal population. This HPLC method is now being used extensively in our laboratory as a routine method for determination of ψ in urine from patients with various types of cancer and in chemotherapy response studies. Data are presented on the dynamics of ψ excretion by normal males and females. When the excretion of ψ was normalized with the excretion of creatinine, it was noted that samples collected at random have the same ψ: Cr ratio value as for the 24-h total collection, thus, allowing the use of random samples. The constancy of the ψ: Cr ratio implies that RNA turnover is constant and ψ excretion is independent of diet. Base values are presented for the ψ: Cr     

Measurement of catecholamines in biological fluids by high-performance liquid chromatography : A comparison of fluorimetric with electrochemical detection

An improved method for the determination of catecholamines in biological fluids, by reversed-phase high-performance liquid chromatography (HPLC) with fluorimetric detection is presented. The pH titration previously employed in the alumina extraction was abandoned in favour of the use of a molar excess of pH 8.5 Tris—HCl buffer. A novel lyophilisation step serves to concentrate the catechols and by reconstituting in mobile phase, chromatography disturbances are minimised. The addition of 2 mM octanesulphonic acid to a citrate—phosphate mobile phase at pH 6.0 gave optimal resolution and sensitivity.That HPLC separation can improve the specificity of the trihydroxyindole reaction, to the extent of providing a reliable analytical method, has been demonstrated and validated by the technique of HPLC with electrochemical detection. A correlation coefficient of 0.98 was obtained between the two techniques as applied to the measurement of urinary catecholamines. The HPLC—fluorimetric method was sensitive enough to measure 0.1 ng/ml of noradrenaline or adrenaline at a signal-to-noise ratio of 2.0. Application of the method to the quantitative determination of catecholamines in human urine, plasma and rat brain homogenates is demonstrated.     

Determination of sialic acids in biological fluids using reversed-phase ion-pair high-performance liquid chromatography

A simple, rapid and sensitive reversed-phase ion-pair high-performance liquid chromatographic method for the determination of N-acetylneuraminic acid and 2-deoxy-2,3-dehydro-N-acetylneuraminic acid in biological fluids is described. Determination of N-acetylneuraminic acid released by acidic hydrolysis, in serum, urine and saliva, and 2-deoxy-2,3-dehydro-N-acetylneuraminic acid in urine, without hydrolysis, was accomplished by injecting the sample without derivatization, into the chromatograph. Measurements were carried out isocratically within 6 min using a C₁₈ column and a mobile phase of aqueous solution of triisopropanolamine, as ion-pair reagent, 60 mM, pH 3.5 at room temperature with UV absorbance detection. The present method is reported for the first time for the determination of sialic acids in biological fluids. Recoveries in serum, urine and saliva ranged from 90 to 102% and the limits of detection were 60 nM and 20 nM for the two sialic acids, respectively. The method has been applied to normal and pathological sera from patients with breast, stomach, colon, ovarian and cervix cancers, to normal urine and urine from patient with sialuria and to normal saliva.     

Determination of fenofibric acid in human plasma using automated solid-phase extraction coupled to liquid chromatography

The pharmacokinetic studies of fenofibrate require a rapid, selective and robust method to allow the determination of fenofibric acid, its active metabolite, in different biological matrixes (such as plasma, serum or urine). A new fully automated method for the determination of fenofibric acid in plasma has been developed, which involves the solid-phase extraction (SPE) of the analyte from plasma on disposable extraction cartridges (DECs) and reversed-phase HPLC with UV detection. The SPE operations were performed automatically by means of a sample processor equipped with a robotic arm (ASPEC system). The DEC filled with octadecyl silica was first conditioned with methanol and pH 7.4 phosphate buffer. A 0.8-ml volume of diluted plasma sample containing the internal standard (sulindac) was then applied on the DEC. The washing step was performed with the same buffer (pH 7.4). Finally, the analytes were successively eluted with methanol (1.0 ml) and 0.04 M phosphoric acid (1.0 ml). After a mixing step, 100 μl of the resultant extract was directly introduced into the HPLC system. The liquid chromatographic (LC) separation of the analytes was achieved on a Nucleosil RP-8 stationary phase (5 μm). The mobile phase consisted of a mixture of methanol and 0.04 M phosphoric acid (60:40, v/v). The analyte was monitored photometrically at 288 nm. The method developed was validated. In these conditions, the absolute recovery of fenofibric acid was close to 100% and a linear calibration curve was obtained in the concentration range from 0.25 to 20 μg/ml. The mean RSD values for repeatability and intermediate precision were 1.7 and 3.9% for fenofibric acid. The method developed was successfully used to investigate the bioequivalence between a micronized fenofibrate capsule formulation and a fenofibrate Lidose™ formulation.     

Enantioselective analysis of disopyramide and mono-N-dealkyldisopyramide in plasma and urine by high-performance liquid chromatography on an amylose-derived chiral stationary phase

An enantioselective high-performance liquid chromatography method was developed for the simultaneous determination of disopyramide (DP) and mono-N-dealkyldisopyramide (MND) enantiomers in plasma and urine. The drugs were extracted from plasma samples by liquid–liquid extraction with dichloromethane after protein precipitation with trichloroacetic acid; the urine samples were processed by liquid–liquid extraction with dichloromethane. The enantiomers were resolved on a Chiralpak AD column using hexane–ethanol (91:9, v/v) plus 0.1% diethylamine as the mobile phase and monitored at 270 nm. Under these conditions the enantiomeric fractions of the drug and of its metabolite were analyzed within 20 min. The extraction procedure was efficient in removing endogenous interferents and low values for the relative standard deviations were demonstrated for both within-day and between-day assays. The method described in this paper allows the determination of DP and MND enantiomers at plasma levels as low as 12.5 ng/ml and can be used in clinical pharmacokinetic studies.     

Direct analysis of salicylic acid,salicyl acyl glucuronide,salicyluric acid and gentisic acid in human plasma and urine by high-performance liquid chromatography

A method for the simultaneous direct determination of salicylate (SA), its labile, reactive metabolite, salicyl acyl glucuronide (SAG), and two other major metabolites, salicyluric acid and gentisic acid in plasma and urine is described. Isocratic reversed-phase high performance liquid chromatography (HPLC) employed a 15-cm C₁₈ column using methanol-acetonitrile-25 mM acetic acid as the mobile phase, resulting in HPLC analysis time of less than 20 min. Ultraviolet detection at 310 nm permitted analysis of SAG in plasma, but did not provide sensitivity for measurement of salicyl phenol glucuronide. Plasma or urine samples are stabilized immediately upon collection by adjustment of pH to 3–4 to prevent degradation of the labile acyl glucuronide metabolite. Plasma is then deproteinated with acetonitrile, dried and reconstituted for injection, whereas urine samples are simply diluted prior to injection on HPLC. m-Hydroxybenzoic acid served as the internal standard. Recoveries from plasma were greater than 85% for all four compounds over a range of 0.2–20 μg/ml and linearity was observed from 0.1–200 μg/ml and 5–2000 μg/ml for SA in plasma and urine, respectively. The method was validated to 0.2 μg/ml, thus allowing accurate measurement of SA, and three major metabolites in plasma and urine of subjects and small animals administered salicylates. The method is unique by allowing quantitation of reactive SAG in plasma at levels well below 1% that of the parent compound, SA, as is observed in patients administered salicylates.     

Reversed-phase chromatography of urinary metabolites of paracetamol using ion suppression and ion pairing

High-performance liquid chromatography (HPLC) has proven particularly useful for the study of paracetamol metabolism. Two alternative methods were developed using reversed-phase C₁₈ columns. A rapid ion suppression technique was used for the analysis of free paracetamol, paracetamol mercapturic acid and cysteine conjugate in urine samples obtained from isolated perfused rat kidney preparations, which has conveniently demonstrated the oxidative metabolic capacity of the kidney towards paracetamol. A somewhat longer, but higher resolution, ion-pair HPLC procedure was developed for the analysis of paracetamol metabolites in urine samples from experimental animals. The ion-pairing solvent was composed of tetrabutylammonium hydroxide, Tris and EDTA buffered to pH 7.2 with phosphoric acid. Gradient programming was further used to enhance resolution. Using this system two new metabolites, the sulphate and glucuronide conjugates of 3-thiomethyl-paracetamol were detected and routinely determined along with other known paracetamol metabolites, viz. free paracetamol, paracetamol sulphate, glucuronide, mercapturic acid, and cysteine conjugates, 3-methoxyparacetamol glucuronide and sulphate, p-aminophenol and its O-glucuronide and O-sulphate conjugates. Phenolic O-substituted glucuronide and sulphate conjugates of N-hydroxyparacetamol were also separated.     

Assay of moguisteine metabolites in human plasma and urine: conventional and chiral high-performance liquid chromatographic methods

Moguisteine is a novel peripheral non-narcotic antitussive agent. Pharmacokinetic studies in animal and in man showed that no unchanged drug is present in plasma, urine and faeces after oral administration. The main active metabolite, M1, is the free carboxylic acid of moguisteine, which maintains a stereogenic centre and consists of R(+)-M1 and S(−)-M1 enantiomers. M1 is partly metabolized to M2, its sulfoxidation derivative. A conventional HPLC method is described for the simultaneous determination of M1 and M2 in human plasma and urine after administration of therapeutic moguisteine doses. Plasma samples, previously acidified with phosphoric acid, are extracted with dichloromethane; urine samples are analyzed after appropriate dilution with methanol. Chromatography is performed using a Lichrosorb RP2 column and a linear gradient. M1 enantiomers can be determined in plasma extracts and urine samples by a chiral HPLC method using a β-cyclodextrin column. The analytical characteristics of both HPLC procedures proved to be adequate to analyze samples of subjects treated with therapeutic doses of moguisteine during clinical pharmacokinetic studies.     

Determination of pramipexole (U-98,528) in human plasma and urine by high-performance liquid chromatography with electrochemical and ultraviolet detection

A sensitive and selective high-performance liquid chromatographic (HPLC) method was developed for the determination of pramipexole in human plasma and urine. Plasma/urine is made alkaline before pramipexole and BHT-920 (internal standard) are extracted by ethyl ether and back-extracted with a solution that contains heptanesulfonic acid. Separation is achieved by ion-pair chromatography on a Zorbax Rx C₈ column with electrochemical detection at 0.6 V for plasma and ultraviolet detection at 286 nm for urine. The retention times of pramipexole and internal standard are approximately 14.4 and 10.7 min, respectively. The assay is linear in concentration ranges of 50 to 15 000 pg/ml (plasma) and 10 to 10 000 ng/ml (urine). The correlation coefficients are greater than 0.9992 for all curves. For the plasma method, the analysis of pooled quality controls (300, 3000, and 10 000 pg/ml) demonstrates excellent precision with relative standard deviations (R.S.D.) (n=18) of 1.1%, 2.3%, and 6.8%, respectively. For the urine method, quality control pools prepared at 30, 300, and 3000 ng/ml had R.S.D. values (n=18) of 2.9%, 1.7%, and 3.0%, respectively. The plasma and urine controls were stable for more than nine and three months, respectively. The mean recoveries for pramipexole and internal standard from plasma were 97.7% and 98.2%, respectively. The mean recoveries for pramipexole and internal standard from urine were 89.8% and 95.1%, respectively. The method is accurate with all intra-day (n=6) and overall (n=18) mean values for the quality control samples being less than 6.4 and 5.8% from theoretical for plasma and urine, respectively.     

Determination of sparfloxacin in serum and urine by high-performance liquid chromatography

A specific and sensitive analytical method for the determination of sparfloxacin in serum and urine is described. Serum proteins are removed by precipitation with acetonitrile after the addition of ofloxacin as an internal standard. The supernatant solvent is evaporated in a vacuum concentrator and the dry residue is redissolved in the mobile phase. Separation is performed on a cation-exchange column (Nucleosil 100 5SA, 125 × 4.0 mm I.D., 5 μm particle size) protected by a guard column (Perisorb RP-18, 30 × 4.0 mm I.D., 30–40 μm particle diameter). The mobile phase consisted of 750 ml of acetonitrile and 250 ml of 100 mmol/l phosphoric acid (v/v) to which sodium hydroxide had been added. The final concentration of sodium was 23 mmol/l and the pH was 3.82. Sparfloxacin and ofloxacin were determined by spectrofluorimetry (excitation wavelength 295 nm; emission wavelength 525 nm). The flow-rate was 1.5 ml/min and the retention times were 4.7 (sparfloxacin) and 8.0 (ofloxacin) min. Validation of the method yielded the following results for serum: detection limit 0.05 mg/l; precision between series 10.4-3.6%; recovery 99.5–100.0%; comparison with a microbiological assay c(bioassay) = 1.035c(HPLC) − 0.06. The test organism was Bacillus subtilis ATCC 6633. For urine the results were: detection limit 0.5 mg/l; precision between series 7.8-5.0%; recovery 97.0–97.8%; method comparison c(bioassay) = 1.092c(HPLC) − 1.09. No interferences were observed in human volunteers. The method can also be applied to stool samples.     

Determination of vanilmandelic acid in urine by coupled-column liquid chromatography combining affinity to boronate and separation by anion exchange

An automated liquid chromatographic method for assaying vanilmandelic acid in urine is described. Vanilmandelic acid and potential interfering substances, such as catechol compounds and their metabolites, have been tested for affinity to boronic acid-substituted silica at various pH values. Vanilmandelic acid and the internal standard, isovanilmandelic acid, were bound to the boronate matrix at an acidic pH, whereas for instance catecholamines were unretained and passed through the column. The α-hydroxycarboxylic acids were then desorbed by another mobile phase (pH 6.0) and transferred to an anion exchanger for chromatography and electrochemical detection. A relative standard deviation of 2.8% was obtained for the analysis of human urine samples containing 6.6 μM vanilmandelic acid.