Efficient assay for the determination of atenolol in human plasma and urine by high-performance liquid chromatography with fluorescence detection

An efficient method for the determination of atenolol in human plasma and urine was developed and validated. α-Hydroxymetoprolol, a compound with a similar polarity to atenolol, was used as the internal standard in the present high-performance liquid chromatographic analysis with fluorescence detection. The assay was validated for the concentration range of 2 to 5000 ng/ml in plasma and 1 to 20 μg.ml in urine. For both plasma and urine, the lower limit of detection was 1 ng/ml. The intra-day and inter-day variabilities for plasma samples at 40 and 900 ng/ml, and urine samples at 9.5 μg/ml were <3% (n=5).     

Enantioselective analysis of levetiracetam and its enantiomer R-α-ethyl-2-oxo-pyrrolidine acetamide using gas chromatography and ion trap mass spectrometric detection

A gas chromatographic–mass spectrometric method was developed for the enantioselective analysis of levetiracetam and its enantiomer (R)-α-ethyl-2-oxo-pyrrolidine acetamide in dog plasma and urine. A solid-phase extraction procedure was followed by gas chromatographic separation of the enantiomers on a chiral cyclodextrin capillary column and detection using ion trap mass spectrometry. The fragmentation pattern of the enantiomers was further investigated using tandem mass spectrometry. For quantitative analysis three single ions were selected from the enantiomers, enabling selected ion monitoring in detection. The calibration curves were linear from 1 μM to 2 mM for plasma samples and from 0.5 mM to 38 mM for urine samples. In plasma and urine samples the inter-day precision, expressed as relative standard deviation was around 10% in all concentrations. Selected ion monitoring mass spectrometry is suitable for quantitative analysis of a wide concentration range of levetiracetam and its enantiomer in biological samples. The method was successfully applied to a pharmacokinetic study of levetiracetam and (R)-α-ethyl-2-oxo-pyrrolidine acetamide in a dog.     

Determination of the halothane metabolites trifluoroacetic acid and bromide in plasma and urine by ion chromatography

Halothane (CF₃CHClBr), a widely used volatile anesthetic, undergoes extensive biotransformation in humans. Oxidative halothane metabolism yields the stable metabolites trifluoroacetic acid and bromide which can be detected in plasma and urine. To date, analytical methodologies have either required extensive sample preparation, or two separate analytical procedures to determine plasma and urine concentrations of these analytes. A rapid and sensitive method utilizing high-performance liquid chromatography-ion chromatography (HPLC-IC) with suppressed conductivity detection was developed for the simultaneous detection of both trifluoroacetic acid and bromide in plasma and urine. Sample preparation required only ultrafiltration. Standard curves were linear (r²≥0.99) from 10 to 250 μM trifluoroacetic acid and 2 to 5000 μM bromide in plasma and 10 to 250 μM trifluoroacetic acid and 2 to 50 μM bromide in urine. The assay was applied to quantification of trifluoroacetic acid and bromide in plasma and urine of a patient undergoing halothane anesthesia.     

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.     

Determination of temozolomide in human plasma and urine by high-performance liquid chromatography after solid-phase extraction

As a part of a pilot clinical study, a high-performance reversed-phase liquid chromatography analysis was developed to quantify temozolomide in plasma and urine of patients undergoing a chemotherapy cycle with temozolomide. All samples were immediately stabilized with 1 M HCl (1 + 10 of biological sample), frozen and stored at −20°C prior to analysis. The clean-up procedure involved a solid-phase extraction (SPE) of clinical sample (100 μl) on a 100-mg C₁₈-endcapped cartridge. Matrix components were eliminated with 750 μl of 0.5% acetic acid (AcOH). Temozolomide was subsequently eluted with 1250 μl of methanol (MeOH). The resulting eluate was evaporated under nitrogen at RT and reconstituted in 200 μl of 0.5% AcOH and subjected to HPLC analysis on an ODS-column (MeOH-0.5% AcOH, 10:90) with UV detection at 330 nm. The calibration curves were linear over the concentration range 0.4–20 μg/ml and 2–150 μg/ml for plasma and urine, respectively. THe extraction recovery of temozolomide was 86–90% from plasma and 103–105% from urine over the range of concentrations considered. The stability of temozolomide was studied in vitro in buffered solutions at RT, and in plasma and urine at 37°C. An acidic pH (<5–6) shoul be maintained throughout the collection, the processing and the analysis of the sample to preserve the integrity of the drug. The method reported here was validated for use in a clinical study of temozolomide for the treatment of metastatic melanoma and high grade glioma.     

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 BAY 12-8039, a new 8-methoxyquinolone, in human body fluids by high-performance liquid chromatography with fluorescence detection using on-column focusing

A reversed-phase (RP) high-performance liquid chromatographic (HPLC) method with fluorescence detection allowing the sensitive and specific quantification of BAY 12-8039, a new antimicrobially active 8-methoxyquinolone, in biological fluids is described. The method is compared to a microbiological assay (bioassay) based on B. subtilis test strain with a limit of quantification of approximately 60 μg/l. Following dilution and centrifugation, plasma, saliva or urine supernatant is directly injected onto the HPLC system. Concentrations down to a limit of quantification of 2.5 μg/l can be quantified in plasma, saliva and urine. Data on recovery, accuracy and precision of the method throughout the whole working range as well as results on stability of the analyte are presented. The concentration data are correlated with results from the bioassay. BAY 12-8039 is stable in plasma after repeated freeze-thaw cycles and following storage at −20°C for at least 12 months. The results of HPLC measurements excellently agree with bioassay data indicating the relevance of the method as a tool in clinical development to answer pharmacokinetic questions related to antimicrobial activity. The method was applied to human plasma, saliva and urine from subjects after a single oral dose of 400 mg of BAY 12-8039.     

Quantification of nitrite and nitrate in human urine and plasma as pentafluorobenzyl derivatives by gas chromatography—mass spectrometry using their N-labelled analogs

For the quantification of nitrite and nitrate, the stable metabolites of -arginine-derived nitric oxide (NO) in human urine and plasma, we developed a gas chromatographic—mass spectrometric (GC—MS) method in which [¹⁵N]nitrite and [¹⁵N]nitrate were used as internal standards. Endogenous nitrite and [¹⁵N]nitrite added to acetone-treated plasma and urine samples were converted into their pentafluorobenzyl (PFB) derivatives using PFB bromide as the alkylating agent. For the analysis of endogenous nitrate and [¹⁵N]nitrate they were reduced to nitrite and [¹⁵N]nitrite, respectively, by cadmium in acidified plasma and urine samples prior to PFB alkylation. Reaction products were extracted with toluene and 1-μl aliquots were analyzed by selected-ion monitoring at m/z 46 for endogenous nitrite (nitrate) and m/z 47 for [¹⁵N]nitrite ([¹⁵N]nitrate). The intra- and inter-assay relative standard deviations for the determination of nitrite and nitrate in urine and plasma were below 3.8%. The detection limit of the method was 22 fmol of nitrite. Healthy subjects (n = 12) excreted into urine 0.49 ± 0.25 of nitrite and 109.5 ± 61.7 of nitrate (mean ± S.D., μmol/mmol creatinine) with a mean 24-h output of 5.7 μmol for nitrite and 1226 μmol for nitrate. The concentrations of nitrite and nitrate in the plasma of these volunteers were determined to be (mean ± S.D., μmol/l) 3.6 ± 0.8 and 68 ± 17, respectively.     

Determination of 5-S-cysteinyldopa in plasma and urine using a fully automated solid-phase extraction–high-performance liquid chromatographic method for an improvement of specificity and sensitivity of this prognostic marker of malignant melanoma

5-S-Cysteinyldopa (5-SCD) in plasma and urine was determined by means of a newly developed method. This method incorporates optimized conditions for blood collection and storage, as well as a new extraction and separation technique, required for the strong oxidation and light sensitive 5-SCD. The new aspects of the method are the following: immediate centrifugation and freezing of the samples after blood collection, fully automatical solid-phase extraction (SPE) with phenylboronic acid (PBA) cartridges and immediate HPLC injection of the eluate, nearly complete exclusion of light and air–oxygen during extraction, constant sample cooling, use of the more suitable internal standard 5-S- -cysteinyldopa and easy, sensitive and selective HPLC conditions (RP18-column with isocratic separation and electrochemical detection). The method has a linear range from 0.25 to 50 μg l⁻¹ and 25 to 5000 μg l⁻¹ for plasma and urine samples, respectively, a limit of detection of 0.17 μg l⁻¹, intra-assay variabilities from 1.7 to 3.6%, inter-assay variabilities from 4.0 to 18.3% and an average relative recovery of 103.5% for plasma and 105.4% for urine samples. In our study the measured 5-SCD concentrations of patients with melanomas at various stages correlated better with their clinical pictures than described in literature up to date. The results were obtained in comparison to patients with other skin tumors and in comparison to healthy control persons.     

Development of a highly sensitive high-performance liquid chromatographic method for measuring an anticancer drug, UCN-01, in human plasma or urine

We have established a highly sensitive high-performance liquid chromatographic method for the determination of an anticancer drug, UCN-01, in human plasma or urine. Using a fluorescence detector set at an excitation wavelength of 310 nm and emission monitored at 410 nm, there was a good linearity for UCN-01 in human plasma (r=0.999) or urine (r=0.999) at concentrations ranging from 0.2 to 100 ng/ml or 1 to 400 ng/ml, respectively. For intra-day assay, in plasma samples, the precision and accuracy were 1.8% to 5.6% and −10.0% to 5.2%, respectively. For inter-day assay, the precision and accuracy were 2.0% to 18.2% and 2.4% to 10.0%, respectively. In urine samples, the intra- and inter-day precision and accuracy were within 3.9% and ±2.7%, respectively. The lower limit of quantification (LLOQ) was set at 0.2 ng/ml in plasma and 1 ng/ml in urine. UCN-01 in plasma samples was stable up to two weeks at −80°C and also up to four weeks in urine samples. This method could be very useful for studying the human pharmacokinetics of UCN-01.     

Quantification of 3,4-methylenedioxymetamphetamine and its metabolites in plasma and urine by gas chromatography with nitrogen–phosphorus detection

A gas chromatographic method with nitrogen–phosphorus detection involving a solid–liquid extraction phase was developed and validated for the simultaneous quantification of 3,4-methylenedioxymethamphetamine (MDMA) and 3,4-methylenedioxyamphetamine (MDA) in plasma. A modification of this method was validated for the analysis of MDMA, MDA, 4-hydroxy-3-methoxymethamphetamine (HMMA) and, 4-hydroxy-3-methoxyamphetamine (HMA) in urine. Under the analytical conditions described, the limits of detection in plasma and urine were less than 1.6 μg/l and 47 μg/l, respectively, for all the compounds studied. Good linearity was observed in the concentration range evaluated in plasma (5–400 μg/l) and urine (100–2000 μg/l) for all compounds tested. The recoveries obtained from plasma were 85.1% and 91.6% for MDMA and MDA, respectively. Urine recoveries were higher than 90% for MDMA and MDA, 74% for HMMA, and 64% for HMA. Methods have been successfully used in the assessment of plasma and urine concentrations of MDMA and its main metabolites in samples from clinical studies in healthy volunteers.     

Gas chromatographic determination of 2- and 3-dechloroethylifosfamide in plasma and urine

The metabolic oxidation of one of the chloroethyl groups of the antitumour drug ifosfamide leads to the formation of the inactive metabolites 2- and 3-dechloroethylifosfamide together with the neurotoxic metabolite chloroacetaldehyde. A very sensitive capillary gas chromatographic method, requiring only 50 μl of plasma or urine, has been developed to measure the amounts of the drug and the two inactive metabolites in a single run. Calibration curves were linear (r > 0.999) in the concentration ranges from 50 ng/ml to 100 μg/ml in plasma and from 100 ng/ml to 1 mg/ml in urine.     

Determination of dihydroetorphine in biological fluids by gas chromatography-mass spectrometry using selected-ion monitoring

A method for the determination of dihydroetorphine hydrochloride, a powerful anaesthetic and analgesic drug, in biological fluids by GC-MS with selected-ion monitoring using etorphine as internal standard was established. Dihydroetorphine was extracted from human blood and urine with dichloromethane and then derivatized with N-heptafluorobutyrylimidazole after concentration to dryness. A dihydroetorphine monoheptafluorobutyl derivative was formed which showed good behavior on GC-MS with electronic-impact ionization. The main fragment, m/z 522, which is the base peak, was selected as the ion for quantitation and the corresponding ion, m/z 520, was selected for monitoring the internal standard, etorphine. The recoveries and coefficients of variation of the whole procedure were determined with five controlled dihydroetorphine-free urine and plasma samples spiked with different concentrations of dihydroetorphine. The concentration of dihydroetorphine for quantitation was in the range 1–20 ng/ml for urine and 2.5–250 ng/ml for plasma. The correlation coefficients of the standard curves are sufficient to determine the dihydroetorphine. The accuracy for quantitation of dihydroetorphine in urine and plasma is less than 10.6%.     

Radioimmunoassay of 6β-hydroxycortisol in human plasma and urine

A sensitive and reliable radioimmunoassay for urine and plasma 6β-hydroxycortisol has been developed. Antiserum showing high specificity against 6β-hydroxycortisol was produced in rabbits immunized with 6β-hydroxycortisol 21-hemisuccinate-bovine serum albumin. The sensitivity of the assay was 25 pg on a diluted sample equivalent to 1 μl of urine, and on 50 μl of plasma after separation by celite chromatography. The intra- and inter-assay coefficients of variation for urine were 4.8 and 6.7% and those for plasma were 4.2 and 12.1%. Concentrations were determined in patients with bronchogenic carcinoma, in patients treated with dilantin, in neonates, and in infants aged 5–12 months.     

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.     

High-performance liquid chromatography of the renal blood flow marker p-aminohippuric acid (PAH) and its metabolite N-acetyl PAH improves PAH clearance measurements

PAH (N-(4-aminobenzoyl)glycin) clearance measurements have been used for 50 years in clinical research for the determination of renal plasma flow. The quantitation of PAH in plasma or urine is generally performed by colorimetric method after diazotation reaction but the measurements must be corrected for the unspecific residual response observed in blank plasma. We have developed a HPLC method to specifically determine PAH and its metabolite NAc-PAH using a gradient elution ion-pair reversed-phase chromatography with UV detection at 273 and 265 nm, respectively. The separations were performed at room temperature on a ChromCart^® (125 mm×4 mm I.D.) Nucleosil 100-5 μm C₁₈ AB cartridge column, using a gradient elution of MeOH–buffer pH 3.9 1:99→15:85 over 15 min. The pH 3.9 buffered aqueous solution consisted in a mixture of 375 ml sodium citrate–citric acid solution (21.01 g citric acid and 8.0 g NaOH per liter), added up with 2.7 ml H₃PO₄ 85%, 1.0 g of sodium heptanesulfonate and completed ad 1000 ml with ultrapure water. The N-acetyltransferase activity does not seem to notably affect PAH clearances, although NAc-PAH represents 10.2±2.7% of PAH excreted unchanged in 12 healthy subjects. The performance of the HPLC and the colorimetric method have been compared using urine and plasma samples collected from healthy volunteers. Good correlations (r=0.94 and 0.97, for plasma and urine, respectively) are found between the results obtained with both techniques. However, the colorimetric method gives higher concentrations of PAH in urine and lower concentrations in plasma than those determined by HPLC. Hence, both renal (Cl_R) and systemic (Cl_S) clearances are systematically higher (35.1 and 17.8%, respectively) with the colorimetric method. The fraction of PAH excreted by the kidney Cl_R/Cl_S calculated from HPLC data (n=143) is, as expected, always <1 (mean=0.73±0.11), whereas the colorimetric method gives a mean extraction ratio of 0.87±0.13 implying some unphysiological values (>1). In conclusion, HPLC not only enables the simultaneous quantitation of PAH and NAc-PAH, but may also provide more accurate and precise PAH clearance measurements.     

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.     

High-performance liquid chromatographic method for determination of vanillin and vanillic acid in human plasma, red blood cells and urine

A simple high-performance liquid chromatographic method was developed for the determination of vanillin and its vanillic acid metabolite in human plasma, red blood cells and urine. The mobile phase consisted of aqueous acetic acid (1%, v/v)–acetonitrile (85:15, v/v), pH 2.9 and was used with an octadecylsilane analytical column and ultraviolet absorbance detection. The plasma method demonstrated linearity from 2 to 100 μg/ml and the urine method was linear from 2 to 40 μg/ml. The method had a detection limit of 1 μg/ml for vanillin and vanillic acid using 5 μl of prepared plasma, red blood cells or urine. The method was utilized in a study evaluating the pharmacokinetic and pharmacodynamic effects of vanillin in patients undergoing treatment for sickle cell anemia.     

High-performance liquid chromatographic determination of 3′-hydroxy-5′-(4-isobutyl-1-piperazinyl)benzoxazinorifamycin (KRM-1648) and its deacetyl metabolite in plasma, whole blood, urine and tissue samples in rats

A reversed-phase high-performance liquid chromatographic method was developed for the determination of 3′-hydroxy-5′-(4-isobutyl-1-piperazinyl)benzoxazinorifamycin (KRM-1648, I), a new rifamycin derivative, and its 25-deacetyl metabolite (KRM-1671, II) in plasma, whole blood, tissues and urine from rats. I and II were coextracted with an internal standard from each sample matrix by solid-phase extraction (Bond Elut). Plasma and urine were directly loaded onto Bond Elut, while whole blood and tissues were homogenized and extracted with methanol or dichloromethane—chloroform prior to Bond Elut extraction. The extracts were chromatographed on Shim-pack CLC-ODS(M) using acetonitrile—0.02 M citrate buffer containing 0.1 M sodium perchlorate (2:1, v/v), and peaks were detected at 643 nm. The validation data showed that the assays for I and II in plasma, whole blood, tissues and urine were selective, accurate and reproducible.     

Quantification of BNP7787 (dimesna) and its metabolite mesna in human plasma and urine by high-performance liquid chromatography with electrochemical detection

A sensitive and accurate assay was developed and validated to determine BNP7787 (dimesna), a new protector against cisplatin-induced toxicities, and its metabolite mesna in plasma and urine of patients. Both analytes were measured as mesna in deproteinized plasma or in urine diluted with mobile phase using high-performance liquid chromatography with an electrochemical detector provided with a wall-jet gold electrode. The assays for BNP7787 and mesna in deproteinized plasma were linear over the range of 1.6–500 μM and 0.63–320 μM, respectively. In plasma, the mean recovery of BNP7787 over the whole concentration range was 100.6% and of mesna 94.6%. The lower limits of quantitation (LLQs) of BNP7787 and mesna in deproteinized plasma were 1.6 μM and 0.63 μM, respectively. For both compounds the within- and between-day accuracy and precision of the assay was better than 12%. The assays for BNP7787 and mesna in urine were linear over the range of 0.8–1200 μM and 0.63–250 μM, respectively. In urine, the mean recovery of BNP7787 over the whole concentration range was 94.1% and of mesna 93.1%. The LLQ of BNP7787 in urine was 0.8 μM and of mesna 1.6 μM. The within- and between-day accuracy and precision of the assay for BNP7787 and mesna was lower than 15%. The stability of mesna in urine increased with an increasing concentration of mesna, lower temperature and addition of EDTA (1 g/l) and hydrochloric acid (0.2 M). BNP7787 in urine was stable for at least 24 h at temperatures in the range of −20°C up to 37°C and independent of the concentration. The developed assays are currently applied for samples of patients with solid tumors participating in a phase I trial of BNP7787 in combination with cisplatin.