Fast LC–MS Electrospray Ionization for the Quantification of Digoxin in Human Plasma and Its Application to Bioequivalence Studies

A fast, sensitive and specific liquid chromatography-mass spectrometry method has been developed for quantification of digoxin in human plasma. The method was optimized to bioequivalence studies aiming higher sensitivity and selectivity than previously published methods, in addition to shorter run time allowing high-throughput sample analyses from volunteers. Chromatographic separation was achieved by an RP-18e column hyphenated to an API 5000 mass spectrometer system set at negative electrospray ionization and operating in the MRM mode. Calibration curve was linear over a wide range of concentration (50.0–6000.0 pg mL⁻¹), with the lower limit of quantification at 50.0 pg mL⁻¹ and without interfering peaks at the retention time of digoxin (2.09 min). Dexamethasone was used as internal standard and samples were cleaned up by liquid-liquid extraction obtaining a mean recovery of 73.8%. Validation results confirmed inter-batch accuracy (−8.66 to 5.78%), precision (4.1–10.6%) and stability, in accordance with the U.S. Food and Drug Administration and the Brazilian National Health Surveillance Agency guidelines. The developed analytical method could be successfully applied to a single oral dose (0.25 mg), one-way, randomized, two-sequence, crossover bioequivalence study validating, up to date, the fastest analysis and the most sensitive and specific method already published for digoxin quantification.

     

Fast LC–MS Electrospray Ionization for the Quantification of Digoxin in Human Plasma and Its Application to Bioequivalence Studies

A fast, sensitive and specific liquid chromatography-mass spectrometry method has been developed for quantification of digoxin in human plasma. The method was optimized to bioequivalence studies aiming higher sensitivity and selectivity than previously published methods, in addition to shorter run time allowing high-throughput sample analyses from volunteers. Chromatographic separation was achieved by an RP-18e column hyphenated to an API 5000 mass spectrometer system set at negative electrospray ionization and operating in the MRM mode. Calibration curve was linear over a wide range of concentration (50.0–6000.0 pg mL⁻¹), with the lower limit of quantification at 50.0 pg mL⁻¹ and without interfering peaks at the retention time of digoxin (2.09 min). Dexamethasone was used as internal standard and samples were cleaned up by liquid-liquid extraction obtaining a mean recovery of 73.8%. Validation results confirmed inter-batch accuracy (−8.66 to 5.78%), precision (4.1–10.6%) and stability, in accordance with the U.S. Food and Drug Administration and the Brazilian National Health Surveillance Agency guidelines. The developed analytical method could be successfully applied to a single oral dose (0.25 mg), one-way, randomized, two-sequence, crossover bioequivalence study validating, up to date, the fastest analysis and the most sensitive and specific method already published for digoxin quantification.     

An improved LC‐MS/MS method for quantitation of indapamide in whole blood: application for a bioequivalence study

An improved LC‐MS/MS method for the quantitation of indapamide in human whole blood was developed and validated. Indapamide‐d3 was used as internal standard (IS) and liquid–liquid extraction was employed for sample preparation. LC separation was performed on Synergi Polar RP‐column (50 × 4.6 mm i.d.; 4 µm) and mobile phase composed of methanol and 5 mm aqueous ammonium acetate containing 1 mm formic acid (60:40), at flow rate of 1 mL/min. The run time was 3.0 min and the injection volume was 20 μL. Mass spectrometric detection was performed using electrospray ion source in negative ionization mode, using the transitions m/z 364.0 → m/z 188.9 and m/z 367.0 → m/z 188.9 for indapamide and IS, respectively. Calibration curve was constructed over the range 0.25–50 ng/mL. The method was precise and accurate, and provided recovery rates >80% for indapamide and IS. The method was applied to determine blood concentrations of indapamide in a bioequivalence study with two sustained release tablet formulations. The 90% confidence interval for the geometric mean ratios for maximum concentration was 95.78% and for the area under the concentration–time curve it was 97.91%. The tested indapamide tablets (Eurofarma Laboratórios S.A.) were bioequivalent to Natrilix®, according to the rate and extent of absorption. Copyright © 2014 John Wiley & Sons, Ltd.     

Determination of triamcinolone in human plasma by a sensitive HPLC-ESI-MS/MS method: application for a pharmacokinetic study using nasal spray formulation

A liquid chromatography-electrospray ionization tandem mass spectrometry (HPLC-ESI-MS/MS) method for the quantitation of triamcinolone in human plasma after nasal spray application was developed and validated. Betamethasone was used as internal standard (IS). The analytes were extracted by a liquid-liquid procedure and separated on a Zorbax Eclipse XDB C(18) column with a mobile phase composed of 2 mM aqueous ammonium acetate pH 3.2 and acetonitrile (55:45). Selected reaction monitoring was performed using the transitions m/z 435 → 415 and m/z 393 → 373 to quantify triamcinolone acetonide and betamethasone, respectively. Calibration curve was constructed over the range of 20-2000 pg/ml for triamcinolone acetonide. The lower limit of quantitation was 20 pg/ml. The mean RSD values were 4.6% and 5.7% for the intra-run and inter-run precision, respectively. The mean accuracy value was 98.5% and a recovery rate corresponding to 97.5% was achieved. No matrix effect was detected in the samples. The validated method was successfully applied to determine the plasma concentrations of triamcinolone acetonide in healthy volunteers, in a pharmacokinetic study with nasal spray formulation.