Quantitative determination by high-performance liquid chromatography of acetylsalicylic acid and related substances in tablets

High-performance liquid chromatography on a Zorbax C8 7-micron column (25 cm X 0.46 cm I.D.) with methanol-water-1 M phosphoric acid (59:36:5) as the mobile phase has been used for the analysis of several naturally aged batches of fourteen brands of acetylsalicyclic acid tablets. The extraction solvent is methanol, containing 2% v/v of formic acid. Salicylic acid is the main impurity. Acetylsalicylsalicylic acid is the second most important impurity, and the corresponding salicylsalicylic acid is rarely present. Buffered or dispersible tablets contain relatively more of the latter two impurities and eventually also the corresponding higher oligomers. Acetylsalicylic anhydride is always a minor impurity. Comparison is made with classical spectrophotometric methods, which are observed to be selective for salicylic acid.     

Simultaneous determination of dopa and carbidopa enantiomers by capillary zone electrophoresis

Dopa and carbidopa, components of the dual therapy for Parkinson's disease treatment, are both provided as single enantiomers, since their D-forms are inactive. To ensure the efficiency and safety of the therapy, these D-enantiomers, therefore, should be considered as impurities. In this paper, the enantioseparation power of different types of cyclodextrins, both neutral and charged ones, on dopa and carbidopa enantiomers was tested. Three methods of simultaneous separation of dopa and carbidopa enantiomers were developed, using highly sulfated beta-cyclodextrin and sulfated beta-cyclodextrin as chiral selector, in normal and reversed polarity mode. Two methods among these three were found sensitive enough for the quantitation of 0.1% D-enantiomers in L-forms (impurity level). After the optimization study, the best method was selected, using 16 mM sulfated beta-cyclodextrin in 15 mM sodium phosphate buffer pH 2.45, an uncoated fused-silica capillary (50 num inner diameter, 30 cm total length), and an applied voltage of -12 kV. This method is robust and efficient, with very high resolution for all peaks within a short analysis time of 10 min. Quantitatively, the method offers a limit of detection (LOD) of 0.2 nug/mL and a limit of quantitation (LOQ) of 0.5 nug/mL for both D-dopa and D-carbidopa, which is equivalent to 0.02% and 0.05% against the respective L-enantiomers. A linear relationship was found between the concentration of the analyte and the corresponding peak area in a range of 0.5-2.0 nug/mL.     

Liquid chromatography of erythromycin A and related substances on poly(styrene-divinylbenzene)

Summary An isocratic liquid chromatography method for assay and purity control of erythromycin is presented. Erythromycin A is separated from all its potential impurities, except erythromycin D. The selectivity depends on the pore size of the poly(styrene-divinylbenzene) stationary phase. Wide pore PLRP-S 8 μm 1000 ? shows the best selectivity. The column is heated at 70°C. The mobile phase is acetonitrile-2-methyl-2-propanol-0.2 M potassium phosphate buffer pH 9.0-water (3:16.5:5:75.5). The flow rate is 2 ml/min. UV detection is performed at 215 nm. The total analysis time is about 30 min. The method was used to compare official standards.     

Separation of erythromycin and related substances by high-performance liquid chromatography on poly(styrene-divinylbenzene) packing materials

A comparative evaluation of three brands of poly(styrene-divinylbenzene) copolymers, Hamilton PRP-1 (10 micron), Rogel (8 micron) and TSK-Gel (10 micron), as column packing materials for high-performance liquid chromatographic separation of erythromycins is presented. Erythromycins A, B and C, anhydroerythromycin A, erythromycin A enol ether, N-demethylerythromycin A, anhydro N-demethylerythromycin A and N-demethylerythromycin A enol ether were chromatographed. The effects of column temperature, concentration of organic modifier in the mobile phase, concentration of phosphate buffer, the addition of quaternary ammonium salts and pH are described. The best separations were obtained on TSK-Gel with the mobile phase acetonitrile-methanol-0.2 M tetramethylammonium hydroxide pH 8.0-0.2 M phosphate buffer pH 8.0-water (30:15:25:5:25). PRP-1 and Rogel gave equally good separations but with higher retention volumes.     

Analysis of spectinomycin by liquid chromatography with pulsed electrochemical detection

Until now, no LC method is described to determine the purity and content of spectinomycin without prior derivatization. A reversed-phase ion-pair LC method using a base deactivated column and pulsed electrochemical detection is described. The mobile phase consisted of an aqueous solution containing 5.8 g/l pentafluoropropionic acid, 1.25 g/l potassium dihydrogen phosphate and 5.5 ml/l tetrahydrofuran. The pH was adjusted to 6.25 using dilute NaOH solution. An experimental design was used to optimize the chromatographic parameters and to check the robustness. The quality of separation was investigated on different stationary phases. The method allows the separation of spectinomycin from its related substances as well as some other components of unknown identity. The total time of analysis is 65 min. A number of commercial samples were examined using this method.     

Liquid chromatography of gramicidin

Summary A simple, selective method is described for separation of more than 10 gramicidin components on Spherisorb ODS B, 5 μm,250×4.6 mm I.D. column, maintained at 50°C. The mobile phase comprised methanol-water (71:29) at a flow rate of 1.0 mL min⁻¹. Detection was by UV at 282 nm. Valine gramicidins A, B and C were very well separated from the isoleucine gramicidins A, B and C. Four new gramicidin components were also resolved and their structures determined by liquid chromatography/ mass spectrometry. The names 10-methionine valine gramicidin C, 4-methionine valine gramicidin A, valine gramicidin A hydroxypropyl and isoleucine gramicidin A hydroxypropyl were proposed. Robustness of the liquid chromatography method was evaluated by performing a full factorial design experiment. The method also showed good repeatability, linearity and sensitivity.