Hydrophilic interaction chromatography with aerosol-based detectors (ELSD, CAD, NQAD) for polar compounds lacking a UV chromophore in an intravenous formulation.

In this work, a high performance liquid chromatography (HPLC) method is reported for the separation and quantitation of a drug substance that is highly polar and lacking a chromophore in a mannitol intravenous (IV) formulation. Three polar stationary phases operated in hydrophilic interaction chromatography (HILIC) mode were evaluated in conjunction with an Alltech 800 ELSD detector. These columns were evaluated with respect to chromatographic properties such as buffer, pH and organic concentrations to identify the best stationary phase. The chromatographic method was then validated for the determination of mGlu2/3 receptor agonist (-)-(1R, 4S, 5S, 6S)-4-Amino-2-sulfonylbicyclo [3.1.0] hexane-4,6-dicarboxylic acid (LY404039) content in a mannitol IV formulation with respect to linearity (R(2) of 0.9997), repeatability (%RSD of 0.36%), accuracy, solution stability (99.56% after 24h), specificity, intra-assay precision (%RSD 0.48%) and limit of detection (LOD, ∼50 µg/mL). In addition to the Alltech 800 ELSD detector, several other aerosol-based detectors were investigated for reproducibility, linearity and LOD. These additional detectors consisted of an Alltech 3300 evaporative light scattering detector (ELSD), a nano quantity analyte detector (NQAD) and a charged aerosol detector (CAD). Based on the data from this report, a feasible isocratic LC method was achieved using a TSKgel Amide-80 column with mobile phase conditions of 30% water with 0.2% trifluoroacetic acid (TFA) and 70% acetonitrile (ACN) using any of the four aerosol-based detectors for detection and quantitation.

A systematic approach to development of liquid chromatographic impurity methods for pharmaceutical analysis.

A strategy for developing chromatographic methods designed to determine impurities and degradation products in active pharmaceutical ingredients and drug products is presented. Selectivity is achieved by evaluating a chromatographic space comprised of 12 stationary/mobile phase combinations. Stationary phases predicted to be orthogonal based on their hydrophobic subtraction model parameters used. The particle sizes, column dimensions, and gradient times chosen provide high peak capacities and allow operation at backpressures that can be achieved with standard instrumentation. The mobile phases utilized are compatible with MS detection and cover a wide range of pH, solvent strength, and solvent selectivity. Analyte detection is accomplished using a combination of diode array and mass spectroscopic detectors which allow mixtures of project compounds to be injected and selectively detected. Automation of data acquisition and processing is accomplished using AutoChrom software from ACD\Labs. The strategy is illustrated with detailed data from two case studies and summary data from nineteen pharmaceutical projects.

Evaluating the performances of quantitative structure-retention relationship models with different sets of molecular descriptors and databases for high-performance liquid chromatography predictions.

Quantitative structure-retention relationship (QSRR) models were studied for two databases: one with 151 compounds and the other with 1719 compounds. In both cases, the three modeling methods employed (multiple linear regression, partial least squares, and random forests) provided similar prediction results with regard to root-mean-square error of prediction. The reversed-phase retention related seven molecular descriptors provided better models for the smaller dataset, while the use of over 2000 molecular descriptors generated better models for the larger dataset. The QSRR models were then validated with a mixture of an active pharmaceutical ingredient and its four process/degradation impurities. Finally, classification of compounds based on similar logD profiles before QSRR modeling improved chromatographic predictability for the models used. The results showed that database composition had a desirable effect on prediction accuracy for certain input molecules.

Very high-pressure capillary liquid chromatography assisted by voltage.

Capillary liquid chromatography at moderately high pressures and capillary electrochromatography (CEC) have been combined to drive the mobile phase through capillary columns packed with small diameter particles. In a column packed with 1.5 microm nonporous particles, linear velocities near 3mm/s were observed when combining inlet pressures of 690 bar (10,000 psi) and an applied voltage of 25 kV. Optimum linear velocity for the column was achieved using a pressure-voltage combination of 350 bar (5000 psi) and 5 kV. Separation efficiencies at near optimum linear velocity agreed with those predicted by the van Deemter equation for liquid chromatography. Retention factors were observed to decrease under pressure-voltage combination as the voltage was increased; such a behavior has been attributed to Joule heating effects.

Very high pressure HPLC with 1 mm id columns.

Theoretical calculations and experimental data indicate that very high pressure HPLC can be performed using 1 and 1.5 mm id columns, and contrary to previous beliefs, the frictional heating generated does not appear to be detrimental to the separation.

Organo-silica nano-particles used in ultrahigh-pressure liquid chromatography.

A simple one-step process was used to synthesize uniform, spherical organosilica nano-particles containing octadecyl moieties. These nano-particles, having a diameter of 670 nm, were slurry packed into fused-silica capillary tubes of 50 microm internal diameter and tested for use in ultrahigh-pressure liquid chromatography (UHPLC) at inlet pressures of about 50,000 psi (approximately 3,500 bar), providing for the use of HPLC with nano-particle packed columns. The retention characteristics of a column packed with the organo-nano-particles were shown to be stable under acidic (pH < 1) and basic (pH > 11) conditions. Fast analysis times and relatively high separation efficiencies (approximately 500,000 plates m(-1)) were obtained under the conditions used.