Liquid chromatographic method for enantiopurity control of alaptide using polysaccharide stationary phases

Separation of veterinary drug alaptide ((S)-8-methyl-6,9-diazaspiro(4,5)decane-7,10-dione) from a chiral impurity (R-enantiomer) was developed. Five chiral columns (three amylose and two cellulose type) were evaluated in a reversed-phase system. Three of them offered satisfactory enantiomeric resolution. Finally, three methods were validated and proved to be applicable for the determination of a chiral impurity content below 0.1% (method A: 3-AmyCoat column, tris-[3,5-dimethylphenyl]carbamoyl amylose; mobile phase: water/methanol/propan-2-ol/butan-2-ol=75:20:3.5:1.5 v/v, flow rate: 0.40 mL/min; column temperature: 30 °C; method B: Chiralpak AS-3R, tris-[1-phenylethyl]carbamoyl amylose; water/acetonitrile=80:20 v/v, 0.40 mL/min; 40 °C; method C: Chiralcel OZ-3R, tris-[3-chloro-4-methylphenyl] carbamoyl cellulose; water/acetonitrile=80:20 v/v, 0.40 mL/min; 40 °C). Some decrease in efficiency with repeated sample injections was observed for the 3-AmyCoat column. The resistance to mass transfer in the stationary phase increased probably due to the change in chiral selector conformation. This effect was considerably suppressed by propan-2-ol or to a greater extent by butan-2-ol added to a mobile phase. Simple regeneration was also suggested to recover efficiency of the column.     

Influence of preferential adsorption of mobile phase on retention behavior of amino acids on the teicoplanin chiral selector

The adsorption behavior of two amino acids, i.e., l,d-threonine and l,d-methionine has been investigated on the chiral stationary phase (CSP)column packed with teicoplanin bonded to a silica support. The study has been performed under non-linear conditions of adsorption isotherm for various types of organic modifiers (methanol, ethanol, propan-2-ol and acetonitrile) in the reversed-phase mode. A heterogeneous adsorption mechanism of amino acids has been identified that was strongly affected by the nature of organic modifier. Generally, isotherm non-linearity and retention decreased with decrease of the modifier content in the mobile phase exhibiting a minimum at water-rich mobile phases. These trends were suggested to result from a combined effect of the mobile as well as the adsorbed phase composition. To determine the composition of the adsorbed phase the excess adsorption of modifiers in aqueous solutions has been measured and their binary adsorption equilibria have been quantified and compared. Strongly non-ideal behavior of solvents in the mobile phase and the adsorbed phase has been accounted for by activity coefficients. The fraction of the modifiers in the adsorbed phase decreased in the sequence: methanol, ethanol, propan-2-ol and acetonitrile.     

Separation of fluorescent 1,N6 ethenoderivatives of diadenosine polyphosphates and their enzymatic degradation products by reversed-phase high-performance liquid chromatography

Summary The retention, selectivity and elution order of fluorescent 1,N⁶-etheno derivatives of diadenosine polyphosphates and their enzymatic degradation products on octadecyl and phenyl-bonded silica columns have been studied as a function of mobile phase pH, ionic strength and organic modifier content. Good separations of the compounds of interest were achieved using mobile phases of around 0.1M potassium phosphate buffers at neutral pH containing approximately 10% methanol or 4% acetonitrile for C₁₈ columns and 5% methanol or 1.5% acetonitrile for phenyl columns. The data obtained were used to establish isocratic assays for diadenosine polyphosphate cleaving activities from chromaffin cells using Di(1,N⁶-ethenoadenosine) polyphosphates as fluorogenic substrate analogues followed by fluorescence detection.     

Use of the simplex method to optimize the mobile phase for the micellar chromatographic separation of inorganic anions

The sequential simplex strategy has been used to optimize the mobile phase used for separation of inorganic anions by micellar chromatography on a C(18)- micro Bondapak column, with absorption detection at 230 nm. The amount of acetonitrile and the concentration of phosphate buffer (pH 6.0) were chosen for optimization. The optimum mobile phase was found to be 38% acetonitrile in 18.2 mmol L(-1) phosphate buffer (pH 6.0) containing 10 mmol L(-1) cetyltrimethylammonium bromide (CTAB); this optimum was achieved within seven experiments. The separation of the five anions (nitrite, nitrate, iodide, thiocyanate, and thiosulfate) was accomplished in 18 min.     

Comparison of different HPLC systems for analysis of galantamine and lycorine in various species of Amaryllidaceae family

Retention parameters of galantamine and lycorine standards were determined on different columns, i.e., octadecyl silica, SM C18, and strong cation-exchange (SCX) columns with different aqueous mobile phases. Retention of alkaloids was investigated on C18, SM C18 columns with mobile phase containing 5% MeCN, 20% acetate buffer at pH 3.5, and 0.025 ML^?1 diethylamine (DEA), and on SCX column with mobile phase containing 8% MeCN and phosphate buffer at pH 2.5. Better results were also obtained in ion-exchange chromatographic system. On the basis of results obtained in different chromatographic systems, simple, rapid, and sensitive high-performance liquid chromatography methods were developed for determining lycorine and galantamine in plant extracts from various species belonging to Amaryllidaceae family. Extracts were prepared from various parts of plants collected at different times of the growing season.     

System Maps for Retention of Small Neutral Compounds on a Superficially Porous Ethyl-Bridged,Octadecylsiloxane-Bonded Silica Stationary Phase in Reversed-Phase Liquid Chromatography

The system constants of the solvation parameter model are used to prepare system maps for the retention of small neutral compounds on an ethyl-bridged, ocatadecylsiloxane-bonded superficially porous silica stationary phase (Kinetex EVO C18) for aqueous mobile phases containing 10–70% (v/v) methanol or acetonitrile. Electrostatic interactions (cation-exchange) are important for the retention of weak bases with acetonitrile–water but not methanol–water mobile phase compositions. Compared with a superficially porous octadecylsiloxane-bonded silica stationary phase (Kinetex C18) with a similar morphology but different topology statistically significant differences in selectivity at the 95% confidence level are observed for neutral compounds that vary by size and hydrogen-bond basicity with other intermolecular interactions roughly similar. These selectivity differences are dampened with acetonitrile–water mobile phases, but are significant for methanol–water mobile phase compositions containing <30% (v/v) methanol. A comparison of a totally porous ethyl-bridged, octadecylsiloxane-bonded silica stationary phase (XBridge C18) with Kinetex EVO C18 indicated that they are effectively selectivity equivalent.     

Chromatographic methods for the separation of biocompatible iron chelators from their synthetic precursors and iron chelates

Chromatographic methods have been developed for the separation of the three novel biocompatible iron chelators pyridoxal isonicotinoyl hydrazone (PIH), salicylaldehyde isonicotinoyl hydrazone (SIH), and pyridoxal 2-chlorobenzoyl hydrazone (o-108) from their synthetic precursors and iron chelates. The chromatographic analyses were achieved using analytical columns packed with 5 microm Nucleosil 120-5 C18. For the evaluation of all chelators in the presence of the synthetic precursors, EDTA was added to the mobile phase at a concentration of 2 mM. The best separation of PIH and its synthetic precursors was achieved using a mixture of phosphate buffer (0.01 M NaH2PO4, 5 mM 1-heptanesulfonic acid sodium salt; pH 3.0) and methanol (55:45, v/v). For separation of SIH and its synthetic precursors, the mobile phase was composed of 0.01 M phosphate buffer (pH 6.0) and methanol (60:40, v/v). o-108 was analyzed employing a mixture of 0.01 M phosphate buffer (pH 7.0), methanol, and acetonitrile (60:20:20, v/v/v). These mobile phases were slightly modified to separate each chelator from its iron chelate. Furthermore, a RP-TLC method has also been developed for fast separation of all compounds. The chromatographic methods described herein could be applied in the evaluation of purity and stability of these drug candidates.     

Analysis of Non-Selective Calcium-Channel Blockers by Reversed-Phase TLC

The selectivity of TLC separation of non-selective calcium-channel blockers prenylamine, lidoflazine, bepridil, and fendiline has been investigated silanized silica gel RP8 and RP18 plates. Optimization of retention and selectivity for these compounds was achieved by altering the pH and the concentration of organic modifier (methanol, ethanol, tetrahydrofuran, acetonitrile) in the aqueous mobile phases. The substances were separated in horizontal chambers and the drugs were detected by videoscanning and illumination of the plates at λ = 254 nm. On RP8 plates the best separation was achieved with 50% acetonitrile in pH 2.06 phosphate buffer as mobile phase. On RP18 the best separation was achieved with 50% ethanol in pH 2.06 phosphate buffer.

     

Optimization of chromatography to overcome matrix effect for reliable estimation of four small molecular drugs from biological fluids using LC–MS/MS

The article describes a systematic study to overcome the matrix effect during chromatographic analysis of gemfibrozil, rivastigmine, telmisartan and tacrolimus from biological fluids using LC–ESI–MS/MS. All four methods were thoroughly developed by the appropriate choice of analytical column, elution mode and pH of mobile phase for improved chromatography and overall method performance. Matrix effect was assessed by post-column analyte infusion, slope of calibration line approach and post-extraction spiking. The best chromatographic conditions established were: Acquity BEH C₁₈ (50 × 2.1 mm, 1.7 μm) column with 5.0 mm ammonium acetate, pH 6.0–methanol as the mobile phase under gradient program for gemfibrozil; Luna CN (50 × 2.0 mm, 3 μm) column with a mobile phase consisting of acetonitrile–10 mm ammonium acetate, pH 7.0 (90:10, v/v) for rivastigmine; Inertsustain C₁₈ (100 × 2.0 mm, 5 μm) column using methanol–2.0 mm ammonium formate, pH 5.5 (80: 20, v/v) as the mobile phase for isocratic elution of telmisartan; and Acquity BEH C₁₈ (50 × 2.1 mm, 1.7 μm) with methanol–10 mm ammonium acetate, pH 6.0 (95:5, v/v) as mobile phase for tacrolimus. The methods were thoroughly validated as per European Medicines Agency and US Food and Drug Administration guidance and were successfully applied for pharmacokinetic studies in healthy subjects.     

Ultra high-performance liquid chromatography of porphyrins in clinical materials: column and mobile phase selection and optimisation

Ultra high-performance liquid chromatographic (UHPLC) systems on columns packed with materials ranging from 1.9 to 2.7 μm average particle size were assessed for the fast and sensitive analysis of porphyrins in clinical materials. The fastest separation was achieved on an Agilent Poroshell C(18) column (2.7 μm particle size, 50 × 4.6 mm i.d.), followed by a Thermo Hypersil Gold C(18) column (1.9 μm particle size, 50 × 2.1 mm i.d.) and the Thermo Hypersil BDS C(18) column (2.4 μm particle size, 100 × 2.1 mm i.d.). All columns required a mobile phase containing 1 m ammonium acetate buffer, pH 5.16, with a mixture of acetonitrile and methanol as the organic modifiers for optimum resolution of the type I and III isomers, particularly for uroporphyrin I and III isomers. All UHPLC columns were suitable and superior to conventional HPLC columns packed with 5 μm average particle size materials for clinical sample analysis.     

Determination of Ampicillin in Plasma by Paired Ion High Performance Liquid Chromatography

Abstract

A new, accurate, precise, and specific method has been developed for the assay of ampicillin in plasma. No extraction of ampicillin from plasma is called for. Plasma is treated with acetonitrile containing propiophenone as the internal standard, vortexed, centrifuged, and the supernate is injected. A C18 reverse phase column is used. The mobile phase consisted of a mixture of methanol and 0.02M phosphate buffer of pH 6.00, and contained alkyldimethylamine C10 as an ion pair ligand. Detection was by UV at 220 nm. A linear relationship between concentration and peak area ratio was obtained. Recovery, day-to-day, and within-day variation were determined.     

A Comparison of Radially-Compressed and Stainless Steel Columns for the Reversed-Phase Ion-Pair Separation of Phencyclidine Synthetic Mixtures

Abstract

The reversed-phase ion-pair HPLC separation of phencyclidine synthetic mixtures was optimized utilizing Radial-Pak radially compressed columns. Variables examined in the optimization included column type (C-18, C-8, or CN), pairing ion (methane-, pentane-, hexane-, or octane sulfonates) and mobile phase composition (varying concentrations of methanol or acetonitrile in water). The chromatographic behavior of the phencyclidine mixtures in the various systems utilizing radially compressed columns is compared and contrasted to a similar previous study which examined similar variables on stainless steel columns. The optimum system for radially compressed columns was found to consist of a Radial-Pak C-18 column and a mobile phase of 85:15 MeOH:H₂O, 2.5% acetic acid, 1% triethylamine and 5mM sodium hexane sulfonate.     

The drug interaction potential of berberine hydrochloride when co-administered with simvastatin,fenofibrate, gemfibrozil,metformin, glimepiride,nateglinide, pioglitazone and sitagliptin in beagles

Berberine (BBR) hydrochloride is a traditional Chinese medicine with unique hypoglycemic and lipid-lowering effects discovered in recent years. The combination of BBR with other hypoglycemic drugs and lipid-lowering drugs could become a promising treatment strategy. With the aim of evaluating the potential drug-drug interaction (DDI) based on the pharmacokinetics between BBR and simvastatin, fenofibrate, gemfibrozil, metformin, glimepiride, nateglinide, pioglitazone and sitagliptin in beagles, an UPLC-MS/MS method has been developed and validated. The analytes and internal standards were extracted from plasma samples using a magnetic solid phase extraction technique, and then separated by a Luna® Omega C₁₈ column (20.0 × 2.0 mm, 1.6 μm) with water containing 3 mM ammonium and 0.1% formic acid and acetonitrile containing 3 mM ammonium and 0.1% formic acid as the mobile phase. Validation of the UPLC-MS/MS method was carried out following the criteria of the Chinese Pharmacopeia, mainly including specificity, carryover, calibration curve, crosstalk, precision, accuracy, dilution integrity, matrix effect, recovery and stability. The results showed that all the criteria of the method validation met the Chinese Pharmacopoeia guidelines, and the proposed UPLC-MS/MS method was proven to be sensitive, simple and specific to determine all the analytes in the beagles’ plasma samples simultaneously. Meanwhile, the potential DDI between BBR and simvastatin, fenofibrate, gemfibrozil, metformin, glimepiride, nateglinide, pioglitazone and sitagliptin was confirmed in this paper, especially for simvastatin, fenofibrate, gemfibrozil and glimepiride.     

Evaluation of an International Pharmacopoeia method for the analysis of nelfinavir mesilate by liquid chromatography

A gradient LC method for the determination of related substances in nelfinavir mesilate (NFVM) has been recently published in the International Pharmacopoeia. The method uses a base deactivated reversed phase C18 column (25 cm x 4.6 mm I.D.), 5 microm kept at a temperature of 35 degrees C. The mobile phases consist of acetonitrile, methanol, phosphate buffer pH 3.4 and water. The flow rate is 1.0 ml/min. UV detection is performed at 225 nm. A system suitability test (SST) is described to govern the quality of the separation. The separation towards NFVM components was investigated on 18 C18 columns and correlation was made with the column classification system developed in our laboratory. The method was evaluated using a Hypersil BDS C18 column (25 cm x 4.6 mm I.D.), 5 microm. A two level fractional factorial design was applied to examine the robustness of the method. The method shows good selectivity, precision, linearity and sensitivity. Seven commercial samples were examined using this method.     

Studies on the electrochemical behavior of thiazolidine and its applications using a flow-through chronoamperometric sensor based on a gold electrode

The electrochemical behaviors of thiazolidine (tetrahydrothiazole) on gold and platinum electrodes were investigated in a Britton-Robinson buffer (pH 2.77-11.61), acetate buffer (pH 4.31), phosphate buffer solutions (pH 2.11 and 6.38) and methanol or acetonitrile containing various supporting electrolytes. Detection was based on a gold wire electrochemical signal obtained with a supporting electrolyte containing 20% methanol-1.0 mM of phosphate buffer (pH 6.87, potassium dihydrogen phosphate and dipotassium hydrogen phosphate) as the mobile phase. Comparison with results obtained with a commercial amperometric detector shows good agreement. Using the chronoamperometric sensor with the current at a constant potential, and measurements with suitable experimental parameters, a linear concentration from 0.05 to 16 mg L-1 was found. The limit of quantification (LOQ) of the method for thiazolidine was found to be 1 ng.     

Duplicating the Retention of Cationic Analytes Obtained with Ammonium Formate Mobile Phases when Switching to UV Transparent Mobile Phase Additives in RP-LC

This study explored feasibility of utilizing sodium phosphate and mixtures of sodium phosphate and sodium perchlorate salts in mobile phases as UV transparent alternatives to the ammonium formate salts commonly used in LC–MS mobile phases. Chromatography experiments were run at pH 3.5 in 25% acetonitrile mobile phase, using several model cationic analytes to evaluate cation retention on two different C18 columns as the type or amount of salt was varied. For both columns, phosphate consistently showed less cation retention than formate. In other respects, the two columns showed very different behavior. The study suggests that it is feasible to use UV transparent mobile phase additives to provide comparable cation retention of formate mobile phases, but that the exact composition needed for optimal retention agreement is column dependent.     

Development of a novel,fast, simple,nonderivative HPLC method with direct UV measurement for quantification of memantine hydrochloride in tablets

Fast, simple, accurate, and reproducible reverse phase‐high‐performance liquid chromatography method with direct ultraviolet measurement of memantine hydrochloride in tablets was developed, without any chemical derivatization pretreatment. Three main problems appear during chromatographic analysis of memantine: detection, achieving appropriate column retention, and limited choice of mobile phase components, as a result of memantine molecular structure. Among more than 35 tested columns, the best retention and peak symmetry yielded two C8 and three C18 columns with different characteristics, at a temperature of 30°C, mobile phase composed of 1%, v/v, acetonitrile and 99%, v/v, of 0.05–0.1% phosphoric acid or 2.5–5 mmol phosphate buffer, at flow rate of 1 mL/min and injection volume of 5 µL. The retention time of memantine was between 2.6 and 4 min. Both mobile phase concepts showed perfect linearity, precision, and accuracy. This is the first successful and reproducible direct reverse phase‐high‐performance liquid chromatography–ultraviolet quantification method for memantine.     

High Performance Liquid Chromatographic Assay for Adinazolam Mesylate in Rodent Feed Mixtures

Abstract

Adinazolam mesylate was recovered from the feed mixtures by repeated extraction with a pH 4 citrate buffer. The pooled extracts were diluted with water when necessary and mixed with an equal volume of an acetonitrile solution of internal standard (naphthalene). After mixing and centrifugation, the clear supernates were separated for chromatography. The chromatography was carried out on a reverse phase column using a mixture of phosphate buffer, acetonitrile and methanol in the volume ratios of 85:40:20 as mobile phase. Adinazolam and the internal standard were eluted from the columns at about 11.7–12 and 15.50–17.5 minutes, respectively.

The peak height ratios and adinazolam mesylate concentrations showed excellent linearity (r>0.999). Extracts of blank feed samples did not show interference to the assay. Assay results with satisfactory accuracy and precision were obtained. The methodology was applicable for the assay of the drug-feed mixtures containing 0.02 to 10.0 mg of adinazolam mesylate per gm of feed.     

Optimized stationary phases for the high-performance liquid chromatography-electrospray ionization mass spectrometric analysis of basic pharmaceuticals

Stationary phases were investigated for HPLC coupled with electrospray ionization mass spectrometry (ESI-MS) for the analysis of basic drugs. Tricyclic antidepressants (TCAs) and beta-blockers were used as model solutes. The functional groups, pentafluorophenyl (PFP), OH, CN or CH3 were attached to the silica via a propyl chain. The effects of these stationary phases as well as C8 and C18 phases on retention and peak shape of the basic drugs were studied. The CN and PFP phases adequately retained (tR of 2 to 6 min) the basic drugs when the mobile phase was composed of 90% acetonitrile, whereas with the C4, C8 and C18 phases, less than 40% acetonitrile had to be used to provide adequate retention of the basic drugs. Because acetonitrile provides better desolvation in ESI than an aqueous solvent, it produces an increased MS signal. As an example of the HPLC-ESI-MS analysis of the beta-blocker, pindolol, on a CN phase, the use of 90% acetonitrile in the mobile phase increased the ESI-MS signal by 790% when compared to a C18 phase which could use only 5% acetonitrile in the mobile phase for retention of the solute. In addition, the CN and PFP phases provided better peak shape than the OH phase and the hydrophobic phases (C4, C8 and C18) and ion-pairing or ion-suppressing agents were not required. The retention behavior of the TCAs and beta-blockers on each of the phases is described.     

Comparison of zirconia- and silica-based reversed stationary phases for separation of enkephalins

In this study, the separation of biologically active peptides on two zirconia-based phases, polybutadiene (PBD)-ZrO2 and polystyrene (PS)-ZrO2, and a silica-based phase C18 was compared. Basic differences in interactions on both types of phases led to quite different selectivity. The retention characteristics were investigated in detail using a variety of organic modifiers, buffers, and temperatures. These parameters affected retention, separation efficiency, resolution and symmetry of peaks. Separation systems consisting of Discovery PBD-Zr column and mobile phase composed of a mixture of acetonitrile and phosphate buffer, pH 2.0 (45:55, v/v) at 70 degrees C and Discovery PS-Zr with acetonitrile and phosphate buffer, pH 3.5 in the same (v/v) ratio at 40 degrees C were suitable for a good resolution of enkephalin related peptides. Mobile phase composed of acetonitrile and phosphate buffer, pH 5.0 (22:78, v/v) was appropriate for separation of enkephalins on Supelcosil C18 stationary phase.