Chemometric quality control of chromatographic purity

It is common practice in chromatographic purity analysis of pharmaceutical manufacturing processes to assess the quality of peak integration combined by visual investigation of the chromatogram. This traditional method of visual chromatographic comparison is simple, but is very subjective, laborious and seldom very quantitative. For high-purity drugs it would be particularly difficult to detect the occurrence of an unknown impurity co-eluting with the target compound, which is present in excess compared to any impurity. We hypothesize that this can be achieved through Multivariate Statistical Process Control (MSPC) based on principal component analysis (PCA) modeling. In order to obtain the lowest detection limit, different chromatographic data preprocessing methods such as time alignment, baseline correction and scaling are applied. Historical high performance liquid chromatography (HPLC) chromatograms from a biopharmaceutical in-process analysis are used to build a normal operation condition (NOC) PCA model. Chromatograms added simulated 0.1% impurities with varied resolutions are exposed to the NOC model and monitored with MSPC charts. This study demonstrates that MSPC based on PCA applied on chromatographic purity analysis is a powerful tool for monitoring subtle changes in the chromatographic pattern, providing clear diagnostics of subtly deviating chromatograms. The procedure described in this study can be implemented and operated as the HPLC analysis runs according to the process analytical technology (PAT) concept aiming for real-time release.     

Classification of chromatographic data using multidimensional polynomials

Summary A pattern recognition methodology has been developed for analysis of chromatographic data. The method uses a new class of multidimensional orthogonal polynomials developed by Cohen in conjunction with a supervised learning technique. The method is applicable to any chromatographic data for which classification into two or more categories is desired. The algorithm analyzes both elution times and peak areas. An application is shown for the analysis of organic acids in ascitic fluid obtained from patients with liver disorders. Classification of these patients for presence or absence of bacterial infection shows over ninety percent correct classification.     

Chracterization of polyaniline using chromatographic studies

Summary The use of polyaniline as a chromatographic stationary phase has been examined. In the course of this work the column packing material was prepared by coating silica particles with polyaniline chloride. The aniline monomer was polymerised directly on the surface of the silica particles using a chemical method and was characterised using elemental analysis. A series of standard test compounds were employed for chromatographic characterization. The studies revealed information on the practical utility as well as the molecular interactions that took place on the stationary phase.     

Gas chromatographic analysis of chlorophenylmercapturic acid lindane metabolites

An analytical method for phenols has been adapted for the analysis of chlorophenylmercapturic acids in rat urine. Chlorothiophenols were produced from the mercapturic acids by hydrolytic cleavage with sodium hydroxide. Acetate esters of the chlorothiophenols were formed by addition of acetic anhydride to the aqueous alkaline solution. After acylation, the acetate derivatives were extracted into hexane. Forming the acetate esters of the chlorothiophenols prevented their oxidation to disulfides and significantly improved their chromatographic properties. Electron-capture gas chromatographic analysis of the stable acetate esters was performed on a mixed phase column, 4% SE-30 + 6% OV-210. Recoveries of four chlorothiophenols ranged from 82 to 93%. This method required no sample transfer steps; therefore, sample loss and analysis time were minimized.     

高聚物型反相高效液相色谱柱分析多西环素的初步研究

采用高聚物型苯乙烯-二乙烯基苯(PS-DVB)色谱填料的麦科菲反相高效液相色谱柱(MKF-RP-ZH)分析多西环素.对流动相中的叔丁醇,离子对试剂,EDTA的含量和pH条件进行了优化.最优的条件下多西环素样品分离柱效达到4036.     

Importance of quality control in a gas chromatographic method to characterize crude oils

A quality control scheme has been developed to achieve reproducible capillary GC characterization of crude oils and petroleum condensates. The method uses an internal standard to quantify the amount of non-eluted material in the crude oil sample. Correlation between the gas chromatographic results and actual distillation was 2 %. After repeated use, however, weekly analysis of the same standard crude oil did not give the correct composition. This was a result of discrimination, which worsened with time, as a result of leaks in the septum or the graphite ferrules. More reproducible results were obtained by performing frequent analyses of quality control samples to ensure that the gas chromatographic system was operating properly. The use of quality control charts was a convenient way of ensuring correct operation and identifying the need for corrective action on the gas chromatographic system.     

High-performance liquid chromatographic determination of bleomycins.

A rapid and specific ion-pair reversed-phase high-performance liquid chromatographic method was developed for the determination of bleomycins. The use of 5-microns particles of less adsorptive reversed-phase packings and sodium perchlorate as ion-pairing reagent permitted a short analysis time and the transferability of the separations on different batches of the reversed-phase materials. The detection sensitivity and precision of the method demonstrated that the system is suitable for routine analysis.     

Gas chromatographic analysis of 1,4-naphthoquinones

Summary A gas chromatographic method is described for the analysis of 1,4-naphthoquinone derivatives in the mixtures of their isomers. The best results were obtained using 7.5% XE-60 on Chromosorb G at 180°. Quantitative determination was carried out with 1,4-naphthoquinone as the internal standard and using relative response factors or by means of the direct calibration method.     

High-performance liquid chromatographic determination of Tornalate in solution dosage forms; a specificity study

A reversed-phase high-performance liquid chromatographic method has been applied utilizing ion-pairing to measure Tornalate in solution dosage forms. Specificity of the method was demonstrated by selectivity for Tornalate analysis, analysis of stressed samples and by peak homogeneity tests. These included the diode-array derived spectral overlay test and fraction collection with rechromatography in an alternate normal phase system. Linearity was also demonstrated in terms of recovery from synthetic samples and detector response.     

Continuous melting and ion chromatographic analyses of ice cores

A new method for determining concentrations of organic and inorganic ions in ice cores by continuous melting and contemporaneous ion chromatographic analyses was developed. A subcore is melted on a melting device and the meltwater produced is collected in two parallel sample loops and then analyzed simultaneously by two ion chromatographs, one for anions and one for cations. For most of the analyzed species, lower or equal blank values were achieved with the continuous melting and analysis technique compared to the conventional analysis. Comparison of the continuous melting and ion chromatographic analysis with the conventional analysis of a real ice core segment showed good agreement in concentration profiles and total amounts of ionic species. Thus, the newly developed method is well suited for ice core analysis and has the advantages of lower ice consumption, less time-consuming sample preparation and lower risk of contamination.     

Design of experiment techniques for the optimization of chromatographic analysis conditions: A review

Design of experiment (DoE) techniques have been widely used in the field of chromatographic parameters optimization as a valuable tool. A systematic literature review of the available DoE techniques applied to the development of a chromatographic analysis method is presented in this paper. First, the most common available designs and the implementation steps of DoE are comprehensively introduced. Then the studies in recent 10 years for the application of DoE techniques in various chromatographic techniques are discussed, such as capillary electrophoresis, liquid chromatography, gas chromatography, thin-layer chromatography, and high-speed countercurrent chromatography. Current problems and future outlooks are finally given to provide a certain inspiration of research in the application of DoE techniques to the different chromatographic techniques field. This review contributes to a better understanding of the DoE techniques for the efficient optimization of chromatographic analysis conditions, especially for the analysis of complex systems, such as multicomponent drugs and natural products.     

Capillary chromatographic analysis of volatile organic compounds in the indoor environment

The wide variety of volatile organic compounds found in the indoor environment can present a difficult chromatographic problem for the analyst. Capillary-column gas chromatography is required to achieve adequate separation. Thermal desorption/capillary gas chromatography/mass spectrometry is usually the preferred method for broad spectrum analysis of the volatile organics detected indoors. Cryogenic trapping is required for capillary gas chromatographic analysis of the more volatile components.     

Chemometrics for the analysis of chromatographic data in metabolomics investigations

Metabolomics aims to better understand biological systems through the chemical analysis of an organism's metabolic profile. One common method of analysis is mass spectrometry preceded by chromatographic separations. Samples produced by metabolomics investigations can contain hundreds to thousands of compounds, which can put great strain on the instrumental analysis. In order to improve these analyses, the data analysis must not be overlooked. The ever‐evolving field of chemometrics provides many useful tools for the analysis of chromatographic data. These include methods for preprocessing data to extract a maximum amount of information from the data as well as pattern recognition in order to find the compounds that vary the most in relation to the perturbation to the biological system under study. This article aims to highlight and provide future outlooks on current chemometric methods for chromatographic‐based metabolomics investigations. Copyright © 2014 John Wiley & Sons, Ltd.     

Ultra-short columns and ballistic gradients: considerations for ultra-fast chromatographic liquid chromatographic-tandem mass spectrometric analysis

Ultra-fast chromatographic separations has enabled fast chromatographic method development and rapid analysis for sample quantification. Decreasing over-all analytical time has become a factor of major importance for all aspects of drug discovery. However, merely decreasing chromatographic analysis time by decreasing k' can lead to inconsistent quantitative or qualitative results due to ineffective separations in complex matrices. We have found that by changing column length and gradient slope we can maintain chromatographic integrity of chemically diverse analytes and achieve the analytical speed required for bioanalytical drug discovery quantitative analysis. We have optimized method development strategy by performing separations on 2x20 mm HPLC columns at flow-rates of 1.5 ml/min to 2 ml/min with full linear gradients achieved in 1 min for the quantification of pharmaceuticals and their metabolites from biological matrices. This method development strategy can be readily adapted to other matrices. This paper will discuss the effects of column length and gradient time in ultra-fast chromatographic resolution.     

Gas chromatographic method for the analysis of nitrochlorobenzene isomers

Summary An efficient, reproducible and rapid gas chromatographic method for the analysis of nitrochlorobenzenes has been described in this paper. The method uses FFAP as stationary phase and 3,4-dichloronitrobenzene as internal standard. The total analysis time of the method is less than 15 minutes with a coefficient of variation ranging from 0.41% to 1.19% for different levels of three isomers.     

Comparison of methods for characterization of reversed-phase liquid chromatographic selectivity

The goal of the present work is to obtain a better understanding of the chemical factors affecting liquid chromatographic retention. One of the most commonly used formats for liquid chromatographic separations is based on a nonpolar stationary phase, typically an octadecyl-derivatized silica material. A wide variety of these reversed-phase columns are commercially available that differ significantly in their chromatographic retention and selectivity. We seek to quantitatively characterize these differences. Retention data for a range of compounds with many diverse characteristics have been measured on several different octadecyl silica columns (J. Chromatogr. A, submitted for publication). Principal components analysis is used to characterize the different properties of these stationary phases and predict retention factors. The key set factor analysis method and the typical solute method are used in conjunction with the principal components analysis to identify small subsets of solutes that can be used to quantitatively describe the retention of a broad range of compounds. In addition, a quantitative comparison to alternative data analysis methods is made, including linear solvation energy relationships and an iterative subtraction method based on linear regression techniques. Although many earlier studies have reported the application of these methods, this study is the first to make a quantitative comparison of these methods using a highly precise and structurally variable set of test compounds.     

High-performance liquid chromatographic determination of amphotericin B in a liposomal pharmaceutical product and validation of the assay

A validated high-performance liquid chromatographic method is presented to quantitate amphotericin B (AB) in a liposomal pharmaceutical formulation. The analysis is based on the chromatographic separation of AB and 1-amino-4-nitronaphthalene (the internal standard) on a C18 muBondapac reversed-phase column with a mobile phase consisting of a mixture of acetonitrile and 0.02 M ethylenediamine tetra-acetic acid disodium salt at pH 5.0 (45:55, v/v). The chromatographic analysis time is less than 10 min, and the validation of the assay shows that it is selective, accurate, and linear for the concentration range of 2.50 to 7.50 microg/mL with a detection limit of 0.00500 microg/mL. The within-day and between-day relative standard deviation values are 1.26% (n = 18) and 1.25% (n = 8), respectively. The method described conforms to the validation of compendial methods used for finished pharmaceutical products in general and offers a reliable, quick, and cost-effective procedure for examining the consistency or quality-control analysis of AB in liposomal products. It can also be applied for the determination of AB in other nonliposomal lipid-based drug delivery systems that are on the market.     

Development of a capillary gas chromatographic procedure

A simple and fast capillary gas chromatographic method with flame ionisation detection (FID) has been developed for the analysis of fluoxetine, fluvoxamine, citalopram, sertraline and paroxetine in their pharmaceutical preparations, using clomipramine as internal standard in order to achieve quantification. The reported method is the first screening one that allows the determination of the five selective serotonin reuptake inhibitors by GC, permitting also to avoid prederivatization for the first time and it is even a pioneering work including an extensive analytical validation and robustness treatment on placebo pharmaceutical formulations too. Optimal conditions for the quantitative gas capillary separation were investigated: column head pressure (100 kPa), injector and detector (FID) temperatures (210 and 260 °C), time and temperature for the splitless step (0.80 min and 80 °C, respectively), volume injected (2 μL) and oven temperature program, providing analysis times shorter than 7 min. Aspects such as stability of solutions, linearity, accuracy, precision, detection and quantitation limits are examined on a selected placebo in order to validate this method. Peak purity is assessed using mass-selective detection (DMS). The robustness of this method was evaluated using the Plackett-Burman fractional factorial experimental design with a matrix of 15 experiments and the statistical treatment proposed by Youden and Steinner. The scope of the validated method is proved in the analysis of almost existing pharmaceutical preparations, with recoveries between 98.5% and 102.4% with regard to their nominal contents. Finally, the proposed method could be also a very successfully option for the analysis of these SSRIs in real urine samples introducing a previous solid phase extraction-preconcentration step.     

Determination of sterols, erythrodiol, uvaol and alkanols in olive oils using combined solid-phase extraction, high-performance liquid chromatographic and high-resolution gas chromatographic techniques.

A method is described for the determination of the sterol, erythrodiol, uvaol and alkanol content in olive oils by means of solid-phase extraction and high-performance liquid chromatography, instead of liquid-liquid and thin-layer chromatographic separations, the following step being high-resolution gas chromatographic separation. This type of procedure allows the simultaneous analysis of a larger number of samples and a substantial reduction in manual operations. Comparisons were made between the two methods on 100 different olive oils and with a statistical analysis of the results (Student's t-test).