General reversed-phase high-performance liquid chromatographic method for the separation of drugs using triethylamine as a competing base

Triethylamine (TEA) was evaluated as a competing base for the retention control and peak shape improvement in the reversed-phase high-performance liquid chromatographic (RP-HPLC) analysis of selected acidic, basic, and neutral drugs. The effects of this amine on the capacity factor and theoretical plate number values of ephedrine, phenol, and sulfamerazine were examined on three unmodified commercial octadecylsilane chromatographic columns. Based on these results, a general RP-HPLC elution scheme using a mu Bondapak C18 10-micron column, methanol-acetic acid-TEA-water mobile phases, and an ultraviolet detector was developed for more than 150 drugs of pharmaceutical interest. The proposed method was applied to the separation of groups of chemically or pharmacologically related drugs that included sympathomimetic amines, antihistamines, phenothiazines, local anesthetics, Cinchona and tropane alkaloids, xanthines, sulfonamides, and steroids. In addition, paired-ion drugs such as physostigmine salicylate and combinations of ascorbic acid, benzoic acid, salicylic acid, pamoic acid, and 8-chlorotheophylline with various basic moieties were readily and effectively resolved into their ionic components using almost identical RP-HPLC conditions.     

Estimation of chromatographic parameters on two silica-based columns connected in series under nonaqueous reversed phase liquid chromatographic conditions

Empirical equations were produced to relate important chromatographic parameters on two silica-based columns serially linked, in isocratic nonaqueous RP HPLC, to retention times and peak widths of the separated compounds on the individual columns. These equations were derived because the experimental data seemed to deviate from the values expected, applying basic chromatographic theoretical equations. The chromatographic parameters studied were retention time, peak width, resolution, number of theoretical plates, capacity factor, and separation factor. In addition, empirical linear relationships were produced for the estimation of the above mentioned parameters of the serial systems, in direct and reverse order, relating them to those obtained on each column, separately. The experimentally obtained values were in good agreement with those estimated by the derived equations.     

The efficiency of open tubular gas chromatographic columns

Summary A new parameter, the mean specific plate number, is proposed for assessing the efficiency of support coated open tubular (SCOT) and wall coated open tubular (WCOT) columns and for comparing the efficiency of different open tubular columns. It has the advantage over most previously used parameters in that it has only a small dependence on the partition ratio and it allows for the column diameter.A graphical presentation is given of the maximum theoretical mean specific plate number as a function of the partition ratio for SCOT columns having a range of relative porous layer thicknesses and for WCOT columns with a range of phase ratios.This presentation permits ready visual comparison of the potential efficiency of different columns and enables a simple evaluation of the percentage utilization of theoretical efficiency from experimentally determined values of the maximum mean specific plate number. For a given column the percentage utilization of theoretical efficiency at optimum average gas velocity and that at optimum practical gas velocity or at a higher average gas velocity are shown to be equal provided that corrections for column pressure drop are made.     

The comparison of two column classification systems during the chromatographic analysis of steroids

Nowadays, due to the availability of hundreds of brands of reversed-phase liquid chromatographic columns, the selection of suitable columns can be difficult. Therefore, a good characterization and classification system is very important. Among published papers, the classification system based on quantitative structure-retention relationships and a method developed at the Katholieke Universiteit Leuven also exist. In quantitative structure-retention relationships, retention is evaluated in terms of the chemical structure of the analytes and the physicochemical properties of both the stationary and mobile phase. The second system allows to rank columns due to the values of four parameters and the calculation of specific F(KUL)-values for a reference column and to be compared with others. In this paper, the classification systems based both on quantitative structure-retention relationships and the F(KUL)-values using principal components analysis were compared. Moreover, the proposed column ranking systems have been checked in clinical practice case considering liquid chromatography determination of six steroid hormones in urine samples. Despite that the matching of both methods is not exactly the same, both classification systems provide simple, reliable and comparable results.     

Implications of column peak capacity on the separation of complex peptide mixtures in single- and two-dimensional high-performance liquid chromatography

Column peak capacity was utilized as a measure of column efficiency for gradient elution conditions. Peak capacity was evaluated experimentally for reversed-phase (RP) and cation-exchange high-performance liquid chromatography (HPLC) columns, and compared to the values predicted from RP-HPLC gradient theory. The model was found to be useful for the prediction of peak capacity and productivity in single- and two-dimensional (2D) chromatography. Both theoretical prediction and experimental data suggest that the number of peaks separated in HPLC reaches an upper limit, despite using highly efficient columns or very shallow gradients. The practical peak capacity value is about several hundred for state-of-the-art RP-HPLC columns. Doubling the column length (efficiency) improves the peak capacity by only 40%, and proportionally increases both the separation time and the backpressure. Similarly, extremely shallow gradients have a positive effect on the peak capacity, but analysis becomes unacceptably long. The model predicts that a 2D-HPLC peak capacity of 15,000 can be achieved in 8 h using multiple fraction collection in the first dimension followed by fast RP-HPLC gradients employing short, but efficient columns in the second dimension.     

Comparison of the chromatographic behavior of tricyclic neuroleptics on calixarene-bonded, monolithic and conventional RP-HPLC columns

The effect of different chromatographic conditions, such as buffer concentration and type of organic modifier, on the retention behavior of nine tricyclic neuroleptics on three different RP-HPLC columns was investigated. Two recently developed columns, calixarene-bonded (CALTREX) AIII) and monolithic (Chromolith) Performance RP-18e) columns, were compared with a conventional RP-C18 HPLC column (LiChrospher). The results showed how the mobile phase conditions had different effects on the analyte retention on these three columns. For example, the elution order of some analytes and the initiation of separation of the geometric isomers of the three analytes--which have E/Z-isomers (cis/trans-isomers)--could be altered by changing the conditions and the column type. Under identical conditions, a calixarene-bonded phase was the best for this separation, a monolithic phase gave comparable results and the conventional RP-column was the least effective. Concerning the geometric isomers separation, the Chromolith Performance RP-18e was superior.     

Selection of reversed-phase liquid chromatographic columns with diverse selectivity towards the potential separation of impurities in drugs

To select appropriate stationary phases from the continuously expanding supply of potentially suitable HPLC columns, the properties of 28 frequently applied stationary phases were determined by measuring several chromatographic parameters. From these results, based on chromatographic expertise, eight stationary phases with different properties and selectivities were selected. The aim of this study is to apply chemometric tools to evaluate the initially selected set of columns, i.e. a more systematic approach for making such a selection is examined. Starting from the information obtained on the 28 stationary phases, the re-evaluation was performed independently based on the chemometric techniques Pareto-optimality, principal component analysis (PCA), and Derringer's desirability functions. The aim was to select a set of efficient columns exhibiting large selectivity differences. The chemometrically selected stationary phases were divided in groups based on hydrophobicity, a critical retention-determining property in reversed-phase chromatography. This allowed to further reducing the selection to three columns. It is demonstrated that the selection by the chemometric approaches in general is fairly comparable with the initial selection.     

Updating chromatographic predictions by accounting ageing for single and tandem columns

The most efficient optimization methodologies in liquid chromatography are based on the modeling and prediction of the chromatographic behavior for each compound in the sample. However, when the column suffers some ageing after the modeling process, predictions may differ significantly from the actual separation. Repeating the modeling is especially troublesome when several columns are involved, as is the case of coupled columns. We propose a shortcut to correct the time and peak profiles in these situations, after evaluating the effects of ageing. The original models are corrected by introducing parameters accounting for column ageing, obtained using the data of a small subset of compounds from those used to model the brand‐new column. The ageing parameters are fitted from the discrepancies between the data predicted with the original retention models for the brand‐new column and the experimental data measured for the aged column. The approach was developed and tested to predict the chromatographic behavior of 15 sulfonamides, analyzed with individual and tandem columns, using isocratic and gradient elution. Chromatograms more in line with the aged column performance were predicted. The agreement between predictions and experimental data in the aged columns was excellent.     

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.     

反相高效液相色谱法测定酚类化合物的保留指数

以3种ODS柱分别测定了10种酚类化合物的保留值,以烷基甲酮类作为标准参照物计算保留指数及校正保留指数。结果表明,采用校正保留指数系统,可获得比常规保留指数系统更好的精密度和准确性。     

酪蛋白多肽的制备和色谱分离方法

为了得到低成本的多肽,本文利用胰蛋白酶对酪蛋白进行了充分的酶解。采用分析级反相高效液相色谱-电喷雾质谱联用技术(RP-HPLC/ESI-MS)分析了酶解产物各组分的组成,并通过改变流动相的梯度洗脱程序,优化了分析级色谱条件以充分分离相对含量较高的多肽组分;将优化的分析级色谱条件直接放大到制备级RP-HPLC中,在程序控制下通过紫外吸收信号结合ESI-MS信号共同引导实现了多肽的全自动化分离和收集。整个过程方便快捷,经过这样一个单一的分离步骤,得到了多个纯度较高的多肽。除此之外,本文还考察了流动相的酸碱性、柱上样量等因素对该体系制备级分离的影响,并对一次分离中分辨率不好的亲水性多肽混合物进行了二次分离,得到了多个新的多肽。本文建立的多肽制备方法为多肽和多肽材料的广泛应用提供了一种选择。