吖啶作为检测试剂脂肪醇和脂肪酸的间接光度高效液相色谱研究

以吖啶作为新型检测试剂,研究C_4～C_(12)脂肪醇、C_6～C_(16)脂肪酸的间接光度高效液相色谱,探讨影响色谱保留和产生间接光度响应的因素,从分离检测机理解释两类化合物色谱行为和检测响应的差别,提出新的分离测定脂肪醇和脂肪酸的间接光度高效液相色谱系统。     

吖啶作为检测试剂的磷霉素间接光度反相高效液相色谱研究

以吖啶为紫外检测试剂,研究了强极性弱紫外吸收磷霉素的间接光度色谱,探讨了检测试剂性质、浓度、pH值等因素对色谱保留和检测灵敏度的影响,提出一种测定磷霉素的新色谱方法。     

Separation and indirect detection of small-chain peptides using chromophoric mobile phase additives

Ruthenium(II) 1,10-phenanthroline, Ru(phen)3(2+), and ruthenium(II) 2,2'-bipyridyl, Ru(bipy)3(2+), salts were evaluated as mobile phase additives for the liquid chromatographic separation of small-chain peptides on a polystyrene-divinylbenzene copolymeric (Hamilton PRP-1) stationary phase. In a basic mobile phase peptides are anions, and retention, resolution and detection occur because of the interactions between the stationary phase, the RuII complex and the peptide anion. Since the RuII complex concentration changes in the analyte band relative to the background eluent RuII complex concentration, the peptide can be detected by indirect photometric detection using the wavelength where the RuII complex absorbs. Peptide analyte peaks may be positive or negative depending on the counter-anion and its concentration. Small-chain peptides that do not contain chromophoric side-chains are detected without derivatization at about 0.1 nmol injected at a 3:1 signal-to-noise ratio. Factors that affect retention, resolution and indirect photometric detection are the RuII complex, its mobile phase concentration, mobile phase pH and solvent composition, and the type and concentration of the mobile phase counter-anion and/or buffer anion.     

Ruthenium (II) 1,10-Phenanthroline Salts as Mobile Phase Additives for the Separation and Indirect Detection of Free Amino Acids

Abstract

Ruthenium (II) 1,10-phenanthroline, Ru(phen)²⁺ ₃, salts are used as ion interaction reagents in a basic mobile phase for the retention, resolution, and indirect photometric detection (IPD) of free amino acids on a polystyrene divinylbenzene (Hamilton PRP-1) column. Mobile phase Ru(phen)²⁺ ₃ concentration and pH and type and concentration of organic modifier and counteranion affect retention and IPD. Underivatized amino acid elution order is influenced by side chain structure typical of ion exchange processes. Detection limits for the separation and detection of free amino acids using an isocratic elution condition are about 0.1 nmole for lower retained amino acids and 0.25 nmole for higher retained amino acids for a 3:1 signal:noise ratio. Gradient elution is possible but at higher detection limits.     

Indirect detection in liquid chromatography I. Response models for reversed-phase ion-pairing systems

Summary Ionic compounds without inherent detectable properties show good response in reversed phase ion-pairing systems containing a detectable ionic compound (probe) in the mobile phase. The basis for the indirect detection is the common interaction effect for solutes and probe caused by the limited binding capacity of the adsorbent. Quantitative models for solutes and probe with the same or opposite charges show a simple dependence of the response on the retention of the solute and the coverage of the binding surface by the probe. Applications of the models have shown good agreement between calculated and found response. The binding to sites of different kinds on the adsorbent and possibly ion-pair formation in the mobile phase have an influence on the indirect response. Uncharged solutes give low response in such systems owing to low binding to the competitive sites.     

Indirect UV detection of non-ionic substances in liquid chromatography by addition of a UV-absorbing uncharged compound to the mobile phase

Summary Chromatographic systems have been developed, which allow the detection and quantitation of non-ionic substances with low or no UV-absorptive properties. The detector response is obtained by using mobile phases containing an uncharged component with high UV-absorbance. Polar or non-polar bonded stationary phases have been selected, depending on the hydrophobic character of the analytes. The response pattern is compared to that observed in ion-pair reversed-phase systems with a UV-absorbing ion in the eluent. The influence on retention and detection sensitivity of the nature and concentration of the UV-absorbing compound and of the organic modifier added to the mobile phase has been studied. Principles for the optimisation of the response by changing the mobile phase composition are given. The wide application scope of the indirect UV-detection technique in non-ionic systems is demonstrated by examples of separations of various kinds of compounds, such as organic solvents, carbohydrates and polyols. Presented at the 15th International Symposium on Chromatography, Nürnberg, October 1984     

烷基吡啶盐和芳基季铵盐作检测和改性剂的羟基酸间接光度高效液相色谱研究

研究了苄基三甲基溴化铵动态改性、十四烷基吡啶盐等“永久性”涂渍的两种反相色谱,系统分离和间接光度检测了强极性、弱紫外吸收羟基酸。测定这些检测和改性试剂在YWG-CH反相填料和甲醇-磷酸缓冲液色谱体系的吸附等温线,探讨试剂在固定相的吸附量和其它因素对羟基酸保留、检测灵敏度的影响及分离检测机理。     

Comparison of the repeatability of quantitative data measured in high-performance liquid chromatography with UV and atmospheric pressure chemical ionization mass spectrometric detection

A detailed comparison of the repeatability of the retention times, the peak efficiencies and the peak areas of a dozen probe compounds achieved in HPLC, using either HPLC-UV or HPLC-MS for detection purpose, is reported. Three groups of conventional analytes, each one separated under a different set of experimental conditions, were selected for this study. Most of the compounds are basic, the other ones being neutral. The repeatabilities of the retention times do not exhibit any influence of the mode of detection. However, the repeatabilities of the peak areas and the column efficiencies are generally (although not always) better in HPLC-UV than that in HPLC-MS. On average, the precision for the UV peak area detection was 2.5% versus 6.8% for MS detection. Experimental results show that the response factor of the UV detector is more constant than that of the MS detector, probably because the HPLC flow-rate was sufficiently stable. The results obtained in the different tests are discussed.     

Strategies for the Analysis of Pharmaceutical Cocrystals Using HPLC with Charged Aerosol Detection

Several active pharmaceutical ingredients are currently being developed as pharmaceutical cocrystals as these systems often have superior properties compared to traditional pharmaceutical forms. Pharmaceutical cocrystal formers typically used are polar, small molecule acids or bases which often lack a UV chromophore. Their polar nature results in almost no reversed phase retention and their detection typically cannot be done with UV. Here we discuss approaches for the analysis of pharmaceutical cocrystals using HPLC columns designed for polar retention, ion pairing chromatography (IPC), and hydrophilic interaction chromatography (HILIC) using model cocrystal formers. Corona charged aerosol detection (CAD) was used to monitor the cocrystal formers. l-alanine was used as a model basic cocrystal former, and succinic acid and glutaric acid were used as model acidic cocrystal formers. The acidic cocrystal formers were adequately retained on a C18 column. Heptafluorobutyric acid was used as the ion-pairing reagent for l-alanine as it was unretained without the ion-pairing reagent. HILIC, a newer approach for polar compound retention, was also investigated. Using the HILIC mode, all three model cocrystal formers were retained adequately. Of all the approaches studied for the analysis of the cocrystal formers, HILIC appears to be the best choice as the same column can be used for both acidic and basic cocrystal formers. With IPC, the ion-pairing reagent permanently alters the column chemistry and dedicated columns are required for each ion-pairing reagent used. CAD detection provided a linear response in the 80–100% test concentration range for the analytes studied here.     

Ultra-fast HPLC separation of common anions using a monolithic stationary phase

In this work, a monolithic column was used to perform ultrafast separations of common inorganic anions in as little as 15 seconds. Separations were performed using ion-interaction chromatography with tetrabutylammonium-phthalate as the ion-interaction reagent and were monitored using either direct conductivity or indirect absorbance detection. Detection limits for direct conductivity were in the low ppm range, whereas those for indirect absorbance detection were up to an order of magnitude higher. The reproducibility was 0.4% and 2% RSD for retention time and peak area, respectively, for a one minute separation, and 2.8% and 3-15%, respectively, for the 15 second separation. The proposed method was validated versus standard ion chromatography with suppressed conductivity detection for the analysis of an industrial water sample.