Mixed-mode capillary electrochromatographic separation of anionic analytes

E. Hilder, M. Macka, P. Haddad
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引用次数: 32

Abstract

In this work, mixed-mode capillary electrochromatography is introduced as a method for selectivity manipulation in the separation of charged analytes and is investigated for a number of analytes. This concept involves utilising a component of the eluent to permit the chromatographic and capillary electrophoresis (CE) separation mechanisms to contribute in varying proportions to the separation. This approach was first investigated using a combination of CE with reversed-phase liquid chromatography (RP-LC) for hydrophobic, charged analytes (aliphatic sulfonates), and using the concentration of organic modifier in the eluent to control the contributions of CE and RP-LC. However, the use of reversed-phase columns was found to be problematic for mobile phases with less then 50% organic modifier due to the hydrophobicity of the stationary phase causing the column bed to overheat and dry, and low electroosmotic flow (EOF) values (µ ⩽ 17.8 × 10–9 m2 V–1 s–1) caused additional restrictions. In a second case, ion-exchange stationary phases were used, with the type and concentration of a competing anion in the eluent being used to control the contributions of ion chromatography (IC) and CE to the separation. Nine common inorganic anions were separated using a silica based anion-exchange column and phosphate (pH 7.20) or sulfate (pH 8.2) as eluent with direct UV detection at 214 nm and 17 inorganic and small organic anions were separated using a nitrate eluent (pH 6.80) with indirect UV detection at 214 nm. The separation selectivity was shown to be a combination of IC and CE.
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阴离子分析物的混合模式毛细管电色谱分离
在这项工作中,混合模式毛细管电色谱作为一种选择性操作的方法被引入到带电分析物的分离中,并对许多分析物进行了研究。这一概念涉及到利用一种洗脱液成分来允许色谱和毛细管电泳(CE)分离机制以不同的比例对分离做出贡献。该方法首先采用CE和反相液相色谱(RP-LC)相结合的方法对疏水带电分析物(脂肪族磺酸盐)进行了研究,并使用洗脱液中有机改性剂的浓度来控制CE和RP-LC的贡献。然而,对于有机改性剂含量低于50%的流动相,由于固定相的疏水性导致柱床过热和干燥,并且低电渗透流量(EOF)值(µ≤17.8 × 10-9 m2 V-1 s-1)造成了额外的限制,因此发现使用反相柱是有问题的。在第二种情况下,离子交换固定相被使用,在淋洗液中竞争阴离子的类型和浓度被用来控制离子色谱(IC)和CE对分离的贡献。采用二氧化硅基阴离子交换柱,以磷酸盐(pH 7.20)或硫酸盐(pH 8.2)为洗脱液,在214 nm处进行直接紫外检测,分离了9个常见的无机阴离子;采用硝酸盐洗脱液(pH 6.80),在214 nm处进行间接紫外检测,分离了17个无机和小有机阴离子。分离选择性为IC和CE的结合。
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