Capillary zone electrophoresis in a hydrodynamically closed separation system with enhanced sample loadability

Abstract

Some phenomena linked with capillary zone electrophoresis (CZE) performed in a hydrodynamically closed separation system with enhanced sample load capacity via the use of capillary tubes of larger I.D.s were studied. Calculations of the plate heights for varying amounts of the analytes loaded onto 50 and 300 μm I.D. columns under identical CZE separating conditions revealed that the analytical advantages of using columns of larger I.D. include significantly reduced contributions of electromigration dispersion. At higher concentrations of the carrier electrolytes this gain, however, can be partially lost due to increased thermal dispersive effects. Calculated resolutions for a varying ratio of a pair of the analytes loaded onto 50 and 300 μm I.D. columns favoured the use of the latter I.D. in situations when the ratio of the analytes was higher than ca. 102:1. CZE experiments were carried out in a 300 μm I.D. capillary tube made of fluorinated ethylene–propylene copolymer (FEP) with a porous cellophane membrane serving as a hydrodynamic barrier to prevent a flow of the solution in the separation compartment due to a pressure difference between the electrode vessels. Movement of the membrane was found to be a source of undesired flows in the separation compartment, which adversely affected both the reproducibilities of migration times of the analytes and their separation efficiencies. Mechanical support eliminated these problems. Dispersive phenomena associated with electroosmosis in the closed separation compartment were effectively suppressed by using high molecular weight derivatives of water soluble polymers (methylhydroxyethylcellulose and polyethyleneglycol) in the carrier electrolyte solutions. Examples from the separations of various groups of analytes (synthetic food colourants, some inorganic anions, alkali and alkaline earth metal cations and glycoforms of erythropoietin) are given to illustrate a practical utility of the studied CZE approach.