Electromigration technique, capillary

Scriba, G. K. E. (2006). Recent advances in peptide and peptidomimetic stereoisomer separation by capillary electromigration techniques. Electrophoresis 11, 222-230. 

Chankvetadze, B. (1999). Recent trends in enantioseparations using capillary electromigration techniques. Trends Anal. Chem. 18, 485—498. 

B Chankvetadze, G Blaschke. Enantioseparations in capillary electromigration techniques recent developments and future trends. J Chromatogr A 906 309-363, 2001. 

A variety of microscale separation methods, performed in capillary format, employ a pool of techniqnes based on the differential migration velocities of analytes under the action of an electric field, which is referred to as capillary electromigration techniques. These separation techniques may depend on electrophoresis, the transport of charged species through a medium by an applied electric field, or may rely on electrically driven mobile phases to provide a true chromatographic separation system. Therefore, the electric field may either cause the separation mechanism or just promote the flow of a solution throughout the capillary tube, in which the separation takes place, or both. 

On-line conpling of capillary electromigration techniques with nuclear magnetic resonance spectroscopy [5] and matrix-assisted laser desorption/ionization (MALDl) time-of-flight (TOF) mass spectrometry [6] has also been reported. 

INSTRUMENTATION FOR CAPILLARY ELECTROMIGRATION TECHNIQUES 6.3.1 Separation Unit... 

Typically, sample detection in electromigration techniques is performed by on-column detection, employing a small part of the capillary as the detection cell where a property of either the analyte, such as UV absorbance, or the solution, such as refractive index or conductivity, is monitored. This section briefly describes the major detection modalities employed in capillary electromigration techniques, which are accomplished using UV-visible absorbance, fluorescence spectroscopy, and electrochemical systems. The hyphenation of capillary electromigration techniques with spectroscopic techniques employed for identification and structural elucidation of the separated compounds is also described. 

Other detection modes employed in capillary electromigration techniques include chemiluminescence [69-71], Raman spectroscopy [72,73], refractive index [74,75], photothermal absorbance [76,77], and radioisotope detection [78]. Some of these detection modes have found limited use due to their high specificity, which restricts the area of application and the analytes that can be detected, such as radioisotope and Raman-based detection that are specific for radionuclides and polarizable molecules, respectively. On the other hand, the limited use of more universal detection modes, such as refractive index, is either due to the complexity of coupling them to capillary electromigration techniques or to the possibility of detecting the analytes of interest with comparable sensitivity by one of the less problematic detection modes described above. 

The hyphenation of capillary electromigration techniques to spectroscopic techniques which, besides the identification, allow the elucidation of the chemical structure of the separated analytes, such as mass spectrometry (MS) and nuclear magnetic resonance spectroscopy (NMR) has been widely pursued in recent years. Such approaches, combining the separation efficiency of capillary electromigration techniques and the information-rich detection capability of either MS or NMR, are emerging as essential diagnostic tools for the analysis of both low molecular weight and macromolecular compounds. 

Mass spectrometry provides detailed information regarding molecular weights and structures from extremely small quantities of materials. Several types of ionization sources can be employed for the on-line hyphenation of capillary electromigration techniques with MS, which include... 

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