Electrophoresis separation techniques

Capillary affinity electrophoresis (CAE) or affinity capillary electrophoresis (ACE) — An electrophoretic separation technique (- electrophoresis), in which -> analytes are separated in a capillary, with the -> supporting (background) electrolyte containing substances capable of specific, often biospecific, interactions with the analytes. Ref [i] Riekkola ML, Jonsson jA, Smith RM (2004) Pure Appl Chem 76 443... 

Capillary isoelectric focusing (CIEF) — An electrophoretic separation technique (- electrophoresis) for the separation of amphoteric analytes (-> ampholyte) according to their - isoelectric points by the application of an electric field along a pH gradient formed in a capillary. 

Electrokinetic chromatography (EKC), or electrokinetic capillary chromatography (ECC) — An electrophoretic separation technique (- electrophoresis) based on a combination of - electrophoresis and interactions of the analytes with additives (e.g., - surfactants), which form a dispersed phase moving at a different velocity. In order to be separated either the analytes or this secondary phase should be charged. 

In microfluidic-based systems, material is transported within microstructures (of typical dimensions of 10-500 pm) where separations, reactions, and other processes occur. Focus has been on the realization of the traditional separation techniques (electrophoresis, chromatography, isoelectric focusing, etc.) and reactions in the microchip format. The principles of separation, as in the conventional formats, are based on differences in mass and charge (thus mobility) and partitioning between phases. However, advantages associated with the small dimensions provide superior performance. For example, the higher surface to volume ratio arising from the smaller dimensions results in lower heat and mass transfer resistances and thus an improved performance. 

Steiner F, Hassel M (2000) Nonaqueous capillary electrophoresis a versatile completion of electrophoretic separation techniques. Electrophoresis 21 3994-4016. doi 10.1002/1522-2683(200012)... 

Biomolecule Separations. Advances in chemical separation techniques such as capillary zone electrophoresis (cze) and sedimentation field flow fractionation (sfff) allow for the isolation of nanogram quantities of amino acids and proteins, as weU as the characterization of large biomolecules (63—68) (see Biopolymers, analytical techniques). The two aforementioned techniques, as weU as chromatography and centrifugation, ate all based upon the differential migration of materials. Trends in the area of separations are toward the manipulation of smaller sample volumes, more rapid purification and analysis of materials, higher resolution of complex mixtures, milder conditions, and higher recovery (69). 

The heating effect is the limiting factor for all electrophoretic separations. When heat is dissipated rapidly, as in capillary electrophoresis, rapid, high resolution separations are possible. For electrophoretic separations the higher the separating driving force, ie, the electric field strength, the better the resolution. This means that if a way to separate faster can be found, it should also be a more effective separation. This is the opposite of most other separation techniques. 

Electrodriven Separation Techniques encompass a wide range of analytical procedures based on several distinct physical and chemical principles, usually acting together to perform the requh ed separation. Example of electrophoretic-based techniques includes capillary zone electrophoresis (CZE), capillary isotachophoresis (CITP), and capillary gel electrophoresis (CGE) (45-47). Some other electrodriven separation techniques are based not only on electrophoretic principles but rather on chromatographic principles as well. Examples of the latter are micellar... 

With the development of HPLC, a new dimension was added to the tools available for the study of natural products. HPLC is ideally suited to the analysis of non-volatile, sensitive compounds frequently found in biological systems. Unlike other available separation techniques such as TLC and electrophoresis, HPLC methods provide both qualitative and quantitative data and can be easily automated. The basis for the HPLC method for the PSP toxins was established in the late 1970 s when Buckley et al. (2) reported the post-column derivatization of the PSP toxins based on an alkaline oxidation reaction described by Bates and Rapoport (3). Based on this foundation, a series of investigations were conducted to develop a rapid, efficient HPLC method to detect the multiple toxins involved in PSP. Originally, a variety of silica-based, bonded stationary phases were utilized with a low-pressure post-column reaction system (PCRS) (4,5), Later, with improvements in toxin separation mechanisms and the utilization of a high efficiency PCRS, a... 

The spectrum of new analytical techniques includes superior separation techniques and sophisticated detection methods. Most of the novel instruments are hyphenated, where the separation and detection elements are combined, allowing efficient use of materials sometimes available only in minute quantities. The hyphenated techniques also significantly increase the information content of the analysis. Recent developments in separation sciences are directed towards micro-analytical techniques, including capillary gas chromatography, microbore high performance liquid chromatography, and capillary electrophoresis. 

ESI-MS is the most successful method of coupling a condensed phase separation technique to a mass spectrometer. Because the input to ESI is a liquid, electrospray serves as an interface between the mass spectrometer and liquid chromatographic techniques, including SEC and CE (capillary electrophoresis). In LC-MS the flow-rate should lie in the range recommended for the HPLC pump and the mass spectrometer (typically 0.001 -l.OmLmin-1). Recent advances in (nano)electrospray technology include the development of the use of very low solvent flow-rates (30 to 1000nLmin-1) [130,131],... 

The beauty of 2D gel electrophoresis as a separation technique is the orthogonality of the two separation dimensions separation by charge (isoelectric point) in the first dimension, and separation by size in the second dimension. Two-dimensional gel electropheresis is the core separation technique for proteomics, along with HPLC (for preparative isolation). 

There are a few other analytical methods in which electrochemistry plays an essential role, such as (paper) electrophoresis, isotachophoresis, electrography and electrochromatography (according to Fujinaga) as they belong to analytical separation techniques, they are beyond the scope of this book. 

Innovations in separation science continued on this theme and provided one of the most powerful separation techniques used in biochemistry, where proteins are separated with isoelectric focusing (IEF) applied in one direction, and gel electrophoresis (GE) applied at aright angle to the first separation direction (O Farrell, 1975 Celis and Bravo, 1984). In this case, proteins are first separated according to their isoelectric point, measured in p/units, and then according to their molecular weight by gel electrophoresis. The size separation step is usually aided by addition of a surfactant, most typically sodium dodecyl sulfate (SDS), and the gel material is a polyacrylamide formulation. 

There are many combinations of separations techniques and methods of coupling these techniques currently employed in MDLC systems. Giddings (1984) has discussed a number of the possible combinations of techniques that can be coupled to form two-dimensional systems in matrix form. This matrix includes column chromatography, field-flow fractionation (FFF), various types of electrophoresis experiments, and more. However, many of these matrix elements would be difficult if not impossible to reduce to practice. 

Ruchel, R. (1977). Two-dimensional micro-separation technique for proteins and peptides, combining isoelectric focusing and gel gradient electrophoresis. J. Chromatogr. 132, 451 168. 

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