Capillary, coatings surface

Physical surface modifications Adsorption is probably the simplest way to change the EOF on purpose by using appropriate additives. EOF modification by adsorption can be used on both uncoated and coated capillaries. The surface of uncoated fused silica... 

CZE-ELD, with a An microelectrode at —0.6 V vs. SCSE and a Pt wire as auxiliary electrode, using sodium borate buffer and dodecyltrimethylammonium bromide for dynamic coating of the capillary internal surface, can be applied for separation and determination of hydroperoxides in ultra-trace amounts. Thus, various hydroperoxides derived from linoleic acid undergo total dissociation to carboxylates in borate buffer however, due to their similar molecular masses, in order to resolve the ELD signals, it is necessary to add /3 -cyclodextrin (83) to form complexes with the analytes and reduce their mobility, in accordance with the value of the complexation equilibrium constants . 

Several different analytical and ultra-micropreparative CEC approaches have been described for such peptide separations. For example, open tubular (OT-CEC) methods have been used 290-294 with etched fused silicas to increase the surface area with diols or octadecyl chains then bonded to the surface.1 With such OT-CEC systems, the peptide-ligand interactions of, for example, angiotensin I-III increased with increasing hydrophobicity of the bonded phase on the capillary wall. Porous layer open tubular (PLOT) capillaries coated with anionic polymers 295 or poly(aspartic acid) 296 have also been employed 297 to separate basic peptides on the inner wall of fused silica capillaries of 20 pm i.d. When the same eluent conditions were employed, superior performance was observed for these PLOT capillaries compared to the corresponding capillary zone electrophoresis (HP-CZE) separation. Peptide mixtures can be analyzed 298-300 with OT-CEC systems based on octyl-bonded fused silica capillaries that have been coated with (3-aminopropyl)trimethoxysilane (APS), as well as with pressurized CEC (pCEC) packed with particles of similar surface chemistry, to decrease the electrostatic interactions between the solute and the surface, coupled to a mass spectrometer (MS). In the pressurized flow version of electrochromatography, a pLC pump is also employed (Figure 26) to facilitate liquid flow, reduce bubble formation, and to fine-tune the selectivity of the separation of the peptide mixture. 

Electrophoresis in the CZE mode takes place in an open tube and in a free solution without any separation matrix in the capillary. The separation is based on the mass/charge ratio of the analytes. It is appropriate for the separation of nucleosides and nucleotides. It is not well suited for medium to large oligonucleotides, because their mass/charge ratio tend to be smaller. The use of a separation matrix becomes necessary for these species. Various capillary systems, including bare fused silica capillaries and surface-coated capillaries, have been used in CZE. 

The performance of commerically available coated and uncoated capillaries utilizing electroosmotic mobilization has been assessed for model protein mixtures [71]. Although successful separations of basic and neutral proteins were achieved on uncoated capillaries, coated capillaries were required for the separation of acidic proteins in order to provide a constant EOF throughout the capillary. Yeo and Regnier [72] have reported novel coatings for CIEF, which are produced by dynamically modifying octade-cylsilane-derivatized capillaries by adsorption of methylcellulose or surfac-... 

Coating the interior surface of the capillary with an uncharged hydrophilic material reduces or eliminates electroosmotic flow. To be useful for routine analysis, however, the coating must be stable under normal operating conditions. If the capillary coating deteriorates over time, the efficiency and reproducibility of the separation will be compromised. 

Electroosmotic flow can be reduced and even eliminated through coating of the internal surface of the capillaries. Capillaries coated with, e.g., methylcellulose or non-cross-linked acrylamide have negligible EOF [18]. As a result, the focusing of substances will depend principally on the quality of the ampholytes and... 

The EOF can also be controlled by chemical modification of the capillary surface. Various options initially developed for modification of silica in high performance liquid chromatography (HPLC) and for coating capillaries in gas chromatography (GC) are available for the chemical coating of capillaries. The surface silanols at the capillary wall can be reacted with silanes introducing anchor... 

Fatty acids are usually measured as their methylesters by gas liquid chromatography on packed, capillary or surface-coated open tubular (SCOT), columns with flame ionization detection (Christie, 1982a). HPLC can also be used to separate fatty acid esters with measurement by UV-absorption or fluorescence detection (Christie, 1987). 

The applications of the SFM include force measurement between surfaces in liquid and vapor, adhesion between similar or dissimilar materials, contact deformation, wetting and capillary condensation, viscosity in thin films, forces between surfactant and polymer-coated surfaces, and surface chemistry. Fluid-electrolyte interactions between conductive surfaces can also be measured [Smith, et. al., 1988]. A typical microforce of 10 nN can be detected over separation distances to a resolution of 0.1 nm with optical interoferometry between reflective surfaces. With electrostatic forces, relatively large separation are measured 1-100 nm, whereas, short range forces such as van der Waals forces take place over distances of less than 3.0 nm. Ultrasmooth and electrically conductive surfaces can be formed by the deposition of a metal film (40 nm thickness) such as Pt on a smooth substrate of mica [Smith, et. al., 1988]. The separation distance between the two surfaces is controlled by a... 

Capillary electrophoresis (CE) has emerged as an efficient and rapid separation technique in recent years. Its high efficiency has been employed in many applications such as in the analysis of environmental pollutants.Different approaches have been adopted to enhance selectivity for the analysis of different types of compounds. There are two approaches most commonly used to improve CE separations the addition of modifiers into the electrophoretic medium and the modification of the column. Examples of the first approach include the addition of surfactants into the electrophoretic medium as in micellar electrokinetic chromatography (MEKC), and the use of organic solvents,cyclodextrines, " " or bile salts " as buffer modifiers. Examples of the second method include the use of gel-filled columns (capillary gel electrophoresis) " and the coating of the capillary wall surface. " " ... 

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