Nonaqueous capillary electrophoresis (NACE) is the application of a conductive electrolyte dissolved in either one organic solvent or a mixture of several organic solvents to carry out zone electrophoresis or related techniques in fused-silica capillaries. A complete review on the fundamentals, the optimization of analytical methods, practical considerations, and applications is given. To explain the differences to CE in aqueous media, a brief summary on solvent properties and molecular interactions in solutions introduces the reader into these fields. The use of additives to tune separation selectivity by means beyond a pure zone-electrophoretic mechanism is discussed in detail for organic media. Special detection techniques providing high potential for NACE are presented. Data on the precision of NACE methods and a list of relevant applications are included. More specialized applications like the determination of physicochemical constants in NACE or the setup of a semipreparative mode are described.
In aqueous capillary electrophoresis the electroosmotic flow (EOF) can be strongly suppressed or eliminated by coating the capillary surface silanols either by buffer additive adsorption or chemical modification. Hydrophilic coatings, e.g., polyvinyl alcohol (PVA) proved to be most efficient for EOF control in applications like DNA analysis. In nonaqueous capillary electrophoresis (NACE), however, the EOF cannot be totally suppressed with these capillaries and coating efficiency turned out to be solvent-depending. In this paper, fused-silica capillaries with monomeric and polymeric coatings differing in hydrophobicity and chemical properties (vinyl, vinyl acetate, vinyl alcohol and acrylates with different alkyl chain length) were investigated. Besides studying the EOF characteristics with different organic solvents and water, gas chromatography (GC) measurements were carried out to probe the silanol reduction via ether retention and the surface hydrophobicity by retention of nonane. Good correlations between GC results and EOF magnitude could be found. It could be demonstrated that the polymeric coating has to be solvatized by the buffer solvent to reduce the EOF. The PVA coating was optimal for aqueous systems but not effective for some nonaqueous buffers. On the other hand, polyvinyl acetate and polyethyl acrylate as polymeric coatings proved to be optimal to reduce the EOF in NACE.
Mass spectrometric techniques play a prominent role in the rapidly expanding field of high-throughput screening (HTS). In this paper, the authors present a novel qualitative approach for the screening of a small library of compounds using MALDI-TOF-MS and HPLC-ESI-MS/MS. Chymotrypsin (CT), a serine protease, was selected as the target protein. A well-known inhibitor of CT is chymostatin (CS), a naturally occurring peptide aldehyde, which is reported to be a mixture of 3 components-A, B, and C-differing only in one of the amino acids. The authors report that native CS mixture consists of 3 additional ring hydroxylated components and that each compound exists in 2 epimeric forms. In case of protein-binding compounds, only 1 of the epimers was found to be active. A unique feature of this study is the generation of a combinatorial library of CS derivatives applying a one-pot strategy followed by identification and structural elucidation of the library components. Analytical investigation of the library resulted in the identification of 22 compounds. After incubation with CT and centrifugal ultrafiltration, 10 compounds were detected as protein-binding ligands. Finally, the complementary potentials of MALDI-TOF-MS and HPLC-MS/MS in the screening of complex ligand mixtures have been discussed.
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