High performance liquid chromatography, applications instrumentation

High performance liquid chromatography, applications of 102-171 instrumentation 5-14 determination of, anions 146-159 cations, 146-159 organic ompounds 102-137 organometallic compounds 137-146... 

High performance liquid chromatography is a technique that has arisen from the application to liquid chromatography (lc) of theories and instrumentation that were originally developed for gas chromatography (gc). 

Bushey, M.M., Jorgenson, J.W. (1990). Automated instrumentation for comprehensive two-dimensional high-performance liquid chromatography of proteins. Anal. Chem. 62,161-167. Cabrera, K. (2004). Applications of silica-based monolithic HPLC columns. J. Sep. Sci. 27, 843-852. 

High performance liquid chromatography (HPLC) and capillary electrophoresis (CE) are two instrumental separation techniques that are applicable to the separation of proteins and peptides. The advantage of HPLC and CE techniques is that they afford the analyst the freedom to resolve a complex mixture by different routes employing different... 

In this section we will review the application of near-IR system instrumentation to the most commonly encountered fluorescence measurements such as steady-state spectra, excited state lifetimes, anisotropy, microscopy, multiplexing, high-performance liquid chromatography (HPLC), and sensors. 

For the pharmaceutical scientist, understanding the theory and application of the equipment is usually not sufficient there is the matter of compliance. The qualification of CE is similar to that of other instruments. Installation qualification (IQ), operational qualification (OQ), and performance qualification (PQ) apply in much the same way as high-performance liquid chromatography (HPEC). This chapter details the different parts of the modern CE instrument, equipment-related issues and troubleshooting, instrument qualification, and the future of the CE instrument. 

High-performance liquid chromatography (HPLC) is one of the premier analytical techniques widely used in analytical laboratories. Numerous analytical HPLC analyses have been developed for pharmaceutical, chemical, food, cosmetic, and environmental applications. The popularity of HPLC analysis can be attributed to its powerful combination of separation and quantitation capabilities. HPLC instrumentation has reached a state of maturity. The majority of vendors can provide very sophisticated and highly automated systems to meet users needs. To provide a high level of assurance that the data generated from the HPLC analysis are reliable, the performance of the HPLC system should be monitored at regular intervals. In this chapter some of the key performance attributes for a typical HPLC system (consisting of a quaternary pump, an autoinjector, a UV-Vis detector, and a temperature-controlled column compartment) are discussed [1-8]. 

The method of complete electrolysis is also important in elucidating the mechanism of an electrode reaction. Usually, the substance under study is completely electrolyzed at a controlled potential and the products are identified and determined by appropriate methods, such as gas chromatography (GC), high-performance liquid chromatography (HPLC), and capillary electrophoresis. In the GC method, the products are often identified and determined by the standard addition method. If the standard addition method is not applicable, however, other identification/determination techniques such as GC-MS should be used. The HPLC method is convenient when the product is thermally unstable or difficult to vaporize. HPLC instruments equipped with a high-sensitivity UV detector are the most popular, but a more sophisticated system like LC-MS may also be employed. In some cases, the products are separated from the solvent-supporting electrolyte system by such processes as vaporization, extraction and precipitation. If the products need to be collected separately, a preparative chromatographic method is use-... 

An overview and discussion is given of literature methods published after 1989 devoted to the ion-interaction chromatographic determination of inorganic anions. Seventy references are quoted. Ion-interaction chromatography makes use of commercial reversed-phase stationary phase and conventional high-performance liquid chromatography instrumentation. The basis of the technique, the modification of the stationary phase surface, the choice of the ion-interaction reagent as well as the dependence of retention on the different variables involved are discussed. Examples of application in the fields of environmental, clinical and food chemistry are presented. The experimental conditions of stationary phase, of mobile phase composition as well as detection mode, detection limit and application are also summarized in tables. 1997 Elsevier Science B.V. 

Park J-W, Cundy KC, Ames BN (1989) Detection of DNA adducts by high-performance liquid chromatography with electrochemical detection. Carcinogenesis 10 827-832 Patterson LK (1987) Instrumentation for measurement of transient behavior in radiation chemistry. In Farhataziz, Rodgers MAJ (eds) Radiation chemistry. Principles and applications. Verlag Che-mie, Weinheim, pp 65-96... 

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