Liquid chromatography environmental applications

J. ON-LINE SOLID-PHASE EXTRACTION-HIGH-PRESSURE LIQUID CHROMATOGRAPHY ENVIRONMENTAL APPLICATIONS... 

On-line Solid-Phase Extraction—High-Pressure Liquid Chromatography Environmental Applications Large-Volume Analysis by Solid-Phase Extraction... 

Reversed-Phase Liquid Chromatography—Environmental and General Applications... 

His research interests include air and water pollution, liquid chromatography, and applications of different chromatographic techniques in food, water, and environmental parameters analysis. 

Brown, M.A., Liquid Chromatography/Mass Spectrometry Applications in Agricultural, Pharmaceutical and Environmental Chemistry, Oxford University Press, Oxford, 1998. 

For selective estimation of phenols pollution of environment such chromatographic methods as gas chromatography with flame-ionization detector (ISO method 8165) and high performance liquid chromatography with UV-detector (EPA method 625) is recommended. For determination of phenol, cresols, chlorophenols in environmental samples application of HPLC with amperometric detector is perspective. Phenols and chlorophenols can be easy oxidized and determined with high sensitivity on carbon-glass electrode. 

E. A. Hoogendoom and P. van Zoonen, Coupled-column reversed phase liquid chromatography as a versatile technique for the determination of polar pesticides in Environmental Analysis - Techniques, Applications and quality assurance, Barcelo D (Ed.), Vol. 13, Elsevier, Amsterdam, pp. 181-196 (1993). 

The use of multidimensional chromatography in environmental analysis has been reviewed in the literature (1-6). Of the multidimensional systems described in previous chapters, GC-GC liquid chromatography LC-LC and LC-GC, whose applications to environmental analysis will be detailed in this chapter, are the ones most often used in environmental analysis. 

As liquid chromatography plays a dominant role in chemical separations, advancements in the field of LC-NMR and the availability of commercial LC-NMR instrumentation in several formats has contributed to the widespread acceptance of hyphenated NMR techniques. The different methods for sampling and data acquisition, as well as selected applications will be discussed in this section. LC-NMR has found a wide range of applications including structure elucidation of natural products, studies of drug metabolism, transformation of environmental contaminants, structure determination of pharmaceutical impurities, and analysis of biofiuids such as urine and blood plasma. Readers interested in an in-depth treatment of this topic are referred to the recent book on this subject [25]. 

Mordehai, A., Lim, H. K., and Henion, J. D. (1995). Ion-spray liquid-chromatography mass-spectrometry and capillary electrophoresis mass-spectrometry on a modified benchtop ion-trap mass-spectrometer. In Practical Aspects of Ion-Trap Mass Spectrometry Chemical, Environmental and Biomedical Applications (R. E. March, and J. F. J. Todd, Eds), Vol. 3, pp. 215—237, CRC Press, Boca Raton, FL. 

Marin JM, Gracia-Lor E, Sancho JV et al (2009) Application of ultra-high-pressure liquid chromatography-tandem mass spectrometry to the determination of multi-class pesticides in environmental and wastewater samples Study of matrix effects. J Chromatogr A 1216 1410-1420... 

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]. 

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. 

APPLICATION OF HIGH PERFORMANCE LIQUID CHROMATOGRAPHY IN 1.10 ENVIRONMENTAL ANALYSIS... 

High performance liquid chromatography (HPLC) is a common analytical technique used to determine a wide range of organic compounds. Its application has been widespread in industries such as dyes, paints, and pharmaceuticals. More than two thirds of all organic compounds can be analyzed using HPLC methods. Its application in environmental analyses, however, has been relatively recent. Only a limited number of U.S. EPA methods are based on HPLC techniques. 

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