Liquid-based method

Additionally, unsatisfactory extraction efficiencies were often blamed on poor extraction conditions, while the true cause was inadequate collection. Consequently many laboratories regarded SFE as too complex and abandoned the technique despite its excellent features. However, at present there are many well-conducted scientific applications and comprehensive text books that aids in the development of potent and competitive methods for the replacement of many conventional liquid-based methods such as Soxhlet. The basic concepts of SFE and important factors governing the extraction process will be outlined. Several applications suitable for SFE will also be presented. 

Nearly all liquid simulations have been done using molecular mechanics force fields to describe the interactions between molecules. A few rare simulations have been completed with orbital-based methods. It is expected that it will still be a long time before orbital-based simulations represent a majority of the studies done due to the incredibly large amount of computational resources necessary for these methods. 

Keller, H. R. and Massart, D. L., Artefacts in Evolving Factor Analysis-Based Methods for Purity Control in Liquid Chromatography with Diode-Array Detection, Ana/yt/ca Chimica Acta 263, 1992, 21-28. 

General trends are focused on reduced-solvent extractions or adsorption-based methods — enviromnentaUy friendly solvents for both solid and liquid samples. In recent decades, advanced techniques like supercritical fluid extraction (SFE), ° pressurized liquid extraction (PLE)," microwave-assisted extraction (MAE), ultrasound-assisted extraction, countercurrent continued extraction (www.niroinc.com), solid... 

Tswett s initial column liquid chromatography method was developed, tested, and applied in two parallel modes, liquid-solid adsorption and liquid-liquid partition. Adsorption ehromatography, based on a purely physical principle of adsorption, eonsiderably outperformed its partition counterpart with mechanically coated stationary phases to become the most important liquid chromatographic method. This remains true today in thin-layer chromatography (TLC), for which silica gel is by far the major stationary phase. In column chromatography, however, reversed-phase liquid ehromatography using chemically bonded stationary phases is the most popular method. 

H.R. Keller and D.L. Massart, Artifacts in evolving factor analysis-based methods for peak purity control in liquid-chromatography with diode array detection. Anal. Chim. Acta, 263 (1992) 21-28. 

E Ruckenstein, V Lesins. Classification of liquid chromatographic methods based on the interaction forces The niche of potential barrier chromatography. In A Mizrahi, ed. Advances in Biotechnological Processes, Vol 8 Downstream Processes Equipment and Techniques. New York Alan R. Liss, 1988, pp 241-314. 

Dean et al. [93] used a high performance liquid chromatographic method for the simultaneous determination of primaquine and carboxyprimaquine in plasma with electrochemical detection. After the addition of the internal standard, plasma was deproteinized by the addition of acetonitrile. Nitrogen-dried supernatants, resuspended in mobile phase were analyzed on a C8 reversed-phase column. Limits of detection for primaquine and carboxyprimaquine were 2 and 5 ng/mL with quantitation limits of 5 and 20 ng/mL, respectively. The assay sensitivity and specificity are sufficient to permit quantitation of the drug in plasma for pharmacokinetics following low dose (30 mg, base) oral administration of primaquine, typically used in the treatment of malaria and P. carinii pneumonia. 

Cuyckens F and Claeys M. 2002. Optimization of a liquid chromatography method based on simultaneous electrospray ionization mass spectrometric and ultraviolet photodiode array detection for analysis of flavonoid glycosides. Rapid Commun Mass Spectrom 16(24) 2341—2348. 

A number of specific elements may be determined quantitatively based on liquid-liquid extraction method or solvent-extraction technique, namely ... 

Vial, J., Jardy, A., Anger, P., Brun, A., Menet, J. M. Methodology for the transfer of liquid chromatography methods based on statistical considerations. J. Chromatogr. A, 815, 1998, 173-182. 

Vaarman A, Kask A, Maeorg U. 2002. Novel and sensitive high-performance liquid chromatographic methods based on electrochemical coulometric assay detection for simultaneous determination of catecholamines, kynure-nine and indole derivatives of tryptophan. J Chrom B 769 145-153. 

This chapter focuses on approaches to the validation of high-performance liquid chromatography methods based on regulatory guidance documents and accepted industry practices. The information in this chapter gives a brief review of the reasons for performing method validation and the regulations that describe this activity. Individual validation parameters are discussed in relation to the type of method to be validated. Examples of typical validation conditions are presented with references to additional information on individual topics. This chapter was written to help analysts responsible for method validation. 

Dahlmann, J., Budakowski, W.R. and Luckas, B., Liquid chromatography-electrospray ionisation-mass spectrometry based method for the simultaneous determination of algal and cyanobacterial toxins in phytoplankton from marine waters and lakes followed by tentative structural elucidation of microcystins, /. Chromatogr., 994, 1-2, 45, 2003. 

These macromolecule-based purification methods isolate polymer-bound products from soluble impurities, but do not generally purify the product from other polymer-bound byproducts. Such byproducts arise from incomplete reactions or side reactions and in classical solution chemistry, similar byproducts are removed during product purification at each step of a multi-step synthesis. Support-based methodologies, while removing the multiple, laborious purification steps of a classical synthesis, generally do not provide a method for the purification of intermediates. Instead, these methodologies demand that reaction conditions be optimized such that reactions are driven to completion to avoid a complicated final mixture of products. However, some developed liquid-phase methods achieve high purity of products without quantitative reaction yields [21-26]. 

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