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Solvent system development, analysis

The Caucasian samples were from 20th century rugs, and it is quite likely that those samples that were not identified were synthetic. Two known early synthetic dyes which were available for analysis, Ponceau R and Amaranth, responded well in the HPLC systems used. Because the Caucasian sample extracts identified as synthetic and the two synthetic dye standards all eluted quite well, the solvent systems developed here fortuitously may be useful for the analysis of early synthetic dyes as well as natural dyes. Once the appropriate synthetic dye standards are found, identification of the samples that did not correspond with known standards will most likely follow. [Pg.180]

A method has been developed which determines the amount of residual alk-ene and secondary alcohol in AOS using an aqueous-organic extraction solvent system followed by GC analysis. Alkanes present (impurities in the feedstock) will also be determined with the unreacted alkene. [Pg.443]

The literature reports [a]n +23.2° (c = l, aqueous 5N hydrochloric acid). The product was analyzed by the submitters. Analysis caleulated for C5H11NO2S C, 40.25 H, 7.43 N, 9.39 S, 21.49. Found C, 40.14 H, 7.42 N, 9.50 S, 21.52. The product was homogeneous according to thin-layer chromatograms on precoated silica gel G plates purchased from Analtech, Inc., Newark, Delaware, and developed with the following two solvent systems (solvents, volume ratios of solvents in the same order) 1-butanol-acetic acid-ethyl acetate-water, 1 1 1 1, Rf 0.49 1-butanol-acetic acid-pyridine-water, 15 3 10 12, R/0.51. [Pg.217]

Silica gel plates also have been used for the separation of 16 different eye pigments of Drosophila melanogaster using two-dimensional development in nonpolar solvent systems [55]. Although not very common, two-dimensional development may be nsed in preparative scale on thick-layered plates for further analysis. [Pg.313]

LC-MS is now a nature technology and operation of an LC-MS system is no longer the realm of an MS specialist. The proper choice of the LC-MS mode to be used in a specific situation depends on analyte class, sample type and problem (detection, confirmation, identification). On-line LC-MS is used more for specialised applications than for general polymer or rubber compound analysis. This derives from the fact that LC-MS method development (column, solvent system, solvent programme, ionisation mode) is rather time consuming. LC-MS (in particular with API interface) enables analysis of a wide range of polar and nonvolatile compounds which cannot be analysed by GC (icf. Scheme 7.7). [Pg.489]

Sidhu et al [86] developed a reliable and simple high performance liquid chromatographic method for the routine analysis of pharmaceutical dosage forms using a Cig Bondapak reversed-phase column with a binary solvent system consisting of... [Pg.190]

Phosphorus, fatty acids, carbohydrates, glycerol, and amino acids were analyzed by the method described in our previous paper [8] and references cited therein. SDS-PAGE [8], TLC [9], HPLC [9], determination of phos-phomonoester [8], reducing sugar analysis [13], methylation analysis [14], and hexose analysis [15] were performed as described in the respective literature. Two dimensional TLC was performed on silica-gel plate (Merck Silicagel 60 F254 No. 5715) using the solvent systems, chloroform-methanol-acetic acid (65/10/1, v/v/v) for the first development and chloroform-methanol-25% ammonia solution (65/10/1) for the second. [Pg.204]

New advances in the l.c. of carbohydrates are likely to come from three general areas. The first is in the development of more-durable and stable, stationary phases. At present, a major limitation on the use of commercial columns, especially those of the aminopropyl-bonded silica-gel variety, is their short life-time and ease of fouling. More-durable, resin-based columns that operate with the same solvent system and selectivity as aminopropyl silica-gel columns are currently available, and will see further use and development. The development of improved phases for supercritical, fluid-type l.c. will allow this method to be of use for analysis of various carbohydrates. ... [Pg.71]

Research has been done showing that rapid pressnre-driven LC analysis can be done with little solvent consumption, demonstrating this as a viable process analytical tool. Using electrokinetic nanoflow pumps LC can be miniaturized to the point of being a sensor system. Developments in terms of sampling to enable sampling directly from a process stream, to the separation channel on a chip are critical for the application of miniaturized process LC. The components (valves and pumps) required for hydrodynamic flow systems appear to be a current limitation to the fnll miniatnrization of LC separations. Detection systems have also evolved with electrochemical detection and refractive index detection systems providing increased sensitivity in miniaturized systems when compared to standard UV-vis detection or fluorescence, which may require precolumn derivatization. [Pg.535]

The chromatographic or electrophoretic behavior of a specific astatocompound must be considered similar, but not necessarily the same, as that of its analogous iodo and bromo derivative. This procedure has been developed and termed sequential analysis 99,102) in order to avoid a coincidental fitting of chromatographic data, several solvent systems should be used. [Pg.51]

A wide selection of solvent systems is available in the biochemical literature. If a new solvent system must be developed, a preliminary analysis must be done on the sample with a series of solvents. Solvents can be rapidly screened by developing several small chromatograms (2X6 cm) in small sealed bottles containing the solvents. For the actual analysis, the sample should be run on a larger plate with appropriate standards in a development chamber (Figure 3.3). The chamber must be airtight and saturated with solvent vapors. Filter paper on two sides of the chamber, as shown in Figure 3.3, enhances vaporization of the solvent. [Pg.63]

Period 2 Part B—Work up the dansyl hydrolysate and spot on the TLC plate with standard dansyl amino acids. Part A. 1—Work up peptide hydrolysate and prepare FMOC derivatives of amino acids for analysis by HPLC or CE. Part A.2-If applicable, develop paper chromatogram in solvent system. [Pg.235]


See other pages where Solvent system development, analysis is mentioned: [Pg.101]    [Pg.5577]    [Pg.323]    [Pg.5576]    [Pg.69]    [Pg.247]    [Pg.358]    [Pg.81]    [Pg.176]    [Pg.179]    [Pg.238]    [Pg.218]    [Pg.215]    [Pg.300]    [Pg.304]    [Pg.312]    [Pg.94]    [Pg.246]    [Pg.141]    [Pg.733]    [Pg.541]    [Pg.240]    [Pg.155]    [Pg.503]    [Pg.153]    [Pg.234]    [Pg.81]    [Pg.176]    [Pg.179]    [Pg.238]    [Pg.106]    [Pg.634]    [Pg.257]    [Pg.630]    [Pg.2305]    [Pg.10]    [Pg.234]   


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Solvent analysis

Solvent developing

Solvent systems analysis

Solvents development

System Development

Systems developed

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