Chromatography aqueous mobile phases

Conductivity detectors, commonly employed in ion chromatography, can be used to determine ionic materials at levels of parts per million (ppm) or parts per bUHon (ppb) in aqueous mobile phases. The infrared (ir) detector is one that may be used in either nonselective or selective detection. Its most common use has been as a detector in size-exclusion chromatography, although it is not limited to sec. The detector is limited to use in systems in which the mobile phase is transparent to the ir wavelength being monitored. It is possible to obtain complete spectra, much as in some gc-ir experiments, if the flow is not very high or can be stopped momentarily. 

The new way of quantitative determination of the ascorbic acid (AC) by means of ion-pair thin layer chromatography (TLC) in organo-aqueous mobile phases containing cetyltrimethylammonium bromide (CTAB) has been alaborated. 

This section discusses in detail the column types that are available for the size exclusion chromatography of both polar and nonpolar analytes. It first discusses the various columns available for standard nonaqueous size exclusion chromatography. It then reviews the columns available for general size exclusion chromatography using aqueous mobile phases. Finally, it examines the columns designed for size exclusion chromatography of proteins and peptides. 

For the size exclusion chromatography of proteins on silica-hased diol packings, it is generally recommended to use fully aqueous mobile phases with a salt concentration between 0.1 and 0.3 M. In general, a phosphate buffer around pH 7 is used as the mobile phase. Under these circumstances, the tertiary structure of most proteins is preserved without difficulty and the interaction of proteins with each other is minimized. However, other inorganic buffers or combinations of buffers with organic solvents can be used without difficulties for special applications. 

In summary, silica gel can be an excellent stationary phase for use in exclusion chromatography in the separation of high molecular weight, weakly polar or polarizable polymers. It cannot be used for separating mixtures that require an aqueous mobile phase or operate at a pH outside the range of 4-8. Examples of the type of materials that can be separated by exclusion chromatography using silica gel are the polystyrenes, polynuclear aromatics, polysiloxanes and similar polymeric mixtures that are soluble and stable in solvents such as tetrahydrofuran. 

Unfortunately, silica gel suffers from a severe disadvantage in that it is slightly soluble in water. This means that the native silica cannot be used in conjunction with aqueous mobile phases. Consequently, silica is precluded from use in the separation of those substances that are strongly polar and require aqueous solvents to render them soluble and stable. For this reason the relatively new, micro-reticular resins are now used in the separation of strongly polar substances by exclusion chromatography. 

Males et al. [103] used aqueous mobile phase with formic acid for the separation of flavonoids and phenolic acids in the extract of Sambuci flos. In a cited paper, authors listed ten mobile phases with addition of acids used by other investigators for chromatography of polyphenolic material. For micropreparative separation and isolation of antraquinone derivatives (aloine and aloeemodine) from the hardened sap of aloe (Liliaceae family), Wawrzynowicz et al. used 0.5-mm silica precoated plates and isopropanol-methanol-acetic acid as the mobile phase [104]. The addition of small amounts of acid to the mobile phase suppressed the dissociation of acidic groups (phenolic, carboxylic) and thus prevented band diffusions. 

Most small organic molecules are soluble in mixed organic-aqueous solvents and can be easily analyzed using RPLC. However, there are some polar compounds which are not soluble in typical RPLC solvent systems or are unstable in an aqueous mobile phase system. These compounds can be analyzed on an RPLC column with a nonaqueous solvent system. This technique is called "nonaqueous reversed phase chromatography" (NARP).20-21 The NARP technique is primarily used for the separation of lipophilic compounds having low to medium polarity and a molecular weight larger than... 

For the given systems (ionizable selectors and solutes), a modified form of CPC was usually more favorable The so-called pH-zone-refining CPC mode, which is a kind of displacement type of chromatography. In this mode, the column is filled with the acidified stationary phase (e.g., using TFA as retainer), then injection of the sample takes place before the rotor is switched on and elution is started with a basic mobile phase (e.g., using ammonia as displacer in the aqueous mobile phase). Apparent pH and enantiomeric composition were determined for every fraction. It appeared that the enantiomers eluted in refined... 

High-performance LC is the favored technique for the determination of carbamates, since many of them lack the thermal stability necessary for gas chromatographic analysis. Most HPLC methods for methyl and phenyl carbamate pesticides have employed reversed-phase chromatography with C18 or C8 columns and aqueous mobile phases (47,50,105,106). Two different solvent sys-... 

One of the advantages of protein-based CSPs is that chiral chromatography is carried out under the reversed-phase mode that is, aqueous mobile phases are used frequently and, therefore, there is a great chance to optimize the chiral resolution. The most important parameters to be optimized are the composition of... 

Each column type has its own place of use. Column variety is what gives HPLC its versatility. It really depends on your compound and application. Approximately 80% of all separations are done on 5-10-jUm reverse phase Ci8 silica columns. Much of this is tradition. Reverse phase columns offer high-resolution separations for a wide variety of compounds and can be run in aqueous mobile phases. Ion exchange separations require salt solutions for separations, and these are not compatible with mass spectrometers. Size separations have lower resolving power and longer run times, but may be the only way to separate proteins solutions that will irreversibly stick to reverse phase columns. Use small pore size separation columns to remove salt from effluent from other chromatography separations. Zirconium and polymeric column are newer and offer possibilities for unique separations. 

Samples containing 150 g of 500 ppm acids were also prepared using 3% added sodium chloride in the 90/10 oil/water blend, water, and vegetable oil as the microwave medium. These samples were heated 0, 1, 2, and 3 minutes in the microwave. Changes in the acid concentration were determined by high pressure liquid chromatography with an organic acid column and an aqueous mobile phase. 

Detection limits for 13 resolved PTH-amino acids ranged from 1.6 to 4.8.10 M, which was by a factor of ten superior to the detection limits reported for micellar electrokinetic chromatography [77]. Most of this improvement in detection limit is due to the higher thermo-optical enhancement produced by the high acetonitrile content in the buffer compared to the aqueous mobile phase used in the micellar electrokinetic separation. 

As stated above, the utility of silica based stationary phases does not limit its use to organic mobile phases. For many years it has been commonplace in flash chromatography to use aqueous solvents to elute analytes from silica based media. Isocratic elution with mixtures of butanol, acetic acid and water is standard protocol for the separation of amino acids and a carefully prepared combination of methanol, chloroform and water is useful for general organic compounds. Peptides are also readily purified by gradient elution on normal phase silica, moving from acetonitrile to aqueous mobile phase 3,2l This technique is particularly useful for extremely hydrophilic peptides that are not strongly retained on reversed phase media. 

---