Stationary phase selectivity parameter

As mentioned earlier, CEC couples the separating power of HPLC and the high efficiency of CE. The packed capillary can be considered the heart of the CEC system because it acts as a pump and provides chromatographic selectivity. The design of the stationary phase related parameters such as mobile phase and pH and instrumental parameters such as pressurization, injection modes, temperature, and voltage polarity play an important role in this technique. 

The specific chemical interactions from the stationary phase have been approached in the same manner. Snyder (95) first proposed that the three types of bonded phases should provide maximum differences in selectivity. He assigned the amino-phase to group I, the cyano- phase to group VI, and the diol-phase to group IV. Cooper and Smith (98,99) have extensively studied the three common types of normal-phase, bonded-phase columns and, using extended solubility parameters, have experimentally located the three columns on a stationary-phase selectivity triangle, shown in Fig. 20. Both the amino-phase and the cyano-phase fall near the predictions however, the diol-phase shows significantly less... 

Column efficiency is only one strategy for achieving peak separation, albeit an important one. Column stationary phase selectively is another important parameter, and is best considered to be a primary parameter where there are only a few target solutes of interest, and where their elution properties are similar (i.e., they have similar retention times). Where there are a plethora of compounds, all of which are important, and they all show problem resolutions, it may be difficult to choose an optimum stationary phase that simultaneously achieves resolution of all these. 

When one develops new reversed-phase (RP)-HPLC methods, one usually uses the selectivity of the mobile phase as the primary method development tool. The chromatographic separation can be influenced by the choice of the organic solvent (mainly methanol and acetonitrile), or by variation of pH or buffer type. Schemes for method development using these parameters have been described in the literature [1,2]. Most important are the selectivity changes caused by pH changes, which are well-understood and easily predictable (3). It is well known that the stationary phase influences the selectivity as well, but this effect is often not very well understood. The primary reason for this is the fact that reliable methods for the description of the stationary phase selectivity have only become available fairly recently. In the last few years, several papers have been published that deal with the subject of selectivity in a fimdamental way [4—9] or represent a data collection based on older methods [10-15]. In this chapter, we describe in detail the method used in our laboratory. We then look at our selectivity charts and discuss our results. It needs to be pointed out in advance that selectivity charts only accurately represent the properties of a stationary phase under the conditions of the measurement. If we depart from the mobile phase composition of the test, the relationships between different columns will change, since selectivity arises from a combined effect of the mobile phase and the stationary phase. 

Pharmaceuticals and drugs, 819-876,947-948 detection and quantitation, 833-839 conventional detection modes, 833-836 instrumental detection modes, 836-387 quantitation, 837-839 development mode selection, 830-833 ease of operation, 819-821 method development, 823-833 mobile phase optimization, 829-830 mobile phase transfer, 830 selection of other parameters, 833 stationary phase selection. 823-825 suitable solvent selection, 827-829 viqwr phase selection. 825-827 method validation. 839-864 general considerations, 840-848... 

In the development of a SE-HPLC method the variables that may be manipulated and optimized are the column (matrix type, particle and pore size, and physical dimension), buffer system (type and ionic strength), pH, and solubility additives (e.g., organic solvents, detergents). Once a column and mobile phase system have been selected the system parameters of protein load (amount of material and volume) and flow rate should also be optimized. A beneficial approach to the development of a SE-HPLC method is to optimize the multiple variables by the use of statistical experimental design. Also, information about the physical and chemical properties such as pH or ionic strength, solubility, and especially conditions that promote aggregation can be applied to the development of a SE-HPLC assay. Typical problems encountered during the development of a SE-HPLC assay are protein insolubility and column stationary phase... 

Typical normal-phase operations involved combinations of alcohols and hexane or heptane. In many cases, the addition of small amounts (< 0.1 %) of acid and/or base is necessary to improve peak efficiency and selectivity. Usually, the concentration of polar solvents such as alcohol determines the retention and selectivity (Fig. 2-18). Since flow rate has no impact on selectivity (see Fig. 2-11), the most productive flow rate was determined to be 2 mL miiT. Ethanol normally gives the best efficiency and resolution with reasonable back-pressures. It has been reported that halogenated solvents have also been used successfully on these stationary phases as well as acetonitrile, dioxane and methyl tert-butyl ether, or combinations of the these. The optimization parameters under three different mobile phase modes on glycopeptide CSPs are summarized in Table 2-7. 

Another fairly important stationary phase in straight phase PLC is aluminum oxide. Comparable with silica gel also in the case of aluminum oxides, hydroxyl groups at the surface of this adsorbent are responsible for the selective retention of sample molecules. The relevant physical parameters for the characterization of aluminum oxides suitable for straight phase PLC are the following ... 

The concept of selectivity parameters has a physicochemical relevance, and it is proved experimentally that among solvents with similar functionality there is a great similarity with the selectivity parameters [42]. This fact is very important at the molecular level of the phenomena, and it is the best proof of the predominant role of functionality in intermolecular interactions of the solvent and solute, and the solvent and stationary phase. 

Trying to determine which column is ideal for a specific analysis can be difficult with over 1000 different columns on the market [74]. A proper choice implies a definition of parameters such as column material, stationary phase (polarity), i.d., film thickness and column length. Guides to column selection are available [74,75]. The most important consideration is the stationary phase. When selecting an i.d., sample concentration and instrumentation must be considered. If the concentration of the sample exceeds the column s capacity, then loss of resolution, poor reproducibility and peak distortion will result. Film thickness has a direct effect on retention and the elution temperature for each sample compound. Longer columns provide more resolving probe, increase analysis times and cost. 

Packed column SFC and CE are both able to make inroads into the application area served by HPLC, but from opposite extremes of polarity and with little overlap. CE is likely to be more efficient and faster, but mostly applicable to very polar molecules and ions. SFC qualifies as a more reproducible, trace technique, with greater selectivity and multiple detection options. HPLC and CE have been compared [365], Owing to their orthogonality, CZE and SFC are worth developing, not in competition or as an alternative to HPLC, but as an additional method in order to augment the information obtained from the analysis. With the broad scope of possible eluents and stationary phases, HPLC has fewer constraints than SFC and CZE. The parameters influencing selectivity may be used as a guide to optimisation (Table 4.44). 

Specific separation effects can be understood from the multicomponent solubility parameter theory. Specific effects for nonpolar compounds are predictable with perfluorinated and graphitized carbon black stationary phases. Specific selectivity for polar compounds in reversed-phase HPLC can be realized with polar additives to the mobile phase. 

As mentioned in Section 11.8.4, the parameters that are most important for a qualitative analysis using most GC detectors are retention time, tR adjusted retention time, t R and selectivity, a. Their definitions were graphically presented in Figures 11.16 and 11.17. Under a given set of conditions (the nature of the stationary phase, the column temperature, the carrier flow rate, the column length and diameter, and the instrument dead volume), the retention time is a particular value for each component. It changes... 

In preparative chromatography, selectivity and efficiency no longer have the same importance they do in analytical chromatography. A certain selectivity is required in preparative chromatography as everywhere else in order to achieve the separation, but other parameters are at least as important if not more so. These include the loading capacity of the stationary phase and the maximum speed (throughput) of the process. The three main economic criteria for a large scale separation process are... 

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