Chromatography separation modes

Adsorption Chromatography—Separation mode resulting from compounds that have different adhesion rates for the packing surface. (See Normal-Phase Chromatography.)... 

GPC (Gel Permeation Chromatography)—Separation mode based on the molecular sizes of the compounds. [See SEC (size exclusion chromatography).]... 

Ion Exchange Chromatography—Separation mode for ionized compounds on charged columns. Anion-exchange columns attract and separate anions cation-exchange columns separate cations. 

Normal Phase Chromatography—Separations mode run on nonbonded, anhydrous porous silica using a nonpolar mobile phase. See Adsorption Chromatography.)... 

Reverse-Phase Chromatography—Separation mode on bonded phase columns in which the solvent/column polarities are the opposite of normal-phase separations. Polar compounds elute before nonpolar compounds, Nonpolar columns require polar solvents. 

Type of Chromatography Separation Mode/Interaction Type... 

A more complicated, but flexible, system has been reported by Blomberg et al. (46). Here, size exclusion chromatography (SEC), normal phase EC (NPLC) and GC were coupled for the characterization of restricted (according to size) and selected (according to polarity) fractions of long residues. The seemingly incompatible separation modes, i.e. SEC and NPLC, are coupled by using an on-line solvent-evaporation step. 

The present chapter is largely concerned with HPLC, together with a summary of developments in quantitative thin-layer chromatography, but a brief account of the various types of liquid chromatography is given first together with a guide to the choice of appropriate separation mode. 

If simple sample pretreatment procedures are insufficient to simplify the complex matrix often observed in process mixtures, multidimensional chromatography may be required. Manual fraction collection from one separation mode and re-injection into a second mode are impractical, so automatic collection and reinjection techniques are preferred. For example, a programmed temperature vaporizer has been used to transfer fractions of sterols such as cholesterol and stigmasterol from a reversed phase HPLC system to a gas chromatographic system.11 Interfacing gel permeation HPLC and supercritical fluid chromatography is useful for nonvolatile or thermally unstable analytes and was demonstrated to be extremely useful for separation of compounds such as pentaerythritol tetrastearate and a C36 hydrocarbon standard.12... 

Liquid chromatography has a number of different configurations with regard to technical (instrumental) as well as separation modes. The HPLC system can be operated in either isocratic mode, i.e. the same mobile phase composition throughout the chromatographic ran, or by gradient elution (GE), i.e. the mobile phase composition varies with run time. The choice of operation... 

There are two general types of multidimensional chromatography separation schemes those in which the effluent from one column flows directly on to a second column at some time during the experiment, and those in which some type of trap exists between the two columns to decouple them (off-line mode). The purpose of a trap is often to allow collection of a fixed eluate volume to reconcentrate the analyte zone prior to the second separation step, or to allow a changeover from one solvent system to another. The use of offline multidimensional techniques (conventional sample cleanup) with incompatible mobile phases, is common in the literature, and replacing these procedures with automated on-line multidimensional separations will require continuous development efforts. 

Detection in 2DLC is the same as encountered in one-dimensional HPLC. A variety of detectors are presented in Table 5.2. The choice of detector is dependent on the molecule being detected, the problem being solved, and the separation mode used for the second dimension. If MS detection is utilized, then volatile buffers are typically used in the second-dimension separation. Ultraviolet detection is used for peptides, proteins, and any molecules that contain an appropriate chromophore. Evaporative light scattering detection has become popular for the analysis of polymers and surfactants that do not contain UV chromophores. Refractive index (RI) detection is generally used with size exclusion chromatography for the analysis of polymers. 

The IEX chromatography possesses several attractive features as a first-dimension separation mode in an MDLC scheme. These features include the following ... 

In chromatography, the separation efficiency of any single separation method is limited by the efficiency and selectivity of the separation mode, that is, the plate count of the column and the phase of the selected system. Adding more columns will not overcome the need to identify more components in a complex sample, due to the limitation of peak capacities. The peak capacity in an isocratic separation can be described, following Grushka (1970), as given in Equation (17.1) ... 

Fig. 9. Conjoint Liquid Chromatography (CLC). Separation of proteins from mouse ascites and isolation of monoclonal antibody IgG in one step obtained by a combination of CIM QA and CIM Protein A Disks. Conditions Separation mode CLC (first disk CIM QA, 12 x 3 mm ID, 0.34 ml second disk - CIM Protein A, 12 x 3 mm ID, 0.34 ml, inserted in monolithic column housing) Instrumentation Gradient HPLC system with extra low dead volume mixing chamber Sample Mouse ascites Injection volume 20 pL Mobile Phase Buffer A 20 mM Tris-HCl, pH 7.4 Buffer B Buffer A + 1 M NaCl Buffer C 0.1 M Acetic acid Conditions Gradient 0 - 50 % B in 50 s, 100% A for 40 s, 100% C for 30 s Flow Rate 4 ml/min Detection UV at 280 nm... 

Although the overwhelming majority of theoretical papers in liquid chromatography are dealing with the various aspects of RP-HPLC separation, theoretical advances have also been achieved in some other separation modes. Thus, a theoretical study on the relation between the kinetic and equilibrium quantities in size-exclusion chromatography has been published, hi adsorption chromatography the probability of adsorbing an analyte molecule in the mobile phase exactly r-times is described by... 

One of the major advantages of CE as a separation technique is the wide variety of separation modes available. Analytes can be separated on the basis of charge, molecular size or shape, pi, or hydrophobicity. The same CE instrument can be used for zone electrophoresis, IEF, sieving separations, isotachophoresis, and chromatographic techniques such as MEKC and capillary electrokinetic chromatography. This section provides a brief description of each separation mode. Zone electrophoresis, IEF, and sieving are the primary modes used for protein separations, and these will be discussed in detail in the following sections. 

Subsequently four different CE modes are described in the sections Capillary Zone Electrophoresis, Capillary Gel Electrophoresis, Capillary Isoelectric Focussing, and Micellar Electrokinetic Chromatography (MEKC), respectively. The fundamental principles of the specific separation modes are briefly explained, using appropriate equations where required. In Table 3 all equations are listed. In addition, the influence of both instrumental parameters and electrolytic solution parameters on the optimization of separations is described. 

Capillary zone electrophoresis (CZE) is the most common electrophoretic separation technique due to its simplicity of operation and its flexibility. It is the standard mode for drug analysis, identification of impurities, and pharmacokinetic studies. Other separation modes, such as capillary isotachopho-resis (CITP), micellar electrokinetc chromatography (MEKC), capillary electrochromatography (CEC), capillary gel electrophoresis (CGE), capillary isoelectric focusing, and affinity capillary electrophoresis (ACE), have then-advantages in solving specific separation problems, since the separation mechanism of each mode is different. 

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