Amino bonded phase, HPLC

Normal-phase HPLC, using an amino-bonded phase, was used for determination of the PAHs of up to 7 rings. This type of separation results in elution by the number of n bonds. A special reversed-phase octadecyl column was used for PAHs of 7 through 12 rings. This HPLC packing, Vydac 201TP5, is well known for its orderly structure and separates the PAHs by their overall shapes. It has been compared to the liquid-crystal phases used in gas chromatography. It provides the best isomer specific separation of PAHs. 

With normal-phase HPLC, oil samples were analyzed as is by simple dilution in n-hexane. A Du Pont Zorbax amino-bonded phase column, 25 cm x 0.46 cm ID, was used, with n-hexane and dichloromethane as solvents. For reversed-phase HPLC, Vydac 201TP5 columns were used (25 cm x 0.46 cm ID for analytical scale and 25 cm x 1 cm ID for preparative scale). Samples for reversed-phase HPLC were fractionated in order to remove the saturated hydrocarbons which can interfere with the separation mechanism. The samples dissolved in n-hexane were passed Baker silica solid-phase extraction cartridges. The PAH fraction was then collected by eluting with a 1 1 mixture of dichloromethane and methanol. Acetonitrile and dichloromethane were used in the HPLC gradient. 

In NPLC, which refers to the use of adsorption, i.e. liquid-solid chromatography (LSC), the surface of microparticulate silica (or other adsorbent) constitutes the most commonly used polar stationary phase normal bonded-phase chromatography (N-BPC) is typified by nitrile- or amino-bonded stationary phases. Silica columns with a broad range of properties are commercially available (with standard particle sizes of 3, 5 and 10 im, and pore sizes of about 6-15nm). A typical HPLC column is packed with a stationary phase of a pore size of 10 nm and contains a surface area of between 100 and 150m2 mL-1 of mobile phase volume. 

Chiral stationary phases for the separation of enantiomers (optically active isomers) are becoming increasingly important. Among the first types to be synthesized were chiral amino acids ionically or covalently bound to amino-propyl silica and named Pirkle phases after their originator. The ionic form is susceptable to hydrolysis and can be used only in normal phase HPLC whereas the more stable covalent type can be used in reverse phase separations but is less stereoselective. Polymeric phases based on chiral peptides such as bovine serum albumin or a -acid glycoproteins bonded to... 

Reverse-phase HPLC can be used for the separation of peptides and proteins. Smaller peptides (less than 50 amino acid residues) may be satisfactorily separated on octadecylsilane (C-18) bonded phases whereas for adequate recovery of larger molecules, tetrylsilane (C-4) or octylsilane (C-8) is recommended. Porous column packing with gel permeation and reverse phase properties is usually required for proteins with relative molecular masses greater than 50 000. 

Riggin and Howard (1979, 1982), Matsui et al. (1983), Fabre et al. (1984), and Ahuja et al. (1988) reported that High Performance Liquid Chromatography (HPLC) with UV or electrochemical detection is capable of analyzing 1,2-diphenylhydrazine. Reversed phase chromatographic columns have been used most often (Ahuja et al. 1988 Fabre et al. 1984 Riggin and Howard 1979, 1982). Cyano-amino polar bonded phase columns also have been used (Matsui et al. 1983). Using a reversed phase and UV detection, the minimum amount detected (on column amounts) is approximately 6-7 ng and the minimum amount quantifiable is less than 1 pg (Ahuja et al. 1988 ... 

The nomenclature of the RP is not consequent. The RP most often used contains octyl (RP C8) or octadecyl (RP C18) groups. There is no differentiation even when two methyl groups are introduced additionally with the silane (as with monofunctional silanes) or only one (difunctional) or none (trifunctional silane). Some manufacturer use silanes with bulky side groups (e.g., isopropyl groups) to improve the hydrolytic stability of the bonded phases, but here also, only the longest alkyl group is used in nomenclature. RP C8 and RP C18 are the work horses in HPLC. Shorter chains (RP4) are used in protein separations, and special selectivity can be obtained with bonded phenyl, cyano, amino or fluoro groups. 

There are two major approaches to achieve enantiomeric separation of d- and L-amino acids. The first involves precolumn derivatization with a chiral reagent, followed by RP-HPLC [226], while the second involves direct separation of underivatized enantiomers on a chiral bonded phase [227], Weiss et al. [209] determined d- and L-form of amino acids by applying derivatization with OPA and chiral /V-isobutyryl-L-cysteine. 

The use of nonpolar chemically bonded stationary phases with a polar mobile phase is referred to as reverse-phase HPLC. This technique separates sample components according to hydrophobicity. It is widely used for the separation of all types of biomolecules, including peptides, nucleotides, carbohydrates, and derivatives of amino acids. Typical solvent systems are water-methanol, water-acetonitrile, and water-tetrahydrofiiran mixtures. Figure 3.15 shows the results of protein separation on a silica-based reverse-phase column. 

In general, there is a wide variety of chromatographic modes (types) that can be employed for the HPLC determination of food components, but only a few have been used for the determination of NOC. These include partition/adsorption on silica gel, liquid-liquid partition on polar-bonded phase (e.g., cyano, amino) or nonpolar hydrophobic-bonded phase (e.g., reversed-phase), and anion-exchange chromatography. Macrae (61) discussed the theories behind the various modes of chromatography. 

As a further test of the etched open tubular approach for the analysis of optical isomers, another column was fabricated based on the selector naphthylethylamine that had been attached to porous silica by the silanization/hydrosilation method for use in HPLC [70]. As in the HPLC experiments, this column was best suited for the resolution of the optical isomers of dinitrobenzoyl methyl esters of amino acids. The best separation (a = 1.14) was obtained for the alanine derivative. In addition, the peak symmetry and efficiency for the naphthylethylamine column was significantly better than that obtained on the cyclodextrin column. However, as shown in HPLC experiments, changes in the amino acid moiety (replacing alanine with valine, etc.) often results in a loss of chiral resolution. In the case of optical isomers, the separation mechanism in HPLC and CEC modes is identical since only interaction between the solute and the bonded phase can result in resolution of the enantiomers. 

A Perkin-Elmer MPF-2A Fluorescence Spectrophotometer was used to determine the excitation and emission wavelengths required for achieving maximum fluorescence intensity for the pesticides studied. The MPF-2A contained a 150 watt xenon arc and an excitation monochromator with a grating blazed at 300 nm as the excitation unit a Hamamatsu R 777 photomultiplier tube (sensitivity range 185 - 850 nm) and an emission monochromator grating blazed at 300 nm as the emission detection unit. A DuPont Model 848 Liquid Chromatograph was used for HPLC (Figure 2). The accessory injection device included a Rheodyne Model 70-10 six-port sample injection valve fitted with a 20 y liter sample loop. A Whatman HPLC column 4.6 mm x 25 cm that contained Partisil PXS 1025 PAC (a bonded cyano-amino polar phase unspecified by the manufacturer) was used with various mobile phases at ambient temperature and a flowrate of 1.25 ml/minute. 

Similarly, reversed-phase HPLC can be used as an Eilternative to the racemization test for amino acids as developed by Manning and Moore (115). Rivier and Burgus (109) have suggested the use of L-phenylalanine, coupled via the N-carboxyanhydride method to a hydrolysate, to monitor racemization during synthesis, although other hydrophobic L-amino acids should also prove equally effective. The use of /eri-butyloxycarbonyl-L-amino acid-Af-hydroxysuccinimide esters in the separation of enantiomeric amino acids and diastereoisomeric peptides has been described (110). Ultimately, these methods may not prove as versatile as the use of chiral stationary phases made by stereoselective control of the bonding process or, alternatively, with surface-active reagents similar to the D-... 

In normal phase HPLC, the cyano and amino columns, in conjunction with the diol bonded phase columns, are now often used in preference to unmodified silica or alumina. Whilst silica can demonstrate remarkable selectivity for the separation of closely related isomers (e.g. E/Z isomers are commonly separated on silica), some of the operational demands of silica limit its usefulness. The difficulty of manufacturing reproducible microcrystalline silica and the possible effect of trace amounts of water on... 

Packed column SFC stationary phases are very similar or identical to those used for HPLC. With neat CO2 mobile phases, polymer or polymer-coated silica stationary phases have typically been used. With modified-C02 mobile phases, bonded-phase silica columns are typically used. For structural separations, diol, amino, or cyano stationary phases are most often used. For stereochemical separations, derivatized polysaccharide-bonded silica columns are most often the stationary phases of choice. A powerful feature of modified-C02 pSFC is the ability to serially connect different stationary phases to obtain enhanced or mul-... 

There are many applications of normal-phase chromatography to separate all eight vitamers using silica or bonded silica phases such as diol or amino (Table 1.5 Figure 1.4). The separation of 3- and y-tocopherols and tocotrienols is the most difficult task, but it can be achieved with normal-phase HPLC. In addition to its... 

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