Pirkle phases applications

There is a wide variety of commercially available chiral stationary phases and mobile phase additives.32 34 Preparative scale separations have been performed on the gram scale.32 Many stationary phases are based on chiral polymers such as cellulose or methacrylate, proteins such as human serum albumin or acid glycoprotein, Pirkle-type phases (often based on amino acids), or cyclodextrins. A typical application of a Pirkle phase column was the use of a N-(3,5-dinitrobenzyl)-a-amino phosphonate to synthesize several functionalized chiral stationary phases to separate enantiomers of... 

More recent developments in the field of the Pirkle-type CSPs are the mixed r-donor/ r-acceptor phases such as the Whelk-Of and the Whelk-02 phases.The Whelk-Of is useful for the separation of underiva-tized enantiomers from a number of families, including amides, epoxides, esters, ureas, carbamates, ethers, aziridines, phosphonates, aldehydes, ketones, carboxylic acids, alcohols and non-steroidal anti-inflammatory drugs.It has been used for the separation of warfarin, aryl-amides,aryl-epoxides and aryl-sulphoxides. The phase has broader applicability than the original Pirkle phases. The broad versatility observed on this phase compares with the polysaccharide-derived CSPs... 

For applications such as enantiopohshing or chiral separations, MIPs are said to offer low capacity. This is true when comparing MIPs with sorbents that rely on an interaction with a surface or a surface modified with a chiral selector (e.g. Pirkle phases). On the other hand, MIPs are at least competitive if one compares their atom economy with that of enzymes or antibodies adding up the molar mass of crosslinker and receptor sites per template (between 5-100kDa depending on synthesis recipe) [14]. 

In order to broaden the capabilities of the Pirkle concept, both polar and polarizable groups were introduced into the molecule. The most popular of this type of chiral stationary phase are the (R,R) Whelk-01 and the (S,S)Whelk-01 phases, the structures of which are shown below. These phases are more versatile and have a wider field of application than the phases previously described. The phases are covalently bonded to the silica and so they can be used with almost any type of solvent. However, they have been found to operate most effectively in the normal phase mode. It should be noted that the polarizable character of the aromatic ring is essential for the stationary phase to function well. As the Pirkle phases are generally available in both the (R) and (S) configurations, the reversal of the elution order of a pair of enantiomers is possible. This stationary phase was originally designed for the separation of the Naproxen enantiomers but has found a wide application to the separation of epoxides, alcohols, diols, amides, imides and carbamates. 

Most of the Pirkle phases, and in particular the Whelk-01 phase, are stable to all types of solvent and can be used either in the reversed phase mode, or the normal mode, which again, adds to its universal applicability. In the normal phase mode of development, hexane/IPA would be a good mobile phase from which to start. A mixture, hexane/IPA 80/20 v/v, would be a practical scouting composition to assess the possible level of retention and chiral selectivity. Again,... 

In view of the importance of chiral resolution and the efficiency of liquid chromatographic methods, attempts are made to explain the art of chiral resolution by means of liquid chromatography. This book consists of an introduction followed by Chapters 2 to 8, which discuss resolution chiral stationary phases based on polysaccharides, cyclodextrins, macrocyclic glyco-peptide antibiotics, Pirkle types, proteins, ligand exchangers, and crown ethers. The applications of other miscellaneous types of CSP are covered in Chapter 9. However, the use of chiral mobile phase additives in the separation of enantiomers is discussed in Chapter 10. 

The Pirkle-type chiral stationary phases are quite stable and exhibit good chiral selectivities to a wide range of solute types. These CSPs are also popular for the separation of many drug enantiomers and for amino acid analysis. Primarily, direct chiral resolution of racemic compounds were achieved on these CSPs. However, in some cases, prederivatization of racemic compounds with achiral reagents is required. The applications of these phases are discussed considering re-acidic, re-basic, and re-acidic-basic types of CSP. These CSPs have also been found effective for the chiral resolution on a preparative scale. Generally, the normal phase mode was used for the chiral resolution on these phases. However, with the development of new and more stable phases, the reversed phase mode became popular. 

Terfloth, G.J., Pirkle, W.H., Lynam, K.G., and Nicolas, E.C. 1995. Broadly applicable polysi-loxane-based chiral stationary phase for high-performance liquid chromatography and supercritical fluid chromatography. Journal of Chromatography A, 705 185-94. 

Modified-C02 mobile phases excel at stereochemical separations, more often than not outperforming traditional HPLC mobile phases. For the separation of diastereomers, silica, diol-bonded silica, graphitic carbon, and chiral stationary phases have all been successfully employed. For enantiomer separations, the derivatized polysaccharide, silica-based Chiralcel and Chiralpak chiral stationary phases (CSPs) have been most used, with many applications, particularly in pharmaceutical analysis, readily found in the recent literature (reviewed in Refs. 1 and 2). To a lesser extent, applications employing Pirkle brush-type, cyclodextrin and antibiotic CSPs have also been described. In addi-... 

The brush-type of CSP was introduced by Pirkle who was one of the pioneers of modern enantioselective liquid chromatography [55]. The most frequently used 7i-acceptor phases are derived from the amino acids phenylglycine (DNBPG) (Fig. 6.8) or leucine (DNBLeu) covalently or ionically bonded to 3-aminopropyl silica gel [56, 57]. These CSPs are commercially available for analytical or preparative separation of enantiomers. Further CSPs based on amino acid or amine chiral selectors such as valine, phenylalanine, tyrosine [58] and l,2-tr s-diaminocyclohexane (DACH-DNB phase) [59] and 1,2-traus-diphenylethylene diamine (ULMO phase) [60] were also developed (Fig. 6.8). These CSPs have been applied for the preparative separation of the enantiomers of a few racemic compounds, but the number of reported preparative applications has remained very limited over the last 10 years. 

The application of the reciprocality concept has led to the design of various phases of the Ji-donor/acceptor type [61, 62]. One successful phase is the Whelk-O 1 CSP developed by Pirkle and Welch [63-65]. 

All five major chiral stationary phases have a very wide range of applications. Nevertheless, the selectivity that they achieve is sometimes limited and the separation ratios of the enantiomers small. As a consequence, relatively high efficiencies are usually necessary to achieve the desired resolution. Examples of the use of the popular protein stationary phases are the separation of the Verapamil isomers, and the epibatidine and vamicamide enantiomers. These chiral stationary phases have also been used to separate optical isomers of a leukotriene antagonist. The Pirkle chiral stationary phases are also very well-liked as... 

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