Chiral compounds chromatography

Analytically, the inclusion phenomenon has been used in chromatography both for the separation of ions and molecules, in Hquid and gas phase (1,79,170,171). Peralkylated cyclodextrins enjoy high popularity as the active component of hplc and gc stationary phases efficient in the optical separation of chiral compounds (57,172). Chromatographic isotope separations have also been shown to occur with the help of Werner clathrates and crown complexes (79,173). 

HPLC separations are one of the most important fields in the preparative resolution of enantiomers. The instrumentation improvements and the increasing choice of commercially available chiral stationary phases (CSPs) are some of the main reasons for the present significance of chromatographic resolutions at large-scale by HPLC. Proof of this interest can be seen in several reviews, and many chapters have in the past few years dealt with preparative applications of HPLC in the resolution of chiral compounds [19-23]. However, liquid chromatography has the attribute of being a batch technique and therefore is not totally convenient for production-scale, where continuous techniques are preferred by far. 

Achiral-chiral multidimensional chromatography remains one of the best ways to separate chiral analytes from interfering matrix components or other compounds. The flexibility offered by different operation modes, stationary and mobile phases, and configurations allows analysis methods to be tailored to the analytical problem. By offering possible configurations for both online sample cleanup and concentration, achiral/chiral LC/LC reduces manual sample preparation. The ability to be coupled to... 

Liquid Chromatography. The development of rapid, simple liquid chromatographic methods for determining the enantiomeric purity of chiral compounds is probably one of the most important developments in the study of asymmetric synthesis in the last 10 years. Several books have been published providing thorough evaluations of various enantiomeric separation techniques and their practical applications.46... 

Initially, chiral stationary phases for chiral liquid chromatography were designed for preparative purposes, mostly based on the concept of three-point recognition .47 Pirkle and other scientists48 developed a series of chiral stationary phases that usually contain an aryl-substituted chiral compound connected to silica gel through a spacer. Figure 1-14 depicts the general concept and an actual example of such a chiral stationary phase. 

It is possible to use chromatography to separate chiral compounds (enantiomers see Section 11.6). This technique uses a stationary phase... 

Since the natural target of macrocyclic antibiotics is the A-acyl-D-alanyl-D-alanine terminus (see Section 2.1), the early choice of suitable substrates for this kind of CSPs was that of amino acids [45]. However, it turned out that the macrocyclic CSPs were very successful not only in amino acids enantioresolution, but also in the separation of a wide variety of different structures. The early stages of application of macrocyclic antibiotics have been surveyed in the different fields of chromatography [1,2]. A summary of the different categories of chiral compounds separated by HPLC on glycopeptides containing CSPs is reported in Table 2.3. 

TABLE 3 Chiral Compounds Tested for Separation by Chiral Ion-Exchange Chromatography... 

Schubert V, Mosandl A, Chiral compounds of essential oils, VIII Stereodifferentiation of linalool using multidimensional gas chromatography, Phytochem Anal 2 171-174, 1991. 

Chromatography the enantiomers are converted into a pair of diastereomers by chemical reaction with an auxiliary (enantiomerically pure, chiral compound) and the ratio of the peak areas is determined by chromatography on an achiral stationary phase. 

Based on preliminary results from Helfferich130, further developments by Davankov and co-workers5 131 133 turned the principle of chelation into a powerful chiral chromatographic method by the introduction of chiral-complex-forming synlhetie resins. The technique is based on the reversible chelate complex formation of the chiral selector and the selectand (analyte) molecules with transient metal cations. The technical term is chiral ligand exchange chromatography (CLEC) reliable and complete LC separation of enantiomers of free a-amino acids and other classes of chiral compounds was made as early as 1968 131. 

Capillary gas chromatography (GC) using modified cyclodextrins as chiral stationary phases is the preferred method for the separation of volatile enantiomers. Fused-silica capillary columns coated with several alkyl or aryl a-cyclo-dextrin, -cyclodextrin and y-cyclodextrin derivatives are suitable to separate most of the volatile chiral compounds. Multidimensional GC (MDGC)-mass spectrometry (MS) allows the separation of essential oil components on an achiral normal phase column and through heart-cutting techniques, the separated components are led to a chiral column for enantiomeric separation. The mass detector ensures the correct identification of the separated components [73]. Preparative chiral GC is suitable for the isolation of enantiomers [5, 73]. 

Separations of enantiomers can be achieved by chiral chromatography. Even, when the enantioselective synthesis of drugs and pharmaceuticals is possible, a major part of chiral compounds is still produced as a racemate and needs to be separated into the enantiomers by chiral high performance liquid chromatography. 

Chromatography. Under certain conditions, even homochiral and het-erochiral self-assemblies can be separated by achiral methods. Thus, chromatography of partially resolved enantiomers can cause depletion or enrichment of enantiomers on achiral stationary phases with an achiral mobile phase. 14C-Labeled nicotine was first resolved into its enantiomers by high-performance liquid chromatography (HPLC) on an achiral stationary phase (Partisil-ODS or -SCX) through coinjection with optically active nicotine (59). This observation was followed by resolution of a number of chiral compounds by chromatography (<50-62) (Scheme 34). When a chiral diamide in 74% ee was separated on a Kieselgel 60... 

This unit describes those methods that can differentiate between enantiomers found in foods that contribute to their taste and aroma. These compounds are volatile odorants that are most easily analyzed using enantioselective high resolution-gas chromatography (HRGC). Other methods exist for the separation and analysis of chiral compounds, which include optical methods, liquid and planar chromatography, and electrophoresis, but for food volatiles, gas chromatography has evolved to the point where it is now the cornerstone for the most comprehensive analysis of volatile compounds. 

The requirements for analyzing food odorants are demanding. The system must have a sensitivity of a few parts per billion or less, and be capable of handling highly volatile compounds. Although many methods exist for the analysis of chiral compounds, gas chromatography is the only viable method for analyzing food odorants because many are present in amounts too low for detection by most analyti-... 

Kreis, P. and Mosandl, A. 1992. Chiral compounds of essential oils. Part XII. Authenticity control of rose oils, using enantioselective multidimensional gas chromatography. Flavour Fragrance J. 7 199-203. 

Sensors for the detection of enantiomers are of great interest, as so far the on-line monitoring of production processes and medical diagnostics using standard chemical analytical methods is not possible. Quite often only one enantiomer of a chiral compound is actually a bioactive therapeutic. Therefore a proper analysis of the final product is essential. Currently, this involves separation techniques like liquid chromatography, GC and capillary electrophoresis, and determination of enantiomeric purity with circular dichro-ism and specific rotation. These are all off-line procedures and therefore no real-time analysis can be performed. Sensing devices for the distinction of different enantiomers would be a much cheaper, faster and easier-to-use alternative for this task, amenable to automation. 

The analysis of chiral compounds to determine their optical purity is still not a trivial task. The analysis method has to differentiate between the two antipodes and, thus, has to involve a chiral agent. However, the development of chiral chromatography, especially HPLC (high-performance liquid chromatography), has done a significant amount to relieve this problem. The purpose of this book is to discuss large-scale synthetic reactions, but the reader is reminded that the development of chiral analytic methods may not have been a trivial undertaking in many examples. 

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