Enantioselective Techniques

Tetrahedral Prochiral Carbons Have a Pro-R Group and a Pro-S Group 

Trigonal Planar Prochiral Carbons Have a Re Face and a Si Face 

In a similar manner, a racemic amine could be resolved using a chiral carboxylic acid, such as the naturally occurring tartaric acid. 

Resolution of compounds containing functional groups that are not acidic or basic requires a reversible functional group interconversion involving a chiral resolving agent. For example, the reaction of a racemic alcohol with a chiral carboxylic acid results in a mixture of diastereomeric esters that can be separated. After separation, hydrolysis of the ester regenerates the desired alcohol. To resolve a racemic ketone or aldehyde, a reaction with a chiral diol or a chiral amine could be employed to form diastereomeric acetals or imines, respectively. 

Asymmetric synthesis represents a robust field of research, with entire journals and books devoted to the topic. The current literature is full of examples of new and improved chiral reagents, catalysts, and auxiliaries that can be used for enantioselective syntheses. In every case, a chiral environment is produced that favors reaction with one prochiral face of a planar center, or one prochiral group of a tetrahedral center. The ongoing research seeks to not only develop 

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For all chromatographic enantioselective techniques it is necessary to create a chiral environment. If the method of separation is LC, especially high-performance liquid chromatography, four different techniques are available ordered in decreasing importance they are given as follows ... 

The Sharpless asymmetric epoxidation of allylic alcohols (one of the reactions that helped K. Barry Sharpless earn his part of the 2001 Nobel Prize) offers a good example of an enantioselective technique that can be used to create either enantiomer of an epoxide product. This reaction uses a diester of tartaric acid, such as diethyl tartrate (DET) or diisopropyl tartrate (DIPT), as the source of chirality. The dialkyl tartrate coordinates with the titanium tetraisopropoxide [Ti(Oi-Pr)4] catalyst and t-butyl hydroperoxide (r-BuOOH) to make a chiral oxidizing agent. Since both enantiomers of tartaric acid are commercially available, and each enantiomer will direct the reaction to a different prochiral face of the alkene, both enantiomers of an epoxide can be synthesized. 

To our knowledge, the results presented in this chapter provide the first example of enantioselective Lewis-acid catalysis of an organic reaction in water. This discovery opens the possibility of employing the knowledge and techniques from aqueous coordination chemistry in enantioselective catalysis. This work represents an interface of two disciplines hitherto not strongly connected. 

Clearly, there is a need for techniques which provide access to enantiomerically pure compounds. There are a number of methods by which this goal can be achieved . One can start from naturally occurring enantiomerically pure compounds (the chiral pool). Alternatively, racemic mixtures can be separated via kinetic resolutions or via conversion into diastereomers which can be separated by crystallisation. Finally, enantiomerically pure compounds can be obtained through asymmetric synthesis. One possibility is the use of chiral auxiliaries derived from the chiral pool. The most elegant metliod, however, is enantioselective catalysis. In this method only a catalytic quantity of enantiomerically pure material suffices to convert achiral starting materials into, ideally, enantiomerically pure products. This approach has found application in a large number of organic... 

Of all the work described in this thesis, this discovery is probably the most significant. Given the fact that the arene - arene interactions underlying the observed enantioselectivity of ftie Diels-Alder reactions described in Chapter 3 are also encountered in other organic reactions, we infer that, in the near future, the beneficial influence of water on enantioselectivity can also be extended to these transformations. Moreover, the fact that water can now be used as a solvent for enantioselective Lewis-add catalysed reactions facilitates mechanistic studies of these processes, because the number of equilibria that need to be considered is reduced Furthermore, knowledge and techniques from aqueous coordination chemistry can now be used directly in enantioselective catalysis. 

The dependence of chiral recognition on the formation of the diastereomeric complex imposes constraints on the proximity of the metal binding sites, usually either an hydroxy or an amine a to a carboxyHc acid, in the analyte. Principal advantages of this technique include the abiHty to assign configuration in the absence of standards, enantioresolve non aromatic analytes, use aqueous mobile phases, acquire a stationary phase with the opposite enantioselectivity, and predict the likelihood of successful chiral resolution for a given analyte based on a weU-understood chiral recognition mechanism. 

On that basis, crystallization is often used in combination with other enantiose-lective techniques, such as enantioselective synthesis, enzymatic kinetic resolution or simulated moving bed (SMB) chromatography [10, 11]. In general, when referring to crystallization techniques, the aim is to obtain an enantiomeric enrichment in the crystallized solid. However, the possibility of producing an enrichment in the mother liquors [12, 13], even if this is not a general phenomenon [14], must be taken into account. 

Among the existing separation techniques, some - due to their intrinsic characteristics - are more adapted than others to processing large amounts of material. Such processes, which already exist at industrial level, can be considered in order to perform an enantioselective separation. This is the case for techniques such as distillation and foam flotation, both of which constitute well-known techniques that can be adapted to the separation of enantiomers. The involvement of a chiral selector can be the clue which changes a nonstereoselective process into an enantioselective one. Clearly, this selector must be adapted to the characteristics and limitations of the process itself. 

All enantioselective separation techniques are based on submitting the enantiomeric mixture to be resolved to a chiral environment. This environment is usually created by the presence of a chiral selector able to interact with both enantiomers of the mixture, albeit with different affinities. These differences in the enantiomer-selector association will finally result in the separation that is sought. 

In general, high selectivities can be obtained in liquid membrane systems. However, one disadvantage of this technique is that the enantiomer ratio in the permeate decreases rapidly when the feed stream is depleted in one enantiomer. Racemization of the feed would be an approach to tackle this problem or, alternatively, using a system containing the two opposite selectors, so that the feed stream remains virtually racemic [21]. Another potential drawback of supported enantioselective liquid membranes is the application on an industrial scale. Often a complex multistage process is required in order to achieve the desired purity of the product. This leads to a relatively complicated flow scheme and expensive process equipment for large-scale separations. 

A number of studies have recently been devoted to membrane applications [8, 100-102], Yoshikawa and co-workers developed an imprinting technique by casting membranes from a mixture of a Merrifield resin containing a grafted tetrapeptide and of linear co-polymers of acrylonitrile and styrene in the presence of amino acid derivatives as templates [103], The membranes were cast from a tetrahydrofuran (THF) solution and the template, usually N-protected d- or 1-tryptophan, removed by washing in more polar nonsolvents for the polymer (Fig. 6-17). Membrane applications using free amino acids revealed that only the imprinted membranes showed detectable permeation. Enantioselective electrodialysis with a maximum selectivity factor of ca. 7 could be reached, although this factor depended inversely on the flux rate [7]. Also, the transport mechanism in imprinted membranes is still poorly understood. 

The development of Sharpless asymmetric epoxidation (SAE) of allylic alcohols in 1980 constitutes a breakthrough in asymmetric synthesis, and to date this method remains the most widely applied asymmetric epoxidation technique [34, 44]. A wide range of substrates can be used in the reaction ( ) -allylic alcohols generally give high enantioselectivity, whereas the reaction is more substrate-dependent with (Z)-allylic alcohols [34]. 

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