Optically active compounds synthesis, Resolution

In a catalytic asymmetric reaction, a small amount of an enantio-merically pure catalyst, either an enzyme or a synthetic, soluble transition metal complex, is used to produce large quantities of an optically active compound from a precursor that may be chiral or achiral. In recent years, synthetic chemists have developed numerous catalytic asymmetric reaction processes that transform prochiral substrates into chiral products with impressive margins of enantio-selectivity, feats that were once the exclusive domain of enzymes.56 These developments have had an enormous impact on academic and industrial organic synthesis. In the pharmaceutical industry, where there is a great emphasis on the production of enantiomeri-cally pure compounds, effective catalytic asymmetric reactions are particularly valuable because one molecule of an enantiomerically pure catalyst can, in principle, direct the stereoselective formation of millions of chiral product molecules. Such reactions are thus highly productive and economical, and, when applicable, they make the wasteful practice of racemate resolution obsolete. 

There are two possible approaches for the preparation of optically active products by chemical transformation of optically inactive starting materials kinetic resolution and asymmetric synthesis [44,87], For both types of reactions there is one principle in order to make an optically active compound we need another optically active compound. A kinetic resolution depends on the fact that two enantiomers of a racemate react at different rates with a chiral reagent or catalyst. Accordingly, an asymmetric synthesis involves the creation of an asymmetric center that occurs by chiral discrimination of equivalent groups in an achiral starting material. This can be done either by enan-tioselective (which involves the reaction of a prochiral molecule with a chiral substance) or diastereoselective (which involves the preferential formation of a single diastereomer by the creation of a new asymmetric center in a chiral molecule) synthesis. 

Since the early times of stereochemistry, the phenomena related to chirality ( dis-symetrie moleculaire, as originally stated by Pasteur) have been treated or referred to as enantiomericaUy pure compounds. For a long time the measurement of specific rotations has been the only tool to evaluate the enantiomer distribution of an enantioimpure sample hence the expressions optical purity and optical antipodes. The usefulness of chiral assistance (natural products, circularly polarized light, etc.) for the preparation of optically active compounds, by either resolution or asymmetric synthesis, has been recognized by Pasteur, Le Bel, and van t Hoff. The first chiral auxiliaries selected for asymmetric synthesis were alkaloids such as quinine or some terpenes. Natural products with several asymmetric centers are usually enantiopure or close to 100% ee. With the necessity to devise new routes to enantiopure compounds, many simple or complex auxiliaries have been prepared from natural products or from resolved materials. Often the authors tried to get the highest enantiomeric excess values possible for the chiral auxiliaries before using them for asymmetric reactions. When a chiral reagent or catalyst could not be prepared enantiomericaUy pure, the enantiomeric excess (ee) of the product was assumed to be a minimum value or was corrected by the ee of the chiral auxiliary. The experimental data measured by polarimetry or spectroscopic methods are conveniently expressed by enantiomeric excess and enantiomeric... 

Production. Many industrial processes exist for the production of menthols. For (—)-menthol, isolation from peppermint oil (see Mint Oils) competes with partial and total syntheses. When an optically active compound is used as a starting material, optical activity must be retained throughout the synthesis, which generally consists of several steps. Total syntheses or syntheses starting from optically inactive materials require either resolution of racemic mixtures or asymmetric synthesis of an intermediate. Recently used processes are the following ... 

Although some kinds of optically active compounds can be prepared by an asymmetric synthesis using a chiral catalyst, this method is not applicable for preparation of all kinds of compounds. Furthermore, optical yields of the product are not always very high. On the contrary, optical resolution method by inclusion complexation with a chiral host is applicable to various kinds of guest compounds as described in this chapter. When optically pure product cannot be obtained by one resolution procedure, perfect resolution can be accomplished by repeating the process, although asymmetric synthetic process cannot be repeated. Especially, optical resolutions by inclusion complexation with a chiral host in a water suspension medium and by fractional distillation in the presence of a chiral host are valuable as green and sustainable processes. 

Relatively few applications of optically active tertiary arsines to asymmetric synthesis have been reported by comparison with the extensive work with phosphines . Authoritative accounts of the synthesis and stereochemistry of compounds of Group V elements are available other reviews cover the subject up until 1979 . For general treatments of organoarsenic chemistry up until 1976, including optically active compounds, two important works are available . Of related interest is an article on stereochemical aspects of phosphorus chemistry and another published in this series on optically active phosphines preparation, uses and chiroptical properties . On matters concerning the intricacies of resolutions work, the reader should consult Reference 21, especially Chapter 7, which is entitled Experimental Aspects and Art of Resolutions. 

Pasteur s success in 1848 of the first enantiomer separation (optical resolution) of racemic acid as ammonium sodium ( )-tartrate tetrahydrate together with McKenzie s success in 1904 of the first asymmetric synthesis prompted many chemists to synthesize optically active compounds without recourse to the vital force of organisms, although by employing the capacity of a special species of organism, Homo sapiens, to discriminate left from right. Pasteur remarked in 1883 that The universe is dissymmetric. Since then chemists efforts have been focused on the control of asymmetry in this world of chiral and nonracemic materials. 

There are three methods available for the enantioselective synthesis of pheromones (1) derivation from enantiopure natural products, (2) enantiomer separation (optical resolution), and (3) chemical or biochemical asymmetric synthesis. Practitioners of enantioselective synthesis must be familiar with the analytical methods for the determination of enantiomeric purity of an optically active compound. These basic methods will be explained briefly in this section, and discussed in depth through examples in the later sections of this chapter. 

Numerous tetrahedral optically active organosilicon compounds have now been obtained, and various resolution procedures have been successfully employed. They include resolution through separation of diastereomers as well as kinetic resolution and asymmetric synthesis. Moreover, the stereospecificity of substitution reaction at silicon makes possible the synthesis of various optically active compounds starting from resolved organosilicon compounds. 

A method introduced by Velluz (1957) involves seeding of a supersaturated solution of a racemate (an equimolar mixture of d- and 1-isomers obtained in the last step of synthesis of a compound capable of showing optical isomerism) with crystals of the optically active isomer sought. Resolution of dl-chloramphenicol... 

Resolution of enantiomers, separation of diastereomers, asymmetric synthesis, microbial and enzymatic reactions and synthesis from chiral starting materials are all methods for producing optically active compounds. 

Though asymmetric hydrogenation, isomerization, and epoxidation have been well developed for the synthesis of enantiopure compounds, the universality of these methods is limited. Classical resolution of a racemate with a chiral auxiliary is typically used by chemists for manufacturing optically active compounds, although these methods suffer from low efficiency and large amounts of waste. More importantly, the limitations are aggravated by the unsatisfactory optical purity of the products. 

It has been demonstrated that the combination of metal-catalysed racemisation and enzymatic kinetic resolution is a powerful method for the synthesis of optically active compounds from racemic alcohols and amines. There are many metal complexes active for racemisation, but the conditions for enzymatic acylation often limit the application of the metal complexes to DKR. In the case of DKR of alcohols, complementary catalyst systems are now available for the synthesis of both (R)- and (5)-esters. Thus, (R)-esters can be obtained by the combination of an R-selective lipase, such as CAL-B or LPS, and a racemisation catalyst, whereas the use of an A-selective protease, such as subtilisin, at room temperature provides (5)-esters. The DKR of alcohols can be achieved not only for simple alcohols but also for those bearing various additional functional groups. The DKR of alcohols has also been applied to the synthesis of chiral polymers and coupled to tandem reactions, producing various polycyclic compounds. 

In order to obtain more knowledge about the requirements for the chromatographic resolution of racemic mixtures we synthesized optically active polymers (OAP) which were used as adsorbants. For the synthesis of the OAP we chose the reaction of reactive but optically inactive polymers with low-molecular weight optically active compounds. 

Akai, S. (2014). Dynamic kinetic resolution of racemic allylic alcohols via hydrolase-metal combo catalysis An effective method for the synthesis of optically active compounds. Chem. Lett., 43,746-754. 

Sheldon RA. Racemate resolution via crystallization. In Sheldon RA, editor. Chiro technology industrial synthesis of optically active compounds. New York Marcel Dekker 1993. p 191-192. 

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