High chirality

A similar effect occurs in highly chiral nematic Hquid crystals. In a narrow temperature range (seldom wider than 1°C) between the chiral nematic phase and the isotropic Hquid phase, up to three phases are stable in which a cubic lattice of defects (where the director is not defined) exist in a compHcated, orientationaHy ordered twisted stmcture (11). Again, the introduction of these defects allows the bulk of the Hquid crystal to adopt a chiral stmcture which is energetically more favorable than both the chiral nematic and isotropic phases. The distance between defects is hundreds of nanometers, so these phases reflect light just as crystals reflect x-rays. They are called the blue phases because the first phases of this type observed reflected light in the blue part of the spectmm. The arrangement of defects possesses body-centered cubic symmetry for one blue phase, simple cubic symmetry for another blue phase, and seems to be amorphous for a third blue phase. 

The reaction of allyl-9-BBN with the chiral imine 1 gives the Cram isomer 2 predominantly5,6. The 1,3-asymmetric induction is developed by a transition state 3, in which the 1,2-axial-equa-torial interaction between R and the ligand (L) plays an important role in the high chiral induction. 

The first gold catalyzed C-S bond formation was demonstrated in a route to the 2,5-dihydrothiophene 16 via cycloisomerization of the allene 17 which occurred with high chirality transfer (d.r. > 95 5) <06AG(E)1897>. 

Among optically active polymers, polysaccharide derivatives are particularly valuable. Polysaccharides such as cellulose and amylose are the most readily available optically active polymers and have stereoregular sequences. Although the chiral recognition abilities of native polysaccharides are not remarkable, they can be readily converted to the esters and carbamates with high chiral recognition abilities. The chiral recognition mechanism of these derivatives has been clarified to some extent. 

Reactions of aldehydes with complexes 13—17 provide optically active homoallylic alcohols. The enantioselectivities proved to be modest for 13—16 (20—45% ee). In contrast, they are very high (> 94% ee) for the (ansa-bis(indenyl))(r]3-allyl)titanium complex 17 [32], irrespective of the aldehyde structure, but only for the major anti diastereomers, the syn diastereomers exhibiting a lower level of ee (13—46% ee). Complex 17 also gives high chiral induction (> 94% ee) in the reaction with C02 [32], in contrast to complex 12 (R = Me 11 % ee R = H 19% ee) [15]. Although the aforementioned studies of enan-... 

In face of the above discouraging results, recent innovative catalyst work has led to highly effective solutions for some otherwise very difficult and expensive problems. For example. Dolling and co-workers (Chapter 7) have shown that by careful choice of PTC catalyst and use of optimal reaction conditions one can obtain high chiral selectivity (greater than 90% enantiomeric excess) and have applied this chemistry to a commercial process for production of the diuretic drug candidate Indacrinone. 

The short-end injection was also used in a paper by Perrin et al. [28]. They saw a very high chiral recognition capability of highly sulfated cyclodextrins (HS-CD). Using a test set of 27 amino acid derivatives, the application of HS-a-CD, HS-fl-CD, and HS-y-CD in a 5% w/v concentration allowed the separation of 26 compounds, of which 22 had a Rs > 2. From their experiments, a screening and optimization scheme was derived (Figure 3.3), and based on this scheme, a separation strategy was defined... 

Hsu s group in Taiwan have developed a procedure for the synthesis of (Y)-2-amino-4-phenylbutanoic acid, the phenylalanine homologue with one additional methylene group. Hydantoinase and L-A-carbamoylase genes have been cloned from different Bacillus species and overexpressed in E. coli. Both the R- and the 5-enantiomers were cleaved by the hydantoinase, but only the 5-form of the A-carbamoyl amino acid was hydrolyzed by the second enzyme. The reactions could be run in a single pot, with successive addition of the two enzymes, and were successful in the sense of giving a product of high chiral purity. However, the yield was... 

Song et al. [62] reported poly-salen Co(III) complexes 18, 19 as catalyst for HKR (Figure 5) of terminal alkene epoxides. The polymeric catalysts provided product epoxides with excellent conversion (>49%) and high chiral purity (ee s, 98%) and the catalytic system could be recycled once with retention of activity and enantioselectivity. 

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