Enantioselectivity, with

Porcine liver esterase (PLE) gives excellent enantioselectivity with both dimethyl 3-methylglutarate [19013-37-7] (lb) and malonate (2b) diester. It is apparent from Table 1 that the enzyme s selectivity strongly depends on the size of the alkyl group in the 2-position. The hydrolysis of ethyl derivative (2c) gives the S-enantiomer with 75% ee whereas the hydrolysis of heptyl derivative (2d) results in the R-monoester with 90% ee. Chymotrypsin [9004-07-3] (CT) does not discriminate glutarates that have small substituents in the 3-position well. However, when hydroxyl is replaced by the much bulkier benzyl derivative (Ic), enantioselectivity improves significantly. 

In 1980, Katsuki and Sharpless communicated that the epoxidation of a variety of allylic alcohols was achieved in exceptionally high enantioselectivity with a catalyst derived from titanium(IV) isopropoxide and chiral diethyl tartrate. This seminal contribution described an asymmetric catalytic system that not only provided the product epoxide in remarkable enantioselectivity, but showed the immediate generality of the reaction by examining 5 of the 8 possible substitution patterns of allylic alcohols all of which were epoxidized in >90% ee. Shortly thereafter. Sharpless and others began to illustrate the... 

The first successful chiral resolutions through enantioselective membranes have been published recently, but few cases are applicable to the preparative scale, mainly due to mechanical and technical limitations. Low flow rates, saturation of the chiral selectors and loss of enantioselectivity with time are some of the common problems encountered and that should be solved in the near future. 

In recent years, a great variety of primary chiral amines have been obtained in enantiomerically pure form through this methodology. A representative example is the KR of some 2-phenylcycloalkanamines that has been performed by means of aminolysis reactions catalyzed by lipases (Scheme 7.17) [34]. Kazlauskas rule has been followed in all cases. The size of the cycle and the stereochemistry of the chiral centers of the amines had a strong influence on both the enantiomeric ratio and the reaction rate of these aminolysis processes. CALB showed excellent enantioselec-tivities toward frans-2-phenylcyclohexanamine in a variety of reaction conditions ( >150), but the reaction was markedly slower and occurred with very poor enantioselectivity with the cis-isomer, whereas Candida antarctica lipase A (GALA) was the best catalyst for the acylation of cis-2-phenylcyclohexanamine ( = 34) and frans-2-phenylcyclopropanamine ( =7). Resolution of both cis- and frans-2-phenyl-cyclopentanamine was efficiently catalyzed by CALB obtaining all stereoisomers with high enantiomeric excess. 

Organometallic aldehydes can be reduced enantioselectively with dehydrogenases. For example, optically active organometallic compounds having planar chiralities were obtained by biocatalytic reduction of racemic aldehydes with yeast [22c,d] or HLADH [22e] as shown in Figure 8.29. 

Enantioselective reduction is not possible for aldehydes, since the products are primary alcohols in which the reduced carbon is not chiral, but deuterated aldehydes RCDO give a chiral product, and these have been reduced enantioselectively with B-(3-pinanyl)-9-borabicyclo[3.3.1]nonane (Alpine-Borane) with almost complete optical purity. ... 

Scheme 7a-c. Switch in enantioselectivity with the reaction conditions... 

The reaction used to test these solid catalysts was the aziridination of styrene with AT-tosyliminophenyliodinane (Phi = NTos) (Scheme 10). In most cases, enantioselectivities were low or moderate (up to 60% ee). The loss of enantioselectivity on changing from ligand 11a to ligand 12 was attributed to the fact that ligand 12 is too big for the copper complex to be accommodated into the zeolite supercages. Further studies carried out with hgands 11a and 11b [62] demonstrated that the reaction is more enantioselective with the supported catalyst (82% ee with 11a and 77% ee with 11b) than in solution (54% ee with 11a and 31% ee with 11b). This trend supports the confinement effect of the zeolite structure on the stereoselectivity of the reaction. 

The variation of enantioselectivities with temperature and pressure was investigated. The effects of these two factors are very substrate dependent and difficult to generalize even in a single substrate serie. However, it seems that enantioselectivities are shghly better at 25-40 °C than at lower temperatures (0 °C or less). The stereoselectivity can be inverted for specific alkenes (formation of the S or R enantiomer preferentially). For several substrates, the reactions tend to proceed to completion with optimal ee s when performed at lower hydrogen pressure (2 bar) instead of 50 bar (Fig. 13). Pronoimced variation of enantioselectivities with hydrogen concentration in solution may indicate the presence of two (or even more) different mechanisms which happen to give opposite enantiomers for some substrates. 

In 2000, other S/N-ferrocenyloxazolines were prepared by Ai t-Haddou et al. starting from ehiral 2-amino-3-phenyl-l,3-propanediol. The corresponding P/N-analogues were also prepared in order to compare their efficiency in the test reaction. As shown in Scheme 1.68, both ligands gave good results in terms of both activity and enantioselectivity with a better result for the S/N ligand. 

In recent years, the variety of useful diazo substrates for asymmetric intramolecular cyclopropanation processes has really expanded. As another example, Charette and Wurz have reported the first example of an intramolecular cyclopropanation involving a-nitro-a-diazo carbonyl compounds.This reaction, catalysed by Rh2[(S)-DOSP]4, led to the formation of nine-membered nitrocyclopropyl lactones in good yields and enantioselectivities with extremely high diastereoselectivities (Scheme 6.17). This novel methodology constituted an efficient entry into chiral functionalised macrocyclic-fused cyclopropane oc-amino acids. 

As with aldol and Mukaiyama addition reactions, the Mannich reaction is subject to enantioselective catalysis.192 A catalyst consisting of Ag+ and the chiral imino aryl phosphine 22 achieves high levels of enantioselectivity with a range of N-(2-methoxyphenyljimines.193 The 2-methoxyphenyl group is evidently involved in an interaction with the catalyst and enhances enantioselectivity relative to other A-aryl substituents. The isopropanol serves as a proton source and as the ultimate acceptor of the trimethyl silyl group. 

The corresponding haloboranes are also useful for enantioselective hydrobo-ration. Isopinocampheylchloroborane can achieve 45-80% e.e. with representative alkenes.206 The corresponding bromoborane achieves 65-85% enantioselectivity with simple alkenes when used at —78° C.207... 

This complex is formed with more than 1.0 equivalents of (C2H5)2A1C1 with concomitant formation of Li2AICI2. The open and chelated structures have been characterized by NMR.90 The chelated structure is substantially more reactive than the open complex, which accounts for the increase in enantioselectivity with more than 1.0 equivalents of catalyst. 

Enantioselective Reactions of Organocopper Reagents. Several methods have been developed for achieving enantioselectivity with organocopper reagents. Chiral auxiliaries can be used for example, oxazolidinone auxiliaries have been utilized in conjugate additions. The outcome of these reactions can be predicted on the basis of steric control of reactant approach, as for other applications of the oxazolidinone auxiliaries. 

With unhindered aldehydes such as cyclohexanecarboxaldehyde, the diastereoselec-tivity is higher than 95%, with the F-boronate giving the anti adduct and the Z-boronate giving the syn adduct. Enantioselectivity is about 90% for the F-boronate and 80% for the Z-boronate. With more hindered aldehydes, such as pivaldehyde, the diastere-oselectivity is maintained but the enantioselectivity drops somewhat. These reagents also give excellent double stereodifferentiation when used with chiral aldehydes. For example, the aldehydes 3 and 4 give at least 90% enantioselection with both the E- and Z-boronates.43... 

Enantioselective Addition Reactions of Allylic Stannanes. There have been several studies of the enantiomers of a-oxygenated alkenyl stannanes. The chirality of the a-carbon exerts powerful control on enantioselectivity with the preference for the stannyl group to be anti to the forming bond. This is presumably related to the stereoelectronic effect that facilitates the transfer of electron density from the tin to the forming double bond.182... 

Protection of the nitrogen in 4 faced the classical N- versus O-alkylation selectivity issue, which was solved by selection of the solvent system. The original protecting group, pMB, was replaced with 9-anthrylmethyl (ANM), which provided the best enantioselectivity with the newly discovered asymmetric addition to the ketimine. 

Jacobsen et al. reported that a different type of dintrogen ligand (48), fe[(2,6-dichlorophenyl)-methylideneaminojcyclohexane, was an efficient chiral ligand for copper-mediated asymmetric aziridination (Scheme 35).154 The reactions of conjugated c/.v-olefins show high enantioselectivity with this catalyst, but enantioselectivity of the reactions of simple olefins such as styrene and indene is moderate. 

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