Enantioselectivity enhancement

When we first contemplated thermochemical products available from Glu, a search of the literature revealed no studies expressly directed at hydrogenation to a specific product. Indeed, the major role that Glu plays in hydrogenation reactions is to act as an enantioselectivity enhancer (17,18). Glu (or a number of other optically active amino acids) is added to solutions containing Raney nickel, supported nickel, palladium, or ruthenium catalysts and forms stereoselective complexes on the catalyst surface, leading to enantioselective hydrogenation of keto-groups to optically active alcohols. Under the reaction conditions used, no hydrogenation of Glu takes place. 

Earle, M. J., McCormac, P. B. Seddon, K. R. Diels-Alder reactions in ionic liquids a safe recyclable green alternative to lithium perchlorate-diethyl ether mixtures. Green Chem., 1999, 1(1), 23-25 Doherty, S. Goodrich, P. Hardacre, C. et al. Marked enantioselectivity enhancements for Diels-Alder reactions in ionic liquids catalysed by platinum diphosphine complexes. Green Chem., 2004, 6(1), 63-67. 

Persichetti, R-A., Lalonde, J.J., Govardhan, C.P., Khalaf, N.K. and Margolin, A.L. (1996) Candida-ragosa lipase—enantioselectivity enhancements in organic solvents. 

Enzymatic enantioselectivity in organic solvents can be markedly enhanced by temporarily enlarging the substrate via salt formation (Ke, 1999). In addition to its size, the stereochemistry of the counterion can greatly affect the enantioselectivity enhancement (Shin, 2000). In the Pseudomonas cepacia lipase-catalyzed propanolysis of phenylalanine methyl ester (Phe-OMe) in anhydrous acetonitrile, the E value of 5.8 doubled when the Phe-OMe/(S)-mandelate salt was used as a substrate instead of the free ester, and rose sevenfold with (K)-maridelic acid as a Briansted-Lewis acid. Similar effects were observed with other bulky, but not with petite, counterions. The greatest enhancement was afforded by 10-camphorsulfonic acid the E value increased to 18 2 for a salt with its K-enanliomer and jumped to 53 4 for the S. These effects, also observed in other solvents, were explained by means of structure-based molecular modeling of the lipase-bound transition states of the substrate enantiomers and their diastereomeric salts. 

AlAough Ae unique solvating properties of supercritical C( may be Ae cause of Ae enantioselectivity enhancements observed, differences in selectivity can be caused by pressure in conventional solvents as well. For this reason, we carried out two hyctogenation reactions of 5 in hexane at 40°C wiA catalyst 1 as Ae BARF... 

Doherty, S., Goodrich, P., Hardacre, C., Luo, H. K., Rooney, D.W., Seddon, KR. Styring, P. (2004). Marked Enantioselectivity Enhancements for Diels-Alder reactions in Ionic Liquids Catalysed by Platinum Diphosphine Complexes, Green Chem., 6, pp. 63-67... 

Copper-bis oxazolidinone complex catalyzed the addition of alkyl and aromatic alkynes to the imine formed by the reaction of ethyl glyoxylate and p-anisidine, providing an easy access to chiral p,Y-alkynyl a-amino acids in good yields (61-80%) and enantioselectivities (66-74%) [38]. The presence of the two phenyl groups in the ligand was found to be crucial in the enantioselectivity enhancement and reduction of the reaction time, with aryl alkynes providing better results than alkyl acetylene derivatives [39]. Another type of Cu(II)-pybox complex led to excellent results in terms of enantioselectivities (28-93% yield, 81-98% ee) in the reaction of aliphatic alkynes with aldehydes and amines [40]. 

Table 2 shows that the derivation of the amine group of amino acids can improve chiral recognition, e.g., the enantioselectivity factors of alanine are 1.8 and 2.7 on teicoplanin and TAG CSPs they become 13 and 3.6, respectively, upon derivati-zation of the amine group forming A-benzoyl alanine (Table 2). Enantioselectivity enhancement is very often obtained by N-derivatization of amino acids [14, 16]. Such enantiorecognition enhancement is not an absolute rule as shown by iV-benzoyl phenylalanine in Table 2. The phenylalanine enantioselectivity factors jumps from 1.5 (native form, Rs = 3.1) to 4.4 (N-benzoylated form, Rs = 11.4) on teicoplanin CSP. It decreases from 3.7 (native form, Rs = 13.7) down to 1.5 Rs = 2.6) after N-benzoylation on the TAG CSP. There is a clear steric effect due to the attached benzoyl group very beneficial for enantiorecognition on teicoplanin CSP and detrimental when the TAG CSP is used.

Cleij, M., Archelas, A. and Furstoss, R. (1998) Microbiological transformations. Part 42 A two-liquid-phase preparative scale process for an epoxide hydrolase catalysed resolution of parfl-bromo-a-methyl styrene oxide. Occurrence of a surprising enantioselectivity enhancement. Tetrahedron Asymmetry, 9, 1839-1842. 

Yang HM, Li L, Jiang KZ, Jiang JX, Lai GQ, Xu LW. Highly enantioselective synthesis of warfarin and its analogs by means of cooperative LiC104/DPEN-catalyzed Michael reaction enantioselectivity enhancement and mechanism. Tetrahedron 2010 66(51) 9708-9713. 

Most importantly, enantioselectivity benefits considerably from the use of water. This effect could be a result of water exerting a favourable influence on the cisoid - transoid equilibrium. Unfortunately, little is known of the factors that affect this equilibrium. Alternatively, and more likely, water enhances the efficiency of the arene - arene interactions. There is support for this observation"" . Since arene-arene interactions are held responsible for the enantioselectivify in many reactions involving chiral catalysts, we suggest that the enhancement of enantioselectivity by water might well be a general phenomenon. 

Optically Active Acids and Esters. Enantioselective hydrolysis of esters of simple alcohols is a common method for the production of pure enantiomers of esters or the corresponding acids. Several representative examples are summarized ia Table 4. Lipases, esterases, and proteases accept a wide variety of esters and convert them to the corresponding acids, often ia a highly enantioselective manner. For example, the hydrolysis of (R)-methyl hydratropate [34083-55-1] (40) catalyzed by Hpase P from Amano results ia the corresponding acid ia 50% yield and 95% ee (56). Various substituents on the a-carbon (41—44) are readily tolerated by both Upases and proteases without reduction ia selectivity (57—60). The enantioselectivity of many Upases is not significantly affected by changes ia the alcohol component. As a result, activated esters may be used as a means of enhancing the reaction rate. 

Perhaps the biggest impact on the practical utilization of enzymes has been the development of nonaqueous enzymology (11,16,33,35). The use of enzymes in nonaqueous media gready expands the scope of suitable transformations, simplifies thek use, and enhances stabiUty. It also provides an easy means of regulation of the substrate specificity and regio- and enantioselectivity of enzymes by changing the reaction medium. 

Nonselective membranes can assist enantioselective processes, providing essential nonchiral separation characteristics and thus making a chiral separation based on enantioselectivity outside the membrane technically and economically feasible. For this purpose several configurations can be applied (i) liquid-liquid extraction based on hollow-fiber membrane fractionation (ii) liquid- membrane fractionation and (iii) micellar-enhanced ultrafiltration (MEUF). 

In the short term, we do not expect chiral membranes to find large-scale application. Therefore, membrane-assisted enantioselective processes are more likely to be applied. The two processes described in more detail (liquid-membrane fractionation and micellar-enhanced ultrafiltration) rely on established membrane processes and make use of chiral interactions outside the membrane. The major advantages of these... 

Methanol remains the most widely used modifier because it produces highly efficient separations, but it does not always produce the highest selectivity [8]. Recent studies have provided insight into the role of the modifier in enantioselectivity in SFC [69]. Blackwell and Stringham examined a series of phenylalanine analogues on a brush-type CSP and developed a model that allowed prediction of selectivity based on the bulk solvation parameters of various modifiers [70]. Careful choice of modifiers can be used to mask or enhance particular molecular interactions and ultimately provide control of selectivity [71]. 

Diels-Alder reactions Neutral ionic liquids have been found to be excellent solvents for the Diels-Alder reaction. The first example of a Diels-Alder reaction in an ionic liquid was the reaction of methyl acrylate with cyclopentadiene in [EtNH3][N03] [40], in which significant rate enhancement was observed. Howarth et al. investigated the role of chiral imidazolium chloride and trifluoroacetate salts (dissolved in dichloromethane) in the Diels-Alder reactions between cyclopentadiene and either crotonaldehyde or methacroline [41]. It should be noted that this paper describes one of the first examples of a chiral cationic ionic liquid being used in synthesis (Scheme 5.1-17). The enantioselectivity was found to be < 5 % in this reaction for both the endo (10 %) and the exo (90 %) isomers. 

In contrast to 1, isomeric p-nitrophenyl nicotinate shows almost no catalysis. Thus, it is clear that substrate coordination to the metal ion complex plays the critical role for an enormous rate enhancement. The lipophilic ester (R = C5Hn) also undergoes a large rate enhancement indicating the importance of substrate binding into the micellar phase by hydrophobic interaction. A large rate enhancement can also be seen in lipophilic esters which lack the metal coordination site as given below with the enantioselective micellar reactions (Table 9, 10). 

Addition of (R,S)-9 to the aromatic benzaldehyde proceeded with higher enantiosclcctivity than the addition of the diastereomeric reagent (S,S)-9. The reverse is true for additions to aliphatic aldehydes. Thus, the highest enantioselectivity of 92% ee was observed in the addition of (R,R)- 9 to cyclohexanccarboxaldehyde. The low chemical yields of most addition reactions can be improved by addition of the Lewis acid diethylaluminum ethoxide. The presence of the Lewis acid solely enhanced the chemical yield without changing the enantioselectivity of the addition reactions. 

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