Enantioselective addition reactions

The target molecule above contains a chiral center. An enantioselective synthesis can therefore be developed We use this opportunity to summarize our knowledge of enantioselective reactions. They are either alkylations of carbanions or addition reactions to C = C or C = 0 double bonds ... 

There are a number of powerful synthetic reactions which join two trigonal carbons to form a CC single bond in a stereocontrolled way under proper reaction conditions. Included in this group are the aldol, Michael, Claisen rearrangement, ene and metalloallyl-carbonyl addition reactions. The corresponding transforms are powerfully stereosimplifying, especially when rendered enantioselective as well as diastereoselective by the use of chiral controller groups. Some examples are listed in Chart 20. 

Finally, use the relative amounts of the different cation conformers along with the reactivity preference of each conformer to determine the overall enantioselectivity of the addition reaction. Do you expect more R or S 2-butyl bromide to form Explain how you arrived at this answer. 

In a more recent study on 1,3-dipolar cycloaddition reactions the use of succi-nimide instead of the oxazolidinone auxiliary was introduced (Scheme 6.19) [58]. The succinimide derivatives 24a,b are more reactive towards the 1,3-dipolar cycloaddition reaction with nitrone la and the reaction proceeds in the absence of a catalyst. In the presence of TiCl2-TADDOLate catalyst 23a (5 mol%) the reaction of la with 24a proceeds at -20 to -10 °C, and after conversion of the unstable succinimide adduct into the amide derivative, the corresponding product 25 was obtained in an endojexo ratio of <5 >95. Additionally, the enantioselectivity of the reaction of 72% ee is also an improvement compared to the analogous reaction of the oxazolidinone derivative 19. Similar improvements were obtained in reactions of other related nitrones with 24a and b. 

Quite a number of asymmetric thiol conjugate addition reactions are known [84], but previous examples of enantioselective thiol conjugate additions were based on the activation of thiol nucleophiles by use of chiral base catalysts such as amino alcohols [85], the lithium thiolate complex of amino bisether [86], and a lanthanide tris(binaphthoxide) [87]. No examples have been reported for the enantioselective thiol conjugate additions through the activation of acceptors by the aid of chiral Lewis acid catalysts. We therefore focussed on the potential of J ,J -DBFOX/ Ph aqua complex catalysts as highly tolerant chiral Lewis acid catalyst in thiol conjugate addition reactions. 

As shown above, it was not so easy to optimize the Michael addition reactions of l-crotonoyl-3,5-dimethylpyrazole in the presence of the l ,J -DBFOX/ Ph-Ni(C104)2 3H20 catalyst because a simple tendency of influence to enantio-selectivity is lacking. Therefore, we changed the acceptor to 3-crotonoyl-2-oxazolidi-none in the reactions of malononitrile in dichloromethane in the presence of the nickel(II) aqua complex (10 mol%) (Scheme 7.49). For the Michael additions using the oxazolidinone acceptor, dichloromethane was better solvent than THF and the enantioselectivities were rather independent upon the reaction temperatures and Lewis base catalysts. Chemical yields were also satisfactory. 

Finally we have performed the Michael addition reactions of malononitrile and 3-(2-alkenoyl)-2-oxazolidinones in dichloromethane in the presence of the R,R-DBF0X/Ph-Ni(C104)2-31 20 and TMP (10 mol% each). Enantioselectivities were a little lower than 90% ee for acceptors having a variety of / -substituents. The best selectivity was 94% ee in the reaction of t-butyl-substituted acceptor (Scheme 7.50). 

Copper-catalyzed Enantioselective Conjugate Addition Reactions of Organozinc Reagents... 

With the use of chiral reagents a differentiation of enantiotopic faces is possible, leading to an enantioselective reaction. The stereoselective version of the Michael addition reaction can be a useful tool in organic synthesis, for instance in the synthesis of natural products. 

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. 

With both diastereomers (S,R)-9 and (R,R)-9 the same enantiomer is predominantly formed. Therefore, the enantioselectivity of the addition reactions is induced by the chirality of the fcrrocenyl moiety rather than by the chirality of the aminoethyl substituent. 

The first reports on enantioselective addition reactions of achiral organometallic reagents, modified by aprotic chiral additives, described the addition of Grignard reagents to prostereogenic carbonyl compounds in the presence of ( + )-(/ ,/J)-2,3-dimethoxybutane (l)4 5, (-)-tetrahydro-2-methylfuran (2)6, (-)-l-[(tetrahydro-2-furanyl)methyl]pyrrolidine (3)7 or (-)-sparteine (4)8. The enantioselectivity, however, was poor (0-22% ee). 

Addition reactions to aldehydes in the presence of the tartaric acid derived chiral auxiliaries (.S ..S )-l,2,3,4-tetramethoxybutane (5), (S,.S)-2,3-dimethoxy-A%V,/V, A,, -tctramethyl-l,4-bu-tanediamine (6) and (5,5)-2,3-bis[2-(dimethylamino)ethoxy]-Af,yV,A. iV -tetramethyl-l,4-bu-tanediamine (7) have been studied in detail9" u. Again there was low enantioselection (generally 10-55% ee). 

A remarkable effect of the reaction temperature on the enantioselectivity of the addition of butyllithium to benzaldehyde was found with polystyrene-bound cvs-enofo-S-dimethylamino -(benzyloxy)bornane (8)12. When the soluble monomeric ligand 9 was tested, the enantioselectivity increased with decreasing temperature (53% ee at — 78 C). In contrast, the polymer-bound chiral additive 8 showed an optimum at — 20 C (32% ee). Although the enantioselectivity of this addition reaction is low, an advantage of a polymer-bound chiral auxiliary is that it can be removed by a simple filtration. 

The methyltitanium reagents 37 modified by the chiral 2-pyrrolidinemethanols 36 also did not show satisfactory enantioselectivities in addition reactions to aromatic aldehydes35. Noteworthy, however, is the fact that the enantioselectivity substantially increases with the change from A-methyl to A-acyl substituents. 

The synthesis of 4-alkyl-y-butyrolactones 13 and 5-alkyl-<5-valerolactones 14 can be achieved in high enantiomeric excess by alkylation of ethyl 4-oxobutanoate and ethyl 5-oxopentanoate (11, n = 2, 3). The addition of diethylzinc, as well as dimethylzinc, leads to hydroxy esters 12 in high optical purity. When methyl esters instead of ethyl esters are used as substrates, the enantioselectivity of the addition reaction is somewhat lower. Alkaline hydrolysis of the hydroxy esters 12, followed by spontaneous cyclization upon acidification, leads to the corresponding y-butyro- and -valerolactones32. 

Table 4. Utilization of 1,3-Dicarbon-Substituted Allyl Anions in Enantioselective Carbonyl Addition Reactions...

The Diels-Alder reaction of nonyl acrylate with cyclopentadiene was used to investigate the effect of homochiral surfactant 114 (Figure 4.5) on the enantioselectivity of the reaction [77]. Performing the reaction at room temperature in aqueous medium at pH 3 and in the presence of lithium chloride, a 2.2 1 mixture of endo/exo adducts was obtained with 75% yield. Only 15% of ee was observed, which compares well with the results quoted for Diels-Alder reactions in cyclodextrins [65d]. Only the endo addition was enantioselective and the R enantiomer was prevalent. This is the first reported aqueous chiral micellar catalysis of a Diels-Alder reaction. 

An enantioselective Michael addition reaction was also accomplished in an inclusion complex with a chiral host compound. Treatment of a 1 1 complex of 10c and 66b with 2-mercaptopyridine (137) in the solid state gave (+)-138 of 80% ee in 51% yield. By a similar method, 3-methyl-3-buten-2-one (139) gave (+)-140 of 49% ee in 76% yield [30]. 

In addition, highly enantioselective nitroaldol reactions were performed by Bandini et al. by using a new class of C2-symmetric oligothiophene ligands, in 2007. Thus, associated to copper, these C2-symmetric bis(amino) ligands allowed the synthesis of a wide range of enantiomerically enriched nitroalcohols... 

Enantioselective Catalysis of the Aldol Addition Reaction. There are also several catalysts that can effect enantioselective aldol addition. The reactions generally involve enolate equivalents, such as silyl enol ethers, that are unreactive toward the carbonyl component alone, but can react when activated by a Lewis acid. The tryptophan-based oxazaborolidinone 15 has proven to be a useful catalyst.148... 

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. 

As in intermolecular reactions, enantioselectivity can be achieved in IMDA additions by use of chiral components. For example, the dioxolane ring in 5 and 6 results in TS structures that lead to enantioselective reactions.130 The chirality in the dioxolane ring is reflected in the respective TSs, both of which have an endo orientation of the carbonyl group. 

Conjugate addition reactions involving organocopper intermediates can be made enantioselective by using chiral ligands.86 Several mixed cuprate reagents containing... 

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... 

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