Chiral carbonyl compounds, electrophilic

The introduction of umpoled synthons 177 into aldehydes or prochiral ketones leads to the formation of a new stereogenic center. In contrast to the pendant of a-bromo-a-lithio alkenes, an efficient chiral a-lithiated vinyl ether has not been developed so far. Nevertheless, substantial diastereoselectivity is observed in the addition of lithiated vinyl ethers to several chiral carbonyl compounds, in particular cyclic ketones. In these cases, stereocontrol is exhibited by the chirality of the aldehyde or ketone in the sense of substrate-induced stereoselectivity. This is illustrated by the reaction of 1-methoxy-l-lithio ethene 56 with estrone methyl ether, which is attacked by the nucleophilic carbenoid exclusively from the a-face —the typical stereochemical outcome of the nucleophilic addition to H-ketosteroids . Representative examples of various acyclic and cyclic a-lithiated vinyl ethers, generated by deprotonation, and their reactions with electrophiles are given in Table 6. 

The addition of a hydride donor to a /i-hydroxyketo ne can also be conducted in such a way that the opposite diastereoselectivity is observed. However, the possibility previously discussed for additions to a-chiral carbonyl compounds is not applicable here. One must therefore use a different strategy as is shown in Figure 10.22, in which the OH group at the stereocenter C-/i of the substrate is used to bind the hydride donor before it reacts with the C=0 double bond. Thus, the hydridoborate A reacts intramolecularly. This species transfers a hydride ion to the carbonyl carbon after the latter has been protonated and thereby made more electrophilic. The hydride transfer takes place via a six-membered chair-like transition state,... 

Two highly efficient and very practical alternatives have emerged in recent years (Scheme 1.2). One of these approaches consists of activating the acceptors by reversible conversion into a chiral iminium ion. Thus, the reversible condensation of an a,p-unsaturated carbonyl compound with a chiral secondary amine provides a chiral a,p-unsaturated iminium ion. A face-selective reaction with the nucleophile provides an enamine, which can be either reacted with an electrophile and then hydrolysed, or just hydrolysed to a p-chiral carbonyl compound. The second approach is the enamine pathway. If the nucleophile is... 

Allyltitanium complexes derived from a chiral acetal have been reacted with carbonyl compounds and imines [63], While the chiral induction proved to be low with carbonyl compounds, high induction was observed with imines. This complex represents the first chiral homoenolate equivalent that reacts efficiently with imines. Finally, the reactions with electrophiles other than carbonyl compounds and imines, namely a proton source, NCS, and I2, furnished the corresponding alkene, chloro, and iodo derivatives in good yields [64]. 

Chiral phosphoric acids mediate the enantioselective formation of C-C, C-H, C-0, C-N, and C-P bonds. A variety of 1,2-additions and cycloadditions to imines have been reported. Furthermore, the concept of the electrophilic activation of imines by means of phosphates has been extended to other compounds, though only a few examples are known. The scope of phosphoric acid catalysis is broad, but limited to reactive substrates. In contrast, chiral A-triflyl phosphoramides are more acidic and were designed to activate less reactive substrates. Asymmetric formations of C-C, C-H, C-0, as well as C-N bonds have been established. a,P-Unsaturated carbonyl compounds undergo 1,4-additions or cycloadditions in the presence of A-triflyl phosphoramides. Moreover, isolated examples of other substrates can be electrophil-ically activated for a nucleophilic attack. Chiral dicarboxylic acids have also found utility as specific acid catalysts of selected asymmetric transformations. 

If the mesomeric stabilization is provided by a double bond, the lithiated species is a homoenolate synthon, as shown in Scheme 44a. Reaction with an electrophile typically occurs at the y-position, yielding an enamine, which can then be hydrolyzed to a carbonyl compound. An important application of this approach is to incorporate a chiral auxiliary into the nitrogen substituents so as to effect an asymmetric synthesis. 2-AzaaUyl anions (Scheme 44b), which are generated by tin-lithium exchange, can be useful reagents for inter- and intramolecular cycloaddition reactions. ... 

The lithium derivatives described above react with electrophiles such as alkyl halides, carbonyl compounds, and thiocarbonyl compounds, resulting in the corresponding 3-substituted derivatives (190). Hydrolysis of these products by dilute acid as described in Section B,1 gives the new nonproteinogenic amino acid ester (191) along with the original amino acid ester used as the chiral auxiliary. The chemical yields are above 80% (83MI1). 

The asymmetric a-alkylation of carbonyl compounds is a fundamental reaction. Under PTC conditions, acidic substrates such as phenylketone derivatives can be used to create chiral stereogenic centers. Andrus demonstrated asymmetric glycolate alkylation with up to 90% ee using various electrophiles and its application to the synthesis of (-)-ragaglitazar in six steps (Scheme 3.16) [37-39]. 

The direct activation and transformation of a C-H bond adjacent to a carbonyl group into a C-Het bond can take place via a variety of mechanisms, depending on the organocatalyst applied. When secondary amines are used as the catalyst, the first step is the formation of an enamine intermediate, as presented in the mechanism as outlined in Scheme 2.25. The enamine is formed by reaction of the carbonyl compound with the amine, leading to an iminium intermediate, which is then converted to the enamine intermediate by cleavage of the C-H bond. This enamine has a nucleophilic carbon atom which reacts with the electrophilic heteroatom, leading to formation of the new C-Het bond. The optically active product and the chiral amine are released after hydrolysis. 

A different mechanism operates in the direct a-heteroatom functionalization of carbonyl compounds when chiral bases such as cinchona alkaloids are used as the catalysts. The mechanism is outlined in Scheme 2.26 for quinine as the chiral catalyst quinine can deprotonate the substrate when the substituents have strong electron-withdrawing groups. This reaction generates a nucleophile in a chiral pocket (see Fig. 2.6), and the electrophile can thus approach only one of the enantiotopic faces. 

Carbonyl compounds have also been used as electrophiles with the intermediate 719 to afford a-allenic alcohols758,783 788 1016 1030,1033-1051 and, after hydrolysis, the corresponding hydroxy enones1034 1037 1051. The chiral acrylate equivalent endo-2-acryloylisoborneol (726), used in metal-free Diels-Alder reactions, has been prepared by reaction of (-El-camphor with compound 7191039 (Scheme 190). 

The research on asymmetric organozinc additions to carbonyl compounds started in 1984 when Oguni and Omi obtained 49% e.e. in the reaction of diethylzinc with benzaldehyde catalyzed by (X)-leucinol. Since then, a huge number of chiral (see Chiral) catalysts, mostly derived from amino alcohols, have been developed and the subject has been extensively reviewed. 63.264 jjjg highly enantioselective (see Electrophile) ligand (—)-3-exo-dimethylaminoisobomeol [(-)-DAIB] developed by Noyori and coworkers in 1986 is still used even if its application is mostly limited to aromatic and heteroaromatic aldehydes (equation 62). As shown by previous studies, chiral (see Chiral) ligands have a dual... 

Azo-ene reactions. The ene reaction provides a powerful method for C-C bond formation with concomitant activation of an allylic C-H bond. A variety of functionalized carbon skeletons can be constructed due to the range of enophiles which can be used. For example, carbonyl compounds give homoallylic alcohols and imino derivatives of aldehydes afford homoallylic amines. The azo-ene reaction offers a method for effecting allylic amination by treatment of an alkene with an azo-diester to afford a diacyl hydrazine which upon N-N cleavage furnishes a carbamate. Subsequent hydrolysis of the carbamate provides an allylic amine. Use of chiral diazenedicarboxylates provides a method for effecting stereoselective electrophilic amination. 

The Simmons-Smith reaction is an efficient and powerful method for synthesizing cyclopropanes from alkenes [43]. Allylic alcohols are reactive and widely used as substrates, whereas a,j8-unsaturated carbonyl compounds are unreactive. In 1988, Ambler and Davies [44] reported the electrophilic addition of methylene to a,/3-unsaturated acyl ligands attached to the chiral-at-metal iron complex. The reaction of the racemic iron complex 60 with diethylzinc and diiodomethane in the presence of ZnCl2 afforded the c/s-cyclopropane derivatives 61a and 61b in 93 % yield in 24 1 ratio (Sch. 24). 

Most organic free radicals are nucleophilic and will react with electrophilic centers. Lewis acids have been used to activate aj3-unsaturated carbonyl compounds towards addition of free radicals and also to stabilize a-keto radicals [67]. The first report of the use of a chiral Lewis acid to effect an asymmetric free-radical reaction was that of Urabe, Yamashita, Suzuki, Kobayashi, and Sato in 1995 [68]. They found that if the BINOL aluminum catalyst 313 is stoichiometrically complexed with lactone 323 and then treated with butyl iodide and tributylstannane in the presence of triethylborane the alkylated lactone 324 can be isolated in 47 % yield with 23 % ee (Sch. 40). 

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