Michael acceptors extended

Van Leusen and co-workers also demonstrated the utility of dilithio-tosylmethyl isocyanide (dilithio-TosMIC) to extend the scope of the application. Dilithio-TosMIC is readily formed from TosMIC and two equivalents of n-butyllithium (BuLi) in THF at -70"C. Dilithio-TosMIC converts ethyl benzoate to oxazole 14 in 70% yield whereas TosMIC monoanion does not react. In addition, unsaturated, conjugated esters (15) react with dilithio-TosMIC exclusively through the ester carbonyl to provide oxazoles (16). On the other hand, use of the softer TosMIC-monoanion provides pyrroles through reaction of the carbon-carbon double bond in the Michael acceptor. 

Copper-mediated Addition Reactions to Extended Michael Acceptors... 

In 1976, Stetter extended the synthetic utility of the Breslow intermediate (1) as an acyl anion equivalent by showing that aldehydes could be coupled with Michael acceptors to generate 1,4-dicarbonyl compounds [55]. 

Rovis and co-workers further extended the scope of the reaction to the enantio-and diastereoselective cyclisation of a,P-disubstituted Michael acceptors 137. The high diastereoselectivity of the process relies on selective protonation of the resnltant enolate after conjugate addition. It was found that HMDS (formed dnring deprotonation of the triazolium salt pre-catalyst) was detrimental to the... 

Similar models explain the 1,8-, 1,10- and 1,12-addition reactions to the extended Michael acceptors 91, 93 and 95, respectively (Schemes 2.32 and 2.33). Again, these transformations start with the formation of a cuprate Jt-complex at the double bond neighbouring the acceptor group [61a]. Subsequently, an equilibrating mixture of a-copper(III) intermediates is presumably formed and the regioselectivity of the reaction may then be governed by the different relative rates of the reductive elimination step of these intermediates. Consequently, the exclusive formation of allenic prod-... 

Nucleophilic additions of amines to acceptor-substituted dienes were examined as early as 1950. Frankel and coworkers98 found that the reaction of 2,4-pentadienenitrile with various secondary amines proceeded regioselectively to furnish the 1,6-addition products (equation 29). In some cases, these could converted into the 2,4-diamino-substituted pen-tanenitriles by isomerization and 1,4-addition of a second molecule of amine. Analogous results were reported by other groups17,99 100 and extended to hydrazine as nucleophile101 and to vinylcyclobutenones48 and dienoates102-104 as Michael acceptors. 

The neutral 1,4- and 1,2-quinone methides react as Michael acceptors. However, the reactivity of these quinone methides is substantially different from that of simple Michael acceptors. The 1,6-addition of protonated nucleophiles NuH to simple Michael acceptors results in a small decrease in the stabilization of product by the two conjugated 7T-orbitals, compared to the more extended three conjugated 7T-orbitals of reactant. However, the favorable ketonization of the initial enol product (Scheme 1) confers a substantial thermodynamic driving force to nucleophile addition. By comparison, the 1,6-addition of NuH to a 1,4-quinone methide results in a large increase in the -stabilization energy due to the formation of a fully aromatic ring (Scheme 2A). This aromatic stabilization is present to a smaller extent at the reactant quinone methide, where it is represented as the contributing zwitterionic valence bond structure for the 4-0 -substituted benzyl carbocation (Scheme 1). The ketonization of the product phenol (Scheme 2B) is unfavorable by ca. 19 kcal/mol.1,2... 

Phenol complexes of [Os] display pronounced reactivity toward Michael acceptors under very mild conditions. The reactivity is due, in part, to the acidity of the hydroxyl proton, which can be easily removed to generate an extended enolate. Reactions of [Os]-phenol complexes are therefore typically catalyzed using amine bases rather than Lewis acids. The regio-chemistry of addition to C4-substituted phenol complexes is dependent upon the reaction conditions. Reactions that proceed under kinetic control typically lead to addition of the electrophile at C4. In reactions that are under thermodynamic control, the electrophile is added at C2. These C2-selective reactions have, in some cases, allowed the isolation of o-quinone methide complexes. As with other [Os] systems, electrophilic additions to phenol complexes occur anti to the face involved in metal coordination. 

Michael acceptor Dye (extended chromophore) Aminals Ketal/acetal... 

Some recent examples of user-customized features include extended negative ionizable features including sulfonamides, Michael acceptor features for covalent addition, zinc ion binding features, and extended positive ionizable features that can map carbocation intermediates. ... 

A Michael-type addition has been used to insert suitable Michael acceptors (47 R = CN, COMe, C02Me/Et) between the carbonyls of benzils (48), to give a range of 1,4-diketones (49). The reaction is catalysed by cyanide (typically as B114NCN), and the aryl rings can bear substituents such as chloro or methoxy. Reminiscent of the Benzoin condensation, the reaction proceeds through an O-aroylmandelonitrile anion (50). The reaction has also been extended to C—O rather than C—C insertion benzaldehyde inserts into benzil under the same conditions to give an a-aroyloxy-ketone (51). 

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