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DOI: 10.1055/s-0034-1379166
Enamide Derivatives: Versatile Building Blocks for Highly Functionalized α,β-Substituted Amines
Publication History
Received: 25 July 2014
Accepted after revision: 28 August 2014
Publication Date:
06 November 2014 (online)
Abstract
As demonstrated by earlier successes with enamines, nitrogen-activated C=C double bonds have considerable potential for use in the construction of various nitrogen-containing products. To expand the applications of this class of substrates, we focused on studying the reactivity of enamides and enecarbamates as promising representatives. Starting from the well-known Povarov reaction, we gradually developed other cycloaddition reactions and, more generally, an extended range of methods for α,β-difunctionalization. Our most recent work, which involves radical processes, has contributed to a significant increase in the diversity of scaffolds accessible from these nitrogenous substrates and is potentially applicable to various natural and bioactive synthetic targets.
1 Introduction
2 General Design
3 Asymmetric Brønsted Acid-Catalyzed α,β-Difunctionalization of Enamides
3.1 Intramolecular α,β-Difunctionalization of Enamides Through Cycloaddition Reactions
3.1.1 Povarov Reactions
3.1.2 Diels–Alder Reactions of 1-Azadienes
3.2 Intermolecular α,β-Difunctionalization of Enamides
3.2.1 Mannich Reactions
3.2.2 Addition to Azo Compounds
3.2.3 Halogenation Reactions
4 Radical Tandem Difunctionalization: β-Alkylation Followed by α-Functionalization of Enamides
4.1 Photoredox-Mediated Tandem α,β-Difunctionalization of Enamides
4.1.1 Oxyalkylation
4.1.2 Oxy-, Amino- and Carbotrifluoromethylation
4.2 Single-Electron Transfer-Mediated Tandem α,β-Difunctionalization of Enamides
5 Conclusion
-
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For selected reviews on difunctionalization of alkenes, see:
For monographs on asymmetric organocatalysis, see:
For selected reviews on enamine catalysis, see:
For selected examples, see:
For other selected examples, see:
For vicinal difunctionalization of enamides, see:
For recent reviews on catalysis by chiral phosphoric acids, see:
For the first examples of Povarov reactions using eneamide derivatives, see:
For examples of enantioselective processes combining a chiral phosphoric acid and a Pd catalyst, see:
For examples with enamides and enecarbamates, see:
For examples with enamines, see:
For a concerted mechanism, see:
See also:
For a stepwise mechanism, see:
For examples of interrupted Povarov reactions, see:
For an example of a catalytic enantioselective inverse electron-demand aza-Diels–Alder (IEDADA) reaction using 1-azadienes and chiral Lewis acids, see:
For examples of catalytic enantioselective IEDADA reactions using 1-azadienes and chiral covalent organocatalysts, see:
For examples of bioactive natural 1,3-amines, see:
For examples of bioactive 1,3-amines of non-natural origin, see:
For examples of 1,3-amines as ligands or auxiliaries for asymmetric catalysis, see:
For examples of imine/enamine isomerization, see:
For recent reviews on combining metal and Brønsted acid catalysis, see:
For selected examples of catalysis by chiral Ca(II) salts, see:
For a review, see:
For an example of a monomeric structure of a Ca complex, see:
For reviews, see:
For reviews on organocatalytic asymmetric α-alkylation of aldehydes, see:
For radical additions to enamines, see:
For radical additions to enamides, see:
For recent reviews on photoredox catalysis, see:
For examples of fluorinated amino acids and peptidomimetics, see:
For examples of drugs, see:
For highlights, see:
For selected reviews of the use of CAN as a single-electron oxidant, see:
For intramolecular α-alkylation of aldehydes, see:
For Intramolecular α-allylation of aldehydes, see:
For α-enolation of aldehydes, see: