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Synthesis 2022; 54(06): 1537-1550
DOI: 10.1055/a-1713-8481
DOI: 10.1055/a-1713-8481
short review
Modern Synthesis and Chemistry of Stabilized Ketene N,O-Acetals
This article is dedicated to the late Sandra ‘Sandy’ Newman of the Van D. and Barbara B. Fishback Honors College at South Dakota State University.
Abstract
Ketene N,O-acetals are robust and versatile synthons. Herein, we outline the synthesis of stable ketene N,O-acetals in the twenty-first century. In addition, we review recent developments in the chemistry of ketene N,O-acetals, as it applies to the vinylogous Mukaiyama aldol reaction, electrolysis, and pericyclic transformations. While dated reports rely on in situ use, modern methods of ketene N,O-acetal synthesis are heavily oriented towards producing products with high ‘bench’ stability; moreover, in the present century, chemists typically enhance the stability of ketene N,O-acetals by positioning an electron-withdrawing group at the β-terminus or at the N-position. As propitious substrates in the vinylogous Mukaiyama aldol reaction, ketene N,O-acetals readily provide polyketide adducts with high regioselectivity. When exposed to electrolysis conditions, the title functional group forms a reactive radical cation and cleanly couples with a variety of activated olefins. Given their electron-rich nature, ketene N,O-acetals act as facile substrates in several rearrangement reactions; further, ketene N,O-acetals reserve the ability to act as either dienophiles or dienes in Diels–Alder reactions. Lastly, ketene N,O-acetals are seemingly more stable than their O,O-counterparts and more reactive than analogous N,N- or S,S-acetals; these factors, in combination, make ketene N,O-acetals advantageous substitutes for other ketene acetal homologues.
1 Introduction
2 Select Methods of Stabilization-Oriented Ketene N,O-Acetal Synthesis
3 Ketene N,O-Acetals in the Vinylogous Mukaiyama Aldol Reaction
4 Ketene N,O-Acetals in Anodic Coupling and Electrochemical Oxidation Reactions
5 Rearrangement and Diels–Alder Reactions of Ketene N,O-Acetals
6 Conclusions, Perspectives, and Directions
Key words
ketene acetals - push-pull alkenes - imide enolates - vinylogous Mukaiyama aldol reaction - Kobayashi reaction - electrolysis - rearrangement - Diels–Alder reactionsPublication History
Received: 10 November 2021
Accepted after revision: 06 December 2021
Accepted Manuscript online:
06 December 2021
Article published online:
14 February 2022
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For general information, see the following, as well as the references cited therein:
For details regarding the mechanism of ketene N,O-acetal hydrolysis:
For fundamental, structural information regarding ‘push-pull’ alkenes, see:
Since 2000, ketene N,O-acetals have been utilized in several synthetic applications. These include: ring-opening reactions, radical cyclizations, coupling with isocyanates, aminomethylations, the synthesis of heterocycles, and nucleophilic arylation. For brevity, we have cited these here, but do not discuss the chemistry in detail. For further information, see:
For an essential discussion of heterocyclic aromaticity, and the inherent stability thereof, see:
For examples of the application of cyclic ketene N,O-acetals to the synthesis of pharmaceutically-important heterocycles, see:
For potential routes of ketene N,O-acetal application in material science, see:
For earlier reports that corroborate the stabilizing effects of the designated N-substituted groups, see:
Support for this method can be found in more dated reports:
For information regarding Evans’ chiral auxiliary in asymmetric reactions, see:
For additional reviews, regarding the VMAR, see (as well as the references cited therein):
For early, related works detailing the use of vinyloxyboranes, see:
For select examples:
For applications of the Kobayashi reaction to the synthesis of natural products, see the following reviews:
For additional information, regarding application of Kobayashi technology to the synthesis of natural products, see:
For natural product synthesis, via electrolysis, see:
For select examples of anodic coupling with enol ethers:
For select examples of anodic coupling with dithioketene acetals: