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Synthesis 2019; 51(18): 3369-3396
DOI: 10.1055/s-0037-1611844
DOI: 10.1055/s-0037-1611844
review
Pyridones – Powerful Precursors for the Synthesis of Alkaloids, Their Derivatives, and Alkaloid-Inspired Compounds
Financial support by Narodowe Centrum Nauki (NCN, National Science Center, Poland) (Grant No. 2016/23/N/ST5/00101)Further Information
Publication History
Received: 04 March 2019
Accepted after revision: 02 May 2019
Publication Date:
18 June 2019 (online)
Abstract
2-Pyridone is characterized by a very wide range of reactivity of a different nature, ranging from electrophilic aromatic substitution, CH–metal-mediated reactions, and NH/OH functionalization of both possible lactam/lactim tautomers, through cycloaddition, to nucleophilic addition and transformation of the tautomeric C=O/C–OH moiety. The high availability of 2-pyridones and the possibility of their far-reaching functionalization additionally increased their values. Therefore, they are very useful building blocks for the synthesis of structurally diverse piperidine and pyridine compounds, including naturally occurring 2-pyridones. This review reports on the use of simple 2-pyridones in the synthesis of alkaloids and alkaloids-inspired compounds based on the piperidine or pyridine framework.
1 Introduction
2 Structure, Availability, and Reactivity of 2-Pyridones
3 Monocyclic Piperidine Alkaloids from 2-Pyridones
4 Polycyclic Alkaloids, Their Derivatives, and Alkaloid-Inspired Compounds from 2-Pyridones
4.1 New Ring Formation Involving C/N Atoms of the 2-Pyridone Ring
4.1.1 Indolizine-Fused 2-Pyridones: Camptothecins and Related Compounds
4.1.2 Other Indolizines from 2-Pyridones
4.1.3 Compounds Bearing the Quinolizine Ring System
4.2 New Ring Formation Involving C/C Atoms of the 2-Pyridone Ring
4.2.1 C-2/C-3 Ring Fusion
4.2.2 C-3/C-4 Ring Fusion
4.2.3 C-4/C-5 Ring Fusion
4.2.4 C-5/C-6 Ring Fusion
4.2.5 C-2/C-4 Ring Bridge
4.2.6 C-2/C-6 Ring Bridge
4.2.7 C-3/C-5 Ring Bridge
4.2.8 C-3/C-6 Ring Bridge
4.2.9 C-4/C-6 Ring Bridge
5 Conclusion
-
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