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This review focuses on alkynyl Prins and alkynyl aza-Prins cyclization processes, which involve intramolecular coupling of an alkyne with either an oxocarbenium or iminium electrophile. The oxocarbenium or iminium species can be generated through condensation- or elimination-type processes, to achieve an overall bimolecular annulation that enables the synthesis of both oxygen- and nitrogen-containing saturated heterocycles with different ring sizes and substitution patterns. Also discussed are cascade processes in which alkynyl Prins heterocyclic adducts react to trigger subsequent pericyclic reactions, including [4+2] cycloadditions and Nazarov electrocyclizations, to rapidly construct complex small molecules. Finally, examples of the use of alkynyl Prins and alkynyl aza-Prins reactions in the synthesis of natural products are described. The review covers the literature through the end of 2019. 1 Introduction 1.1 Alkyne-Carbonyl Coupling Pathways 1.2 Coupling/Cyclization Cascades Using the Alkynyl Prins Reaction 2 Alkynyl Prins Annulation (Oxocarbenium Electrophiles) 2.1 Early Work 2.2 Halide as Terminal Nucleophile 2.3 Oxygen as Terminal Nucleophile 2.4 Arene as Terminal Nucleophile (Intermolecular) 2.5 Arene Terminal Nucleophile (Intramolecular) 2.6 Cyclizations Terminated by Elimination 3 Synthetic Utility of Alkynyl Prins Annulation 3.1 Alkynyl Prins-Mediated Synthesis of Dienes for a [4+2] Cyclo- addition-Oxidation Sequence 3.2 Alkynyl Prins Cyclization Adducts as Nazarov Cyclization Precursors 3.3 Alkynyl Prins Cyclization in Natural Product Synthesis 4 Alkynyl Aza-Prins Annulation 4.1 Iminium Electrophiles 4.2 Activated Iminium Electrophiles 5 Alkynyl Aza-Prins Cyclizations in Natural Product Synthesis 6 Summary and Outlook
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Cyclization Strategies for the Concurrent Installation of Multiple Quaternary Stereogenic Centers
Abstract In this review we highlight the general cyclization strategies currently available to organic chemists for the concurrent and stereoselective installation of multipleQuaternary Stereogenic Centers(QSC) atoms in cyclic or polycyclic architectures. QSCs embedded in rigid cyclic architectures are motifs found in many blockbuster drugs and important bioactive natural product classes, and yet, direct access to these structures stereoselectively from simple precursors remains a significant challenge. Underscoring the difficulty associated with their synthesis, such topologically three‐dimensional molecules are underrepresented in existing small molecule compound libraries, which are instead dominated by linear or flat molecules. This review focuses on methods disclosed in both natural product synthesis and methodology studies since the turn of the 21stcentury. The cases to be examined successfully achieve these challenging transformations: (1)one‐step assembly of the cyclized architecture; and (2)concurrent stereoselective installation of multiple (≥2) new QSCs. These cyclization strategies, which address the aforementioned fundamental challenges in complex molecule synthesis, have been categorized into five broad groups: i) Biomimetic Polyene Cyclization Cascades; ii) Cyclization Cascades of Prochiral Alkenes; iii) Cycloadditions; iv) Dearomatizations; v) Electrocyclizations.
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- Award ID(s):
- 1900050
- PAR ID:
- 10449907
- Publisher / Repository:
- Wiley Blackwell (John Wiley & Sons)
- Date Published:
- Journal Name:
- Israel Journal of Chemistry
- Volume:
- 61
- Issue:
- 7-8
- ISSN:
- 0021-2148
- Page Range / eLocation ID:
- p. 469-485
- Format(s):
- Medium: X
- Sponsoring Org:
- National Science Foundation
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