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Synthesis 2021; 53(21): 3909-3934
DOI: 10.1055/a-1519-1670
DOI: 10.1055/a-1519-1670
review
Synthesis and Applications of Cyclopropanones and Their Equivalents as Three-Carbon Building Blocks in Organic Synthesis
This work was supported by North Carolina State University startup funds. Y.J. is grateful to NC State University for a Burroughs Wellcome Fellowship in Organic Chemistry. R.M.R. is grateful to NC State University for Diversity Graduate Assistance grants, and for a Percy Lavon Julian Award in Organic Chemistry.
Dedicated to the memory of Prof. Harry H. Wasserman
Abstract
Cyclopropanone derivatives constitute highly strained cycloalkanones with promising applications as three-carbon building blocks in organic synthesis. Due to the presence of a ketone in such a small ring system, all C–C bonds and the carbonyl group are considered to be labile in suitable conditions, leading to a wide variety of synthetic disconnections, including nucleophilic addition, ring expansion, ring-opening, and (formal) cycloaddition. Despite their synthetic potential, the widespread adoption of cyclopropanones as substrates has been considerably hampered by the difficulties associated with the preparation and storage of such unstable compounds, prompting the development of cyclopropanone surrogates that can equilibrate to the parent ketone in situ via elimination. This review summarizes the syntheses and applications of cyclopropanone derivatives and their equivalents, and offers a perspective of the state of the field as well as its expected future directions.
1 Introduction
2 Preparation of Cyclopropanones and Their Equivalents
2.1 Carbenoid Chemistry
2.2 Allene Oxide Rearrangement
2.3 Ring Closure by Dehydrohalogenation or Dehalogenation
2.4 Photolytic Processes
2.5 Miscellaneous Formation of Cyclopropanones
2.6 Cyclopropanone Equivalents
3 Synthetic Applications of Cyclopropanones and Their Equivalents
3.1 Nucleophilic Addition to the Carbonyl Group
3.2 Ring Expansion
3.3 Ring-Opening
3.4 Cycloaddition and Formal Cycloaddition
4 Conclusion and Outlook
Key words
cyclopropanone - ring strain - oxyallyl - Favorskii - homoenolate - ring expansion - ring openingPublication History
Received: 08 May 2021
Accepted after revision: 27 May 2021
Accepted Manuscript online:
27 May 2021
Article published online:
08 July 2021
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For recent reviews on the stereoselective synthesis of cyclopropane derivatives, see:
For reviews on cyclopropenone chemistry, see:
For recent reviews on the Favorskii rearrangement, see:
For reviews and discussions on oxyallyl species, see:
For discussions of the allene oxide–cyclopropanone equilibrium in biosynthetic pathways, see:
For related electrochemical cyclopropanone formation and Favorskii rearrangements, see:
For related photolytic rearrangements of cyclobutane-1,2-diones to cyclopropanones via decarbonylation, see:
For an analogous reaction with aldehydes instead of cyclopropanone, see:
For reviews on the Kulinkovich cyclopropanation, see:
For related examples, see:
For a related transformation specific to the addition of alkynyllithium nucleophiles, see:
For related examples of the Wittig olefination of cyclopropanone equivalents, see:
For recent reviews on the metal homoenolate chemistry and other ring-opening reactions of cyclopropanols and cyclopropanone (hemi)ketals, see:
For a related study on the use of organic oxidants in the radical ring-opening of cyclopropanone ketals, see:
For another example of β-radical trapping with alkenes following oxidative ring-opening, see:
For related seminal studies performed on cyclopropanols, see:
For reviews on the Pauson–Khand reaction, see:
For an analogous mechanism employing cyclobutanones instead of cyclopropanone, see:
For related transformations of cyclopropenones, see:
For other selected examples of (4+3) cycloadditions involving oxyallyl intermediates, see: