Cyclopropanone Explained

Cyclopropanone is an organic compound with molecular formula (CH2)2CO consisting of a cyclopropane carbon framework with a ketone functional group. The parent compound is labile, being highly sensitive toward even weak nucleophiles. Surrogates of cyclopropanone include the ketals.

Preparation

Cyclopropanone has been prepared by reaction of ketene with diazomethane[1] [2] in an unreactive solvent such as dichloromethane.[3] These solutions are stable at −78 °C. In the presence of protic reagents such as carboxylic acids, primary and secondary amines, and alcohols, cyclopropanone converts to adducts, which are often isolatable at room temperature:[4] [5]

(CH2)2CO + X-H → (CH2)2C(X)(OH)(X-H = R2N-H, HO-H, RO-H)

Structure and bonding

The C3O atoms are coplanar. As deduced from the microwave spectrum, the H2C-CH2 bond length of 157.5 pm is unusually long. By contrast, the C-C bond lengths in cyclopropane are 151 pm. The C=O bond length of 119 pm is short compared to the 123 pm bond length in acetone.[1]

The value of νC=O in the infrared spectrum is near 1815 cm−1, ca. 70 cm−1 higher than values for a typical ketone.

Derivatives

Cyclopropanones are intermediates in the Favorskii rearrangement with cyclic ketones where carboxylic acid formation is accompanied by ring-contraction.

Cyclopropanones react as 1,3-dipoles in cycloadditions for instance with cyclic dienes such as furan.[1] An oxyallyl intermediate or valence tautomer (formed by cleavage of the C2-C3 bond) is suggested as the active intermediate or even a biradical structure (compare to the related trimethylenemethane).

Other reactions of cyclopropanones take place through this intermediate. For instance enantiopure (+)-trans-2,3-di-tert-butylcyclopropanone racemizes when heated to 80 °C.[6]

An oxyallyl intermediate is also proposed in the photochemical conversion of a 3,5-dihydro-4H-pyrazole-4-one with expulsion of nitrogen to an indane:[7]

In this reaction oxyallyl intermediate A, in chemical equilibrium with cyclopropanone B attacks the phenyl ring through its carbocation forming a transient 1,3-cyclohexadiene C (with UV trace similar to isotoluene) followed by rearomatization. The energy difference between A and B is 5 to 7 kcal/mol (21 to 29 kJ/mol).

Coprine

The cyclopropanone derivative 1-aminocyclopropanol occurs naturally by hydrolyzes of coprine, a toxin in some mushrooms. 1-Aminocyclopropanol is an inhibitor of the enzyme acetaldehyde dehydrogenase.[8]

See also

Notes and References

  1. Book: 10.1002/0470023449.ch23. The Chemistry of Cyclopropanones. PATAI'S Chemistry of Functional Groups: Cyclopropyl Group. 1987. Wasserman. Harry H.. Berdahl. Donald R.. Lu. Ta-Jung. 1455–1532. 9780470023440.
  2. 10.1021/ar50013a004. Cyclopropanones. Accounts of Chemical Research. 2. 25–32. 1969. Turro. Nicholas J..
  3. Encyclopedia: 10.1002/047084289X.rc302. Cyclopropanone. Norbert. De Kimpe. Encyclopedia of Reagents for Organic Synthesis.
  4. J. . Salaün. J.. Marguerite. Cyclopropanone Ethyl Hemiacetal from Ethyl 3-Chloropropanoate. Organic Syntheses. 1985. 63. 147. 10.15227/orgsyn.063.0147.
  5. 10.1021/cr00058a002. Cyclopropanone Hemiacetals. 1983. Salaun. Jacques. Chemical Reviews. 83. 6. 619–632.
  6. 10.1021/ja00728a051. Thermal reactions of a cyclopropanone. Racemization and decarbonylation of trans-2,3-di-tert-butylcyclopropanone. Journal of the American Chemical Society. 92. 25. 7488. 1970. Greene. Frederick D.. Sclove. David B.. Pazos. Jose F.. Camp. Ronald L..
  7. 10.1021/jo062259r. 17362038. First Direct Detection of 2,3-Dimethyl-2,3-diphenylcyclopropanone. The Journal of Organic Chemistry. 72. 8. 2777–2784. 2007. Moiseev. Andrey G.. Abe. Manabu. Danilov. Evgeny O.. Neckers. Douglas C..
  8. Wiseman . Jeffrey S. . Abeles . Robert H. . Mechanism of inhibition of aldehyde dehydrogenase by cyclopropanone hydrate and the mushroom toxin coprine . Biochemistry . May 2002 . 18 . 3 . 427–435 . 10.1021/bi00570a006. 369602 .