Wharton reaction explained

The Wharton olefin synthesis or the Wharton reaction is a chemical reaction that involves the reduction of α,β-epoxy ketones using hydrazine to give allylic alcohols.[1] [2] [3] This reaction, introduced in 1961 by P. S. Wharton, is an extension of the Wolff–Kishner reduction. The general features of this synthesis are: 1) the epoxidation of α,β-unsaturated ketones is achieved usually in basic conditions using hydrogen peroxide solution in high yield; 2) the epoxy ketone is treated with 2–3 equivalents of a hydrazine hydrate in presence of substoichiometric amounts of acetic acid. This reaction occurs rapidly at room temperature with the evolution of nitrogen and the formation of an allylic alcohol.[1] It can be used to synthesize compounds. Wharton's initial procedure has been improved.[4]

Mechanism and scope

The mechanism of the Wharton reaction begins with reaction of the ketone (1) with hydrazine to form a hydrazone (2). Rearrangement of the hydrazone gives intermediate 3, which can decompose giving off nitrogen gas forming the desired product 4. The final decomposition can proceed by an ionic or a radical pathway, depending on reaction temperature, solvent used, and structure of intermediate 3.[5]

The Wharton olefin synthesis allows the transformation of an α,β unsaturated ketone into an allylic alcohol. The epoxide starting material can be generated by a number of methods, with the most common being reaction of the corresponding alkene with hydrogen peroxide or m-chloroperoxybenzoic acid. The Wharton reaction also commonly suffers from reduction of the allylic alcohol product down to the aliphatic alcohol. This is thought to be due to the oxidation of hydrazine to diimide under the conditions employed in the reaction.[6] The classical Wharton olefin synthesis has two limitations:

Applications

The methodology has been implemented in synthesis of complex molecules:

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References

  1. Wharton, P. S.. Bohlen, D. H.. 1961. Communications- Hydrazine Reduction of α, β-Epoxy Ketones to Allylic Alcohols. J. Org. Chem.. 26. 9. 3615. 10.1021/jo01067a117.
  2. Wharton, P. S.. 1961. Communications- Stereospecific Synthesis of 6-Methyl-trans-5-cyclodecenone. J. Org. Chem.. 26. 11. 4781–4782. 10.1021/jo01069a609.
  3. Chamberlin, A. R.. Reduction of Ketones to Alkenes. Sall, D. J.. Compr. Org. Synth.. 1991. 978-0-08-052349-1. 8. 927–929. 10.1016/B978-0-08-052349-1.00251-1.
  4. Dupuy, C. . Luche, J. L. . Tetrahedron. 1989. 45. 3437. 10.1016/S0040-4020(01)81022-X. New developments of the Wharton transposition. 11.
  5. Stork, G. A. . Williard, P. G. . amp . J. Am. Chem. Soc.. 1977. 99. 7067. 10.1021/ja00463a053. Five- and six-membered-ring formation from olefinic α,β-epoxy ketones and hydrazine. 21.
  6. Book: Hutchins, R. O.. Comp. Org. Synth.. Pergamon. 1991. Oxford. 341–342.
  7. Yu, W., Jin, Z. . Journal of the American Chemical Society . 2002 . 124 . 6576–6583 . 10.1021/ja012119t . 12047177 . Total synthesis of the anticancer natural product OSW-1 . 23 .
  8. Barrero, A.F., Cortes, M., Manzaneda, E. A., Cabrera, E., Chahboun, R., Lara, M., Rivas A. . J. Nat. Prod. . 1999 . 62 . 1488–1491 . 10.1021/np990140q . 10579858 . Synthesis of 11,12-epoxydrim-8,12-en-11-ol, 11,12-diacetoxydrimane, and warburganal from (−)-sclareol . 11 . 10.1.1.379.6604 .

See also