Enone alcohol

A different type of behavior is shown by the reactant 108. Irradiation of this material in solution gives two products, 109 and 110, in relative yields of 3 1. The first of these is an enone alcohol, analogous to 106, and is the sole product of solid-state reaction. The minor product in solution, 110, is a diketone, of considerably different shape from the reactant. It is believed that in solution the... 

Mild conditions (usually base) give the alcohol, more vigorous conditions (acid or base) give the enone. 

Conjugate addition of vinyllithium or a vinyl Grignard reagent to enones and subsequent oxidation afford the 1.4-diketone 16[25]. 4-Oxopentanals are synthesized from allylic alcohols by [3,3]sigmatropic rearrangement of their vinyl ethers and subsequent oxidation of the terminal double bond. Dihydrojasmone (18) was synthesized from allyl 2-octenyl ether (17) based on Claisen rearrangement and oxidation[25] (page 26). 

Enone Formation from Ketones, and Oxidation of Alcohols... 

Oxiranes have been isomerized by palladium compounds to allylic alcohols and enones (79JA1623), and to 1,3-diketones (80JA2095). 

The enantiosclective synthesis of (-)-bilobalide was achieved based on successful synthesis of the chiral enone A and the highly stereoselective reduction of enone A to the desired a-alcohol B. Further transformation to (-)-bilobalide was accomplished following the route used for racemic bilobalide (Ref. 2). 

Metal-ammonia solutions reduce conjugated enones to saturated ketones and reductively cleave a-acetoxy ketones i.e. ketol acetates) to the unsubstituted ketones. In both cases the actual reduction product is the enolate salt of a saturated ketone this salt resists further reduction. If an alcohol is present in the reaction mixture, the enolate salt protonates and the resulting ketone is reduced further to a saturated alcohol. Linearly or cross-conjugated dienones are reduced to enones in the absence of a proton donor other than ammonia. The Birch reduction of unsaturated ketones to saturated alcohols was first reported by Wilds and Nelson using lithium as the reducing agent. This metal has been used almost exclusively by subsequent workers for the reduction of both unsaturated and saturated ketones. Calcium has been preferred for the reductive cleavage of ketol acetates. 

For the reduction of conjugated enones to saturated alcohols, Procedure 5 (section V) may be modified by adding methanol in place of ammonium chloride a sufficient excess of lithium is present to effect reduction of the intermediate saturated ketone to the alcohol. Procedure 2 (section V) for effecting Birch reductions is also useful for reduction of conjugated enones to saturated alcohols. Thus, 17-ethyl-19-nortestosterone affords crude 17a-ethyl-5a-estrane-3) ,17) -diol of mp 174-181°, reported mp 181-183°, in quantitative yield. 

There are ample precedents for reductions of double bonds in conjugated enones with lithium in deuterioammonia (see section V-C). Examples of the reduction of saturated ketones in deuterated media appear only as side reactions (over reductions) during the above mentioned conversions. For experimental details, therefore, one should consult the literature for the analogous reductions in protic medium (see also chapter 1). The use of deuterioammonia is essential for labeling purposes since by using liquid ammonia and methanol-OD the resulting alcohol contains no deuterium. For the preparation of deuterioammonia see section IX-D. 

The formation of an epoxyketone (1) is generally favoured when the expected product of oxidation of an allylic alcohol is a cisoid enone. This type of reaction is promoted by acid conditions and may be prevented by using the chromium trioxide-pyridine reagent which gives only the unsaturated ketone (2) corresponding to the starting alcohol. ... 

Birch reduction of the norgetrel intermediate 5 oil owed by hydrolysis of the enol ether gives the enone oxidation of the alcohol at 17 leads to dione Fermentation of that intermediate in the presence of the mold PeniciIlium raistricky serves to introduce a hydroxyl group... 

The relationship between 9 and its predecessor 10 is close. Oxidation of the allylic C-3 methylene group in 10 and elimination of the methoxy group could furnish enone 9. Retrosynthetic disassembly of ring E in 10 furnishes tertiary alcohol 11 as a viable precursor. That treatment of 11 with a catalytic amount of acid will induce the formation of a transient oxonium ion at C-12 which is then intercepted by the appropriately placed C-4 tertiary hydroxyl group is a very reasonable proposition. As we will see, the introduction of the requisite C-4 hydroxyl group is straightforward from intermediate 12. 

Through a short sequence of functional group manipulations, compound 6 could be elaborated from allylic alcohol 7, the projected product of a Wharton fragmentation4 of epoxy ketone 8 (vide infra). In turn, compound 8 could be derived from enone 9. In the synthetic direction, a Michael addition5 of hydroperoxide anion to enone 9 would be expected to take place from the less hindered side of the molecule. Epoxy ketone 8 would fhen form upon collapse of the intermediate enolate with concomitant expulsion of hydroxide ion (see arrows, Scheme 2). 

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