Enols hydrogenolysis

Addition of a hydroxy group to alkynes to form enol ethers is possible with Pd(II). Enol ether formation and its hydrolysis mean the hydration of alkynes to ketones. The 5-hydroxyalkyne 249 was converted into the cyclic enol ether 250[124], Stereoselective enol ether formation was applied to the synthesis of prostacyclin[131]. Treatment of the 4-alkynol 251 with a stoichiometric amount of PdCl2, followed by hydrogenolysis with formic acid, gives the cyclic enol ether 253. Alkoxypalladation to give 252 is trans addition, because the Z E ratio of the alkene 253 was 33 1. 

The basic solution, which now contains the enolate ion, gives much different results than those obtained in neutral media. More of the hydrogenolysis product (6) is obtained in polar 50% aqueous ethanol than is obtained in the... 

In ketones existing largely as the enol, palladium may prove effective in minimizing hydrogenolysis, Hydrogen was added slereoselectively to the least hindered side of L-ascorbic add (3) to give L-gulono-1,4-lactone (4)... 

Sometimes the structure is such that the reaction is forced into a single path regardless of catalyst. Hydrogenation of the (Z)-enol phosphate 30 over PtOj, 5% Pd-on-C, or 5% Rh-on-C in EtOAc at 3 atm gave a 95% yield of 31, obtained by hydrogenolysis followed by hydrogenation (46a). 

A method for conversion of one of two keto functions to the methylene involves hydrogenolysis of an enol phosphate. 

The 3-deoxyhexoses were obtained crystalline after separation on a column of cellulose, a rather tedious operation recently separation of these sugars by fractional crystallization has been reported (41). From the major unsaturated ester 27, 3-deoxy-D-ribo- and -arabino-hexose were shown to have been produced respectively in the ratio 66 34, and from ester 28 in the ratio 24 76. Saturation of the enol grouping of the esters 27 and 28 gives, therefore, the 1,2-cis products preferentially. However, some hydrogenolysis of the anomeric acetate group accompanies simple saturation of the double bond and poses another separation problem. 

Asymmetric hydrogenolysis of epoxides has received relatively little attention despite the utility such processes might hold for the preparation of chiral secondary alcohol products. Chan et al. showed that epoxysuccinate disodium salt was reduced by use of a rhodium norbornadiene catalyst in methanol/water at room temperature to give the corresponding secondary alcohol in 62% ee (Scheme 7.31) [58]. Reduction with D2 afforded a labeled product consistent with direct epoxide C-O bond cleavage and no isomerization to the ketone or enol before reduction. 

Ester enolates which contain the chiral information in the acid moiety have been widely used in alkylations (see Section D.1.1.1,3.) as well as in additions to carbon-nitrogen double bonds (sec Section D.1.4.2.). Below are examples of the reaction of this type of enolate with aldehydes720. The (Z)-enolate generated from benzyl cinnamate (benzyl 3-phenylpropcnoate) and lithium (dimethylphenylsilyl)cuprate affords the /h/-carboxylic acid on addition to acetaldehyde and subsequent hydrogenolysis, The diastereoselectivity is 90 10. 

On the other hand, syn-carboxylic acids are obtained from a deprotonation of the /5-silyl ester, giving the (E)-enolate, followed by reaction with different aldehydes and subsequent hydrogenolysis. No diastereomers of the aldol product are detected720. 

If hydrogen gas is added to the reaction mixture of J, and 11 the hydrogenolysis reaction of thorium-to-carbon sigma bonds (J-1 22) allows interception of species 13 and thus, catalytic hydrogenation of the inserted carbon monoxide functionality. At 35 C under 0.75 atm initial H2 pressure with [JJ =9.0 x 10" M and [ 1JJ = 6.5 x 10" M, hydrogenation and isomerization are competitive and both the enolate and the alkoxide reduction product 14 are produced (eq.(13)). Under these conditions, turnover fre-... 

The route used to prepare the unsaturated 2 methyl androgen stenbolone provides yet a further illustration of the propensity for the formation of enolates at the 2 position. Thus reaction of dihydrotestosterone acetate (41-1) with formaldehyde and dimethylamine gives the Mannich product (41-2). Hydrogenolysis of that product gives the 2 methyl derivative (41-3) the relatively elevated temperature used for this last reaction suggests that the reaction may proceed via the methylene product... 

Dimethoxyfuran is readily available from the enolic dimethyl 3,4-dihydroxyfuran-2,5-dicarboxylate. This intermediate, like a phenol, can be readily O-methylated or O-benzy-lated. Hydrolysis and decarboxylation then furnishes the 3,4-dialkoxy compounds (78HCA430). The dimethoxy compound readily enters into Diels-Alder reactions, the Man-nich reaction, and may be lithiated. On mild acid hydrolysis it supplies, in poor yield, 4-methoxyfuran-3(2/f)-one and not tetrahydrofuran-3,4-dione, which is not produced by attempted hydrogenolysis of 3,4-dibenzyloxyfuran either. The dione, however, is known, and surprisingly exists in the diketo form (60JA3219). 

Deoxygenation ofketones. Enol triflates, readily available by reaction of ketones and triflic anhydride catalyzed by this sterically hindered base, undergo rapid hydrogenolysis to the saturated hydrocarbon. Overall yields are 65-90%. ... 

Using enol ethers of acetophenone 207 or similar compounds in a reaction with 206 and 2 one primarily obtains 2-phenyl-substituted N-heterocydes 209, which can undergo hydrogenolysis under the reaction conditions to afford the corresponding open-chain compounds 210 as mixtures of several diastereomers (Scheme 5.41). 

Ketones and aldehydes are converted to alkenes by the hydrogenolysis of their enol triflates with formate. The steroidal enone 524 is converted to the dienol triflate 525 and then to the 1,3-diene 526 by the hydrogenolysis with tributylammonium formate... 

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