Lithium selective ketone reduction

The stereoselective total synthesis of both ( )-corynantheidine (61) (170,171) (alio stereoisomer) and ( )-dihydrocorynantheine (172) (normal stereoisomer) has been elaborated by Szdntay and co-workers. The key intermediate leading to both alkaloids was the alio cyanoacetic ester derivative 315, which was obtained from the previously prepared ketone 312 (173) by the Knoevenagel condensation accompanied by complete epimerization at C-20 and by subsequent stereoselective sodium borohydride reduction. ( )-Corynantheidine was prepared by modification of the cyanoacetate side chain esterification furnished diester 316, which underwent selective lithium aluminum hydride reduction. The resulting sodium enolate of the a-formyl ester was finally methylated to racemic corynantheidine (171). 

The main methods of reducing ketones to alcohols are (a) use of complex metal hydrides (b) use of alkali metals in alcohols or liquid ammonia or amines 221 (c) catalytic hydrogenation 14,217 (d) Meerwein-Ponndorf reduction.169,249 The reduction of organic compounds by complex metal hydrides, first reported in 1947,174 is a widely used technique. This chapter reviews first the main metal hydride reagents, their reactivities towards various functional groups and the conditions under which they are used to reduce ketones. The reduction of ketones by hydrides is then discussed under the headings of mechanism and stereochemistry, reduction of unsaturated ketones, and stereochemistry and selectivity of reduction of steroidal ketones. Finally reductions with the mixed hydride reagent of lithium aluminum hydride and aluminum chloride, with diborane and with iridium complexes, are briefly described. 

Hydroxyketones are versatile intermediates in the synthesis of pharmaceutical intermediates and heterocyclic molecules. a-Aryl hydroxyketones have been prepared by reaction of aryl aldehydes with 1,4-dioxane followed by reduction with lithium aluminum hydride (LAH) and by the selective LAH reduction of a-silyloxy a,P-unsaturated esters." WissneC has shown that treatment of acid chlorides with tris(trimethylsilyloxy)ethylene affords alkyl and aryl hydroxymethyl ketones. 1-Hydroxy-3-phenyl-2-propanone (3) has been generated by the osmium-catalyzed oxidation of phenylpropene and by the palladium-catalyzed rearrangement of phenyl epoxy alcohoP both in 62% yield. 

A comparison of four tri-f-alkoxyaluminum hydrides revealed that lithium tris[(3-ethyl-3-pen-tyl)oxy]aluminum hydride, prepared from LAH and 3-ethyl-3-pentanol, was the most selective for reduction of aldehydes over ketones of all types. Even the less reactive benzaldehyde was reduced in THE at -78 C faster than cyclohexanone (97.7 2.3). A good correlation between the steric demands of the reducing agent and the observed chemoselectivity was observed. 

The lithium aluminum hydride reduction of /i-chirar / -alkyl dialkylamino ketones has also been investigated776. Although some of the reactions were effectively unselective, others showed a modest syn selectivity, for example, the reduction of 3-dimethylamino-l-phenylbu-tanone. The sense of the asymmetric induction is consistent with a chelation-controlled mechanism analogous to that of the. svn-selective reductions of /1-hydroxv ketones (see Section 2.3.3.1.1.2.3.). 

Finally, the etiojervane analogue of corticosterone (236) has been synthesized from jervine (231), through the known intermediate (232). The unsaturated a-hydroxy-ester (233) was prepared from (232) by a Darzens reaction, followed by boron trifluororide rearrangement. Selective catalytic hydrogenation and lithium aluminium hydride reduction gave a tetraol, isolated as its acetonide (234), which by oxidation at C-3 gave the ajS-unsaturated ketone (235). The last steps of the sequence, which involved modifications of the side-chain, entailed acid hydrolysis, acetylation of the primary alcohol, and oxidation at C-20 to give (236)." ... 

Several syntheses are available to the 13,14-dihydroprostaglandins, some of which are metabolites of the E and F series. The first of these routes [143, 144] started from the formyl derivative (LVII) of the enol ether of cyclo-pentan-l,3-dione which on reaction with ethyl 6-bromosorbate and tri-phenylphosphine followed by selective catalytic reduction afforded the ester (LVIII). A second formylation followed by elaboration with n-hexanoyl-methylenetriphenylphosphonium chloride 1 to the ketone (LIX) which on reduction of the exocyclic double bond and acid-catalysed solvolysis in benzyl alcohol afforded the benzyl ether (LX) and its isomeric enol ether. Reduction with lithium tri-t-butoxyaluminium hydride to the corresponding 15-hydroxy-compound and palladium-charcoal catalysed hydrogenolysis followed by prolonged catalytic hydrogenation with rhodium-charcoal led to ( )-dihydro-PGEi ethyl ester. 

Selective catalytic hydrogenation of the 6,7-double bond of 17/3-acetoxy-7-methylandrosta-4,6-dien-3-one was achieved with Pd-C-PhCH20H and gave the 7/8-methyl dihydro-compound. Added FeCls has been reported to improve the selectivity of reduction of a,/S-enones in metal-ammonia reactions, thereby improving the yield of the saturated ketones. Similar improvements were observed in the lithium-ethylamine reductions at -78 C when a substantial excess of lithium was used and t-butyl alcohol was the proton source. The influence of solvent and added nitrogenous bases on the stereoselectivity of hydrogenation of A - and A -3-oxo-steroids with Pd catalysts has been studied, and the stereoselectivity of Pd-catalysed hydrogenation of various A -7-oxo-steroids has been reported to be unaffected by substituents at C-3 or C-17. 

Potassium and sodium borohydride show greater selectivity in action than lithium aluminium hydride thus ketones or aldehydes may be reduced to alcohols whilst the cyano, nitro, amido and carbalkoxy groups remain unaffected. Furthermore, the reagent may be used in aqueous or aqueous-alcoholic solution. One simple application of its use will be described, viz., the reduction of m-nitrobenzaldehyde to m-nitrobenzyl alcohol ... 

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