Alcohols ester reduction

PREPARATION OF ALCOHOLS BY REDUCTION OF CARBOXYLIC ACIDS AND ESTERS... 

Decamethylene glycol has been prepared by the reduction of dimethyl sebacate and diethyl sebacate with sodium and ethyl alcohol by the reduction of sebacamide with sodium and amyl alcohol and by the reduction of dimethyl sebacate with sodium and liquid ammonia in absolute alcohol. The reduction of esters with sodium and alcohol has also been applied to the preparation of many other glycols. ... 

The reaction between perfluoraarylmagnesium halides and esters of dicar-boxyltc acids gives, besides the expected keto esters, secondary alcohols as reduction products [29, 30, 31] (equation 10) Such a reduction is enhanced by higher temperature The hydrogen necessary for reduction comes from the solvent, diethyl ether, which is dehydrogenated to ethyl vinyl ether, which has been identified as a by-product in a similar reaction of perfluoroalkyllithium compound [52]... 

An interesting appetite suppressant very distantly related to hexahydroamphetamines is somanta-dine (24). The reported synthesis starts with conversion of 1-adamantanecarboxylic acid (20) via the usual steps to the ester, reduction to the alcohol, transformation to the bromide (21), conversion of the latter to a Grignard reagent with magnesium metal, and transformation to tertiary alcohol 22 by reaction with acetone. Displacement to the fomiamide (23) and hydrolysis to the tertiary amine (24) completes the preparation of somantadine [6]. 

The strategy for the construction of 13 from aldehyde 16 with two units of phosphonate 15 is summarized in Scheme 12. As expected, aldehyde 16 condenses smoothly with the anion derived from 15 to give, as the major product, the corresponding E,E,E-tri-ene ester. Reduction of the latter substance to the corresponding primary alcohol with Dibal-H, followed by oxidation with MnC>2, then furnishes aldehyde 60 in 86 % overall yield. Reiteration of this tactic and a simple deprotection step completes the synthesis of the desired intermediate 13 in good overall yield and with excellent stereoselectivity. 

The procedure is outlined in Scheme 8.33, starting from the generic allylic alcohol 125. SAE on 125 would provide epoxide 126, which could easily be transformed into the unsaturated epoxy ester 127 by oxidation/Horner-Emmonds olefmation (two-carbon extension). This operation makes the oxirane carbon adjacent to the double bond more susceptible to nucleophilic attack by a hydride, so reductive opening (DIBAL) of 127 provides, with concomitant ester reduction, diol 128. Pro-... 

A representative set of a- and -keto esters was also tested as substrates (total 11) for each purified fusion protein (Figure 8.13b,c) [9bj. The stereoselectivities of -keto ester reductions depended both on the identity of the enzyme and the substrate stmcture, and some reductases yielded both l- and o-alcohols with high stereoselectivities. While a-keto esters were generally reduced with lower enantioselec-tivities, it was possible to identify pairs of yeast reductases that delivered both alcohol antipodes in optically pure form. These results demonstrate the power of genomic fusion protein libraries to identify appropriate biocatalysts rapidly and expedite process development. 

Aldehydes and ketones can be converted to ethers by treatment with an alcohol and triethylsilane in the presence of a strong acid or by hydrogenation in alcoholic acid in the presence of platinum oxide. The process can formally be regarded as addition of ROH to give a hemiacetal RR C(OH)OR", followed by reduction of the OH. In this respect, it is similar to 16-14. In a similar reaction, ketones can be converted to carboxylic esters (reductive acylation of ketones) by treatment with an acyl chloride and triphenyltin hydride. " ... 

There are also examples in which phosphate esters of saturated alcohols are reductively deoxygenated.229 Mechanistic studies of the cleavage of aryl dialkyl phosphates have indicated that the crucial C-O bond cleavage occurs after transfer of two electrons.230... 

Carbon-carbon double bonds alkene to alkane reductions, trisubstituted alkenes, 40 ketone-alcohol reduction, 77, 86-87 a,p-unsaturated ester reduction, 93-96 Carbonyl compounds ... 

Tricarbonyl( 1 -ewrfo-allyltetralin)chromium, stereoselective alcohol to hydrocarbon reduction, 132 1,2,3-Trideoxy-D-r/fco-hex-1 -enopyranose diacetate, allyl ester reduction,... 

Hydrolysis of 20 with the aid of butanol followed by syn-selective reduction of jS-keto ester 21 and protection as the isopropylidene acetal was accomplished in 87% yield. L1A1H4 reduction and TBS protection of the primary alcohol gave 22 in very good yields. In this strategy, the furan residue serves as an aldehyde synthon and ozonolysis followed by esterification gave the corresponding methyl ester. Reduction and consecutive oxidation established aldehyde 23 in 71% yield. 

Bouvealt-Blanc method org chem) A laboratory method for preparing alcohols by reduction of esters utilizing sodium dissolved in alcohol. bti,vo blan, meth-3d j bp See boiling point. 

Chromium(II) sulfate is a versatile reagent for the mild reduction of a variety of bonds. Thus aqueous dimethylformamide solutions of this reagent at room temperature couple benzylic halides, reduce aliphatic monohalides to alkanes, convert vicinal dihalides to olefins, convert geminal halides to carben-oids, reduce acetylenes to /raw5-olefins, and reduce a,j3-unsatu-rated esters, acids, and nitriles to the corresponding saturated derivatives. These conditions also reduce aldehydes to alcohols. The reduction of diethyl fumarate described in this preparation illustrates the mildness of the reaction conditions for the reduction of acetylenes and o ,j8-unsaturated esters, acids, and nitriles. 

Koeduka T, Fridman E, Gang DR et al (2006) Eugenol and isoeugenol, characteristic aromatic constituents of spices are biosynthesized via reduction of a coniferyl alcohol ester. Proc Natl Acad Sci USA 103 10128-10133... 

In keto esters reduction can affect the keto group and convert it to an alcoholic group or to a methylene group, or else it can hydrogenolyze the ester group, either to an acid or to an alcohol. The latter reduction may be accompanied by the reduction of the keto group at the same time. 

Esters are completely reduced to alcohols whde unsaturated esters are converted to unsaturated alcohols. Other reduction reactions include conversion of phenyl isocyanate to N-methylanihne ... 

As described above and shown in Table XIV, the identity of the solvent may have significant effects on the rate of CO reduction. Alcohols, esters, and carboxylic acids appear to provide the highest rates, whereas THF and sulfolane are somewhat less effective. Heptane solvent has been reported to afford poor rates of CO reduction by this system (163). Differences in rates among these solvents appear small enough to be attributable to an effect such as the enhanced stabilization of a polar transition state by the more polar solvents. The presence of certain additives, such as boric acid and aluminum alkoxides, has also been found to increase the rate of CO reduction, perhaps for similar reasons (168). 

The compound has also been synthesized from 3-methylindoleacetic acid via the ethyl ester, reduction with sodium and alcohol to the ethanol, to the ethyl bromide with PBr3 in Et20, to the product (2-Me-DMT) with dimethylamine. The reported mp of the free base is 97-98 °C. 

Na-Protected a-amino aldehydes 4 are mainly obtained from their corresponding a-amino acid derivatives. Generally the synthetic route proceeds via acid halides, esters, or active amides of a-amino acids that are then reduced. The reduction of N -protected acid halides and esters is often accompanied by some overreduction to the respective alcohols. However, reduction of active amides is apparently free from overreduction. The different procedures described in this review are listed in Table 3. 

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