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Aldehydes lithium aluminum hydride

For most laboratory scale reductions of aldehydes and ketones catalytic hydro genation has been replaced by methods based on metal hydride reducing agents The two most common reagents are sodium borohydride and lithium aluminum hydride... [Pg.628]

Sodium borohydride and lithium aluminum hydride react with carbonyl compounds in much the same way that Grignard reagents do except that they function as hydride donors rather than as carbanion sources Figure 15 2 outlines the general mechanism for the sodium borohydride reduction of an aldehyde or ketone (R2C=0) Two points are especially important about this process... [Pg.629]

The mechanism of lithium aluminum hydride reduction of aldehydes and ketones IS analogous to that of sodium borohydride except that the reduction and hydrolysis... [Pg.629]

Common catalyst compositions contain oxides or ionic forms of platinum, nickel, copper, cobalt, or palladium which are often present as mixtures of more than one metal. Metal hydrides, such as lithium aluminum hydride [16853-85-3] or sodium borohydride [16940-66-2] can also be used to reduce aldehydes. Depending on additional functionahties that may be present in the aldehyde molecule, specialized reducing reagents such as trimethoxyalurninum hydride or alkylboranes (less reactive and more selective) may be used. Other less industrially significant reduction procedures such as the Clemmensen reduction or the modified Wolff-Kishner reduction exist as well. [Pg.470]

Lithium aluminum hydride (LiAlH4) is the most powerful of the hydride reagents. It reduces acid chlorides, esters, lactones, acids, anhydrides, aldehydes, ketones and epoxides to alcohols amides, nitriles, imines and oximes to amines primary and secondary alkyl halides and toluenesulfonates to... [Pg.61]

A rather special procedure for the preparation of 21-hydroxy-20-ketopreg-nanes starts with the 17a-ethoxyethynyl-17 -hydroxy steroids described earlier. Free radical addition of ethanethiol to the triple bond, followed by acid-catalyzed hydrolysis and dehydration gives the 20-thioenol ether 21-aldehyde. This can be reduced with lithium aluminum hydride to the C-21 alcohol and then hydrolyzed to the C-20 ketone in the presence of mercuric chloride. The overall yield, without isolation of intermediates, is in the order of 50% ... [Pg.212]

An alternate method of producing the 21-hydroxy-20-ketone consists in lithium aluminum hydride reduction of the dimethyl acetal, hydrolysis to the 20-hydroxy-21-aldehyde and rearrangement, preferably via the bisulfite addition product... [Pg.216]

Reduction to alcohols (Section 15.2) Aldehydes are reduced to primary alcohols, and ketones are reduced to secondary alcohols by a variety of reducing agents. Catalytic hydrogenation over a metal catalyst and reduction with sodium borohydride or lithium aluminum hydride are general methods. [Pg.713]

Anet et al. ( 04) obtained in 1947 the alkaloids hygrine (191) and kusk-hygrine (192) in a very good yield by treatment of y-methylaminobutyralde-hyde with acetoacetic or acetonedicarboxylic acids at pH 7. The same reaction was later accomplished by Galinovsky et al. (305-307), who prepared the starting aldehyde by partial reduction of 1-methyl-2-pyrroli-done with lithium aluminum hydride. He used acetonedicarboxylic acid for the synthesis of both alkaloids and showed that a mixture of both alkaloids is formed, the composition of which depends on the ratio of components. [Pg.299]

The Rosenmund reduction is usually applied for the conversion of a carboxylic acid into the corresponding aldehyde via the acyl chloride. Alternatively a carboxylic acid may be reduced with lithium aluminum hydride to the alcohol, which in turn may then be oxidized to the aldehyde. Both routes require the preparation of an intermediate product and each route may have its advantages over the other, depending on substrate structure. [Pg.245]

Lithium aluminum hydride, LiAIH4/ is another reducing agent often used for reduction of aldehydes and ketones. A grayish powder that is soluble in ether and tetrabydrofuran, LiAlH4 is much more reactive than NaBH4 but also more dangerous. It reacts violently with water and decomposes explosively when heated above 120 °C. [Pg.610]

Lithium aluminum hydride, reaction with aldehydes, 610 reaction with carboxylic acids. 611-612... [Pg.1303]

Epoxides from aldehydes, 46, 44 Equatorial alcohols, preparation by use of the lithium aluminum hydride-aluminum chloride reagent, 47, 19... [Pg.129]

From intermediate 28, the construction of aldehyde 8 only requires a few straightforward steps. Thus, alkylation of the newly introduced C-3 secondary hydroxyl with methyl iodide, followed by hydrogenolysis of the C-5 benzyl ether, furnishes primary alcohol ( )-29. With a free primary hydroxyl group, compound ( )-29 provides a convenient opportunity for optical resolution at this stage. Indeed, separation of the equimolar mixture of diastereo-meric urethanes (carbamates) resulting from the action of (S)-(-)-a-methylbenzylisocyanate on ( )-29, followed by lithium aluminum hydride reduction of the separated urethanes, provides both enantiomers of 29 in optically active form. Oxidation of the levorotatory alcohol (-)-29 with PCC furnishes enantiomerically pure aldehyde 8 (88 % yield). [Pg.196]

The homology between 22 and 21 is obviously very close. After lithium aluminum hydride reduction of the ethoxycarbonyl function in 22, oxidation of the resultant primary alcohol with PCC furnishes aldehyde 34. Subjection of 34 to sequential carbonyl addition, oxidation, and deprotection reactions then provides ketone 21 (31% overall yield from (—)-33). By virtue of its symmetry, the dextrorotatory monobenzyl ether, (/ )-(+)-33, can also be converted to compound 21, with the same absolute configuration as that derived from (S)-(-)-33, by using a synthetic route that differs only slightly from the one already described. [Pg.199]

The condensation is usually carried out by adding a solution containing equimolar amounts of the allyl halide and the aldehyde or ketone to a solution of at least two equivalents of chromium-(II) chloride in THF at 0 5°C. Frequently, the less precious component is used in 50-100% excess. Although commercially available anhydrous chromium(II) chloride can be utilized (Method B), its in situ preparation from chromium(III) chloride and lithium aluminum hydride (Method A) is often preferred. The removal of chromium and aluminum hydroxide, which are formed on aqueous workup, can be accomplished by filtration in the presence of a filtration aid. [Pg.435]

The lithium cnolate generated by deprotonation of 2-/m-butyl-6-methyl-l,3-dioxan-4-onc, readily available from polyhydroxybutyric acid (PHB), predominantly affords the diastereo-mers 7 when reacted with aldehydes. The diastereomeric ratios of aldol adducts 7/8, produced by reactions with aliphatic aldehydes, range from 87.5 12.5 to >99 1. Pure diastereoiners7are obtained by recrystallization in 25-74% yield116-118. Only marginal diastereoselectivities with respect to the carbinol center are obtained with aromatic aldehydes111-119. Benzoylation of the dioxanones 7, followed by reduction with lithium aluminum hydride, affords enan-tiomerically and diastereomerically pure triols 9 in >85% yield 11. ... [Pg.512]

The combination of the enantiomerically pure 7V-methylephedrine derived silylketene acetal l-[(l/ ,2S)-2-dimethylamino-1-phenylpropoxy]-l-triniethylsilyloxy-l-propene with the chiral aldehyde (,R)-3-benzyloxy-2-methylpropanal leads, after reduction with lithium aluminum hydride, to the formation of a single 1,3-pentanediol 9 ( matched pair ). [Pg.575]

The crystalline material was shown to be modified sesquiterpinoid (5) containing two aldehyde functions, one of which is a,/3-unsat-urated (la). It analyzed for C13H22O2 and formed the dioxime. It readily took up oxygen on standing and was converted to the diol on treatment with lithium aluminum hydride. The bisdinitrobenzoate of this diol with osmium tetroxide yielded the tetraol, bisdinitrobenzoate, which was not readily acetylated. [Pg.111]

Lithium aluminum hydride Alcohols, aldehydes, ketones, esters, epoxides. [Pg.962]


See other pages where Aldehydes lithium aluminum hydride is mentioned: [Pg.1197]    [Pg.516]    [Pg.1792]    [Pg.1197]    [Pg.516]    [Pg.1792]    [Pg.323]    [Pg.436]    [Pg.79]    [Pg.219]    [Pg.218]    [Pg.387]    [Pg.90]    [Pg.194]    [Pg.196]    [Pg.229]    [Pg.467]    [Pg.664]    [Pg.112]    [Pg.23]    [Pg.396]    [Pg.244]    [Pg.203]    [Pg.413]    [Pg.87]   
See also in sourсe #XX -- [ Pg.17 , Pg.18 , Pg.20 , Pg.98 , Pg.100 , Pg.100 , Pg.102 , Pg.102 , Pg.207 ]




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Lithium aluminum hydride, reaction with aldehydes

Lithium aluminum hydride—cont aldehydes

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