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Amide reduction with lithium aluminum hydride

Amide reduction with lithium aluminum hydride, 39, 19 Amine oxide formation, 39, 40 Amine oxide pyrolysis, 39, 41, 42 -Aminoacetanilide, 39, 1 Amino adds, synthesis of, 30, 7 2-Amino-4-anilino-6-(chloro-METHYl) -S-TRIAZINE, 38, 1 -Aminobenzaldehyde, 31, 6 hydrazone, 31, 7 oxime, 31, 7 phenylhydrazone, 31, 7 > -Aminobenzoic add, 36, 95 2-Aminobenzophenone, 32, 8 c-Aminocaproic acid, 32, 13 6-Aminocaproic acid hydrochloride,... [Pg.83]

Grignard and alkyl lithium reagents were found to add to the carbonyl group of a tricyclic vinylogous amide. However, the same compound underwent the usual vinylogous reduction with lithium aluminum hydride (712). Grignard additions to di- and trichloroenamines gave a-chloro- and dichloroketones (713). [Pg.427]

Vinylogous amides undergo reduction with lithium aluminum hydride, by Michael addition of hydride and formation of an enolate, which can resist further reduction. Thus -aminoketones are usually produced (309, 563,564). However, the alternative selective reduction of the carbonyl group has also been claimed (555). [Pg.431]

Acylation of norephedrine (56) with the acid chloride from benzoylglycolic acid leads to the amide (57), Reduction with lithium aluminum hydride serves both to reduce the amide to the amine and to remove the protecting group by reduction (58), Cyclization by means of sulfuric acid (probably via the benzylic carbonium ion) affords phenmetrazine (59), In a related process, alkylation of ephedrine itself (60) with ethylene oxide gives the diol, 61, (The secondary nature of the amine in 60 eliminates the complication of dialkylation and thus the need to go through the amide.) Cyclization as above affords phendimetra-zine (62), - Both these agents show activity related to the parent acyclic molecule that is, the agents are CNS stimulants... [Pg.260]

In this series, too, replacement of the N-methyl by a group such as cyclopropylmethyl leads to a compound with reduced abuse potential by virtue of mixed agonist-antagonist action. To accomplish this, reduction of 24 followed by reaction with tertiary butylmagnesium chloride gives the tertiary carbinol 27. The N-methyl group is then removed by the classic von Braun procedure. Thus, reaction with cyanogen bromide leads to the N-cyano derivative (28) hydrolysis affords the secondary amine 29. (One of the more efficient demethylation procedures, such as reaction with ethyl chloroformate would presumably be used today.) Acylation with cyclopropylcarbonyl chloride then leads to the amide 30. Reduction with lithium aluminum hydride (31) followed by demethylation of the phenolic ether affords buprenorphine (32).9... [Pg.321]

The reason why the carbonyl group in -santonin remained intact may be that, after the reduction of the less hindered double bond, the ketone was enolized by lithium amide and was thus protected from further reduction. Indeed, treatment of ethyl l-methyl-2-cyclopentanone-l-carboxylate with lithium diisopropylamide in tetrahydrofuran at — 78° enolized the ketone and prevented its reduction with lithium aluminum hydride and with diisobutyl-alane (DIBAL ). Reduction by these two reagents in tetrahydrofuran at — 78° to —40° or —78° to —20°, respectively, afforded keto alcohols from several keto esters in 46-95% yields. Ketones whose enols are unstable failed to give keto alcohols [1092]. [Pg.162]

Amides containing nitro groups are reduced to diamino compounds with alane. A, A -Dimethyl-p-nitrobenzamide, on reduction with lithium aluminum hydride in the presence of sulfuric acid in tetrahydrofuran, gave 98% yield of dimethyl-p-aminobenzylamine [1117]. [Pg.170]

Reduction of the amide function with lithium aluminum hydride then reduces the amide carbonyl to afford atilide (6-4) [6]. [Pg.47]

In some runs, small amounts of sulfur-containing compounds distilled together with the amide. These impurities did not affect the yield and purity of the N,N-dimethylcyclohexylmethylamine obtained in the subsequent reduction with lithium aluminum hydride. [Pg.21]

Given a particular amide, write equations for its hydrolysis and reduction with lithium aluminum hydride. [Pg.191]

The stereochemistry at positions 3,15, and 20 is preserved in alloyo-himbone (LXIV) and its reduction product, alloyohimbane (3a, 15a,20a-yohimbane, LXV), of which several syntheses have been reported (Volume VII, p. 58) (30). In a recent synthesis, tryptamine (XXVI) was condensed with 4-methoxyhomophthalic anhydride (LXVI) to the amide LXVII. This in the five stages shown was converted to LXVIII and the latter, through another series of reactions, converted to LXX consisting of two epimers which were separable. Tosylation of the hydroxyl and ultimate reduction with lithium aluminum hydride generated alloyohimbane (LXV) (31). [Pg.705]

Amides. An amide on reduction with lithium aluminum hydride is converted in good yield into the corresponding amine. The order of reuctivily Is RC ONR, > nr rfNHB > RCONH.. in a arocodura bv Maffiatl" for reduction of S.S dlmethyl ... [Pg.297]

The reagent reacts with aromatic compounds under Friedel-Crafls conditions to give amides, which on reduction with lithium aluminum hydride afford aldehydes. [Pg.350]

Two syntheses of elaeocarpidine have been reported (16, 18). In a simple three-stage synthesis (18) the amide 44, prepared from trypta-mine and 3-A-succinimidopropionie acid, was converted by reaction with phosphorus oxychloride into the dihydrocarboline 45. Reduction with lithium aluminum hydride in tetrahydrofuran then gave elaeocarpidine (41) and dihydroelaeocarpidine (42). [Pg.344]

The common synthetic route3 to N,N-dimethylhomoveratrylamine involves acyl chloride formation from (3,4-dimethoxyphenyl)acetic acid with thionyl chloride (84%),7 followed by amide formation with dimethylamine (99%),8 and reduction with lithium aluminum hydride (71%).9 The procedure provides N.N-dimethylhomoveratrylamine in 59% overall yield, requires three steps and more expensive substrates and reagents. [Pg.138]

AletalHydrides. Metal hydrides can sometimes be used to prepare amines by reduction of various functional groups, but they are seldom the preferred method. Most metal hydrides do not reduce nitro compounds at all (64), although aUphatic nitro compounds can be reduced to amines with lithium aluminum hydride. When aromatic amines are reduced with this reagent, a2o compounds are produced. Nitriles, on the other hand, can be reduced to amines with lithium aluminum hydride or sodium borohydride under certain conditions. Other functional groups which can be reduced to amines using metal hydrides include amides, oximes, isocyanates, isothiocyanates, and a2ides (64). [Pg.263]


See other pages where Amide reduction with lithium aluminum hydride is mentioned: [Pg.246]    [Pg.246]    [Pg.105]    [Pg.113]    [Pg.827]    [Pg.1162]    [Pg.1295]    [Pg.216]    [Pg.222]    [Pg.236]    [Pg.204]    [Pg.205]    [Pg.124]    [Pg.130]    [Pg.199]    [Pg.362]    [Pg.55]    [Pg.213]    [Pg.199]    [Pg.33]    [Pg.316]    [Pg.365]    [Pg.980]    [Pg.906]    [Pg.567]    [Pg.276]    [Pg.45]    [Pg.234]    [Pg.114]    [Pg.38]   
See also in sourсe #XX -- [ Pg.19 , Pg.39 ]




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Aluminum amides

Aluminum hydrides, 155. amides

Aluminum lithium with

Aluminum reduction

Aluminum reduction with

Amidation reductive

Amides hydride

Amides hydride reduction

Amides lithium aluminum hydride

Amides reduction

Amides reduction with

Hydride, aluminum reduction with

Lithium aluminum amides

Lithium aluminum hydride, reduction

Lithium aluminum hydride, reduction amides

Lithium amide

Lithium amide reduction

Lithium hydride reduction

Lithium reductions

Reduction aluminum hydride

Reduction with hydrides

Reductions with lithium aluminum hydride

With lithium, reduction

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