Amides hydride reduction

Amines of the formula n 2n+ be prepared by the lithium aluminum hydride reduction of the corresponding amide, hydrogenolysis... 

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). 

Alteration of the relative reactivity of the ring-positions of quinoline is expected and observed when cyclic transition states can intervene. Quinoline plus phenylmagnesium bromide (Et20,150°, 3 hr) produces the 2-phenyl derivative (66% yield) phenyllithium gives predominantly the same product along with a little of the 4-phenylation product. Reaction of butyllithium (Et 0, —35°, 15 min) forms 2-butylquinoline directly in 94% yield. 2-Aryl- or 6-methoxy-quinolines give addition at the 2-position with aryllithium re-agents, and reaction there is so favored that appreciable substitution (35%) takes place at the 2-position even in the 4-chloroquinoline 414. Hydride reduction at the 2-position of quinoline predominates. Reaction of amide ion at the 2-position via a cyclic... 

Acylation of the monosubstituted piperazine, 99 (obtainable by the protection-deprotection scheme outlined above), with cinnamoyl chloride gives the corresponding amide (100). Reduction of the carbonyl by means of lithium aluminum hydride affords cinnarizine (101). ... 

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... 

A substituted benzoic acid serves as precursor for the nontricyclic antidepressant bipena-mol (175). Selective. saponification of ester 171 afford.s the half-acid 172. Reaction of the acid chloride derived from this intermediate (173) with ammonia gives the amide 174. Reduction of the last by means of lithium aluminum hydride gives bipenamol (175) [44]. 

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... 

From all the above observations, it was concluded that, for diphosphine chelate complexes, the hydrogenation stage occurs after alkene association thus, the unsaturated pathway depicted in Scheme 1.21 was proposed [31 a, c, 74]. The monohydrido-alkyl complex is formed by addition of dihydrogen to the en-amide complex, followed by transfer of a single hydride. Reductive elimination of the product regenerates the active catalysts and restarts the cycle. The monohydrido-alkyl intermediate was also observed and characterized spectroscopically [31c, 75], but the catalyst-substrate-dihydrido complex was not detected. 

The amides on reduction with lithium aluminium hydride yield amines. 

Amides seem to behave differently, with complex metal hydride reduction giving an amine, effectively converting the carbonyl group to a methylene (see Section 7.11). 

Pridefine (80) is a somewhat structurally related antidepressant. It is a centrally active neurotransmitter blocking agent. It blocks norepinephrine in the hypothalamus but does not affect dopamine or 5-hydroxytryptamine. Its synthesis be-(jins by lithium amide-promoted condensation of diethyl succinate and benzophenone followed by saponification to 78. Heating in the presence of ethylamine gives N-ethylsuccinimide 79. Lithium aluminum hydride reduction completes the synthesis of pridefine (80)... 

Amides, azides and nitriles are reduced to amines by catalytic hydrogenation (H2/Pd—C or H2/Pt—C) as well as metal hydride reduction (LiAlH4). They are less reactive towards the metal hydride reduction, and cannot be reduced by NaBITj. Unlike the LiAlIU reduction of all other carboxylic acid derivatives, which affords 1° alcohols, the LiAlIU reduction of amides, azides and nitriles yields amines. Acid is not used in the work-up step, since amines are basic. Thus, hydrolytic work-up is employed to afford amines. When the nitrile group is reduced, an NH2 and an extra CH2 are introduced into the molecule. 

Excellent procedures are available for the preparation of primary, secondary, and tertiary amines by the reduction of a variety of nitrogen compounds. Primary amines can be obtained by hydrogenation or by lithium aluminum hydride reduction of nitro compounds, azides, oximes, imines, nitriles, or unsubstituted amides [all possible with H2 over a metal catalyst (Pt or Ni) or with LiAlH4] ... 

Secondary and tertiary amines, particularly those with different R groups, are prepared easily by lithium aluminum hydride reduction of substituted amides (Section 18-7C). 

Enantiomerically pure a-amino aldehydes containing nonpolar side chains such as Boc-Ala-H, Boc-Leu-H, and Boc-Phe-H are synthesized by lithium aluminum hydride reduction of the corresponding Weinreb amides, Boc-Ala-N(Me)OMe, Boc-Leu-N(Me)OMe, and Boc-Phe-N(Me)OMe, respectively (Table 4). The lithium aluminum hydride does not affect the Boc group due to the low temperature and short 15-minute reaction time. Successful synthesis of side-chain Bzl-protected Boc-Thr(Bzl)-H gives a 95% yield of crude product, however, reduction of N-protected aspartyl and glutamyl aldehydes from their corresponding A-methoxy-A-methylamides leads to overreduction and unreacted hydroxamateJ1920 ... 

Table 4 Synthesis of a-Amino Aldehydes by Lithium Aluminum Hydride Reduction of Weinreb Amides 20-32 ...

The lithium aluminum hydride reduction of225 afforded two products, namely 227 and 228. Emde reduction, however, gave only 227. By contrast, lithium aluminum hydride gave a single product from 224, but lithium in liquid ammonia produced multiple products. Thus either method may be selective, depending on the nature of X. The Emde method has also been applied to 9-cyanoindolizidines with the formation of medium-ring amides.267... 

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