Amines from amide reduction

Other Applications. Hydroxylamine-O-sulfonic acid [2950-43-8] h.2is many applications in the area of organic synthesis. The use of this material for organic transformations has been thoroughly reviewed (125,126). The preparation of the acid involves the reaction of hydroxjlamine [5470-11-1] with oleum in the presence of ammonium sulfate [7783-20-2] (127). The acid has found appHcation in the preparation of hydra2ines from amines, aUphatic amines from activated methylene compounds, aromatic amines from activated aromatic compounds, amides from esters, and oximes. It is also an important reagent in reductive deamination and specialty nitrile production. 

Amide disconnection leaves simple amine (51), available by reductive amination from aldehyde (52). Analysis 2... 

Contrary to an alkoxy benzene scaffold, secondary amides were generated via novel aldehyde linker 43 based upon an indole scaffold (Scheme 15) [52]. The indole resin was prepared from indole-3-carboxy-aldehyde in two steps and reacted with amines under reductive conditions to generate resin-bound secondary amines. Treatment of the resin with... 

Reduction of amides to aldehydes was accomplished mainly by complex hydrides. Not every amide is suitable for reduction to aldehyde. Good yields were obtained only with some tertiary amides and lithium aluminum hydride, lithium triethoxyaluminohydride or sodium bis 2-methoxyethoxy)aluminum hydride. The nature of the substituents on nitrogen plays a key role. Amides derived from aromatic amines such as JV-methylaniline [1103] and especially pyrrole, indole and carbazole were found most suitable for the preparation of aldehydes. By adding 0.25 mol of lithium aluminum hydride in ether to 1 mol of the amide in ethereal solution cooled to —10° to —15°, 37-60% yields of benzaldehyde were obtained from the benzoyl derivatives of the above heterocycles [1104] and 68% yield from N-methylbenzanilide [1103]. Similarly 4,4,4-trifluorobutanol was prepared in 83% yield by reduction of N-(4,4,4-trifluorobutanoyl)carbazole in ether at —10° [1105]. 

The related benzazapinones 105 can be made by formation of C-N bonds in two different ways.16 Amide formation from compounds like 104 is not surprising but reductive amination... 

Aluminum ethoxide, 21, 9 Aluminum isopropoxide, 21, 9 Amalgamated zinc, 20, 57 23, 86 Amide, 20, 37, 62, 66 25, 58, 71 from an acid and urea, 25, 95 preparation by ammonolysis, 20, 62 Amination, by reduction of a ketone in the presence of ammonia, 23, 68 of bromoacetal with use of high-pressure hydrogenation bomb, 24, 3 of a-bromoisocaproic acid, 21, 75 of a-bromo-/3-methylvaleric acid, 21, 62... 

The product is a N,jV-disubstituted amine, which can be formed by reduction of an amide. The amide results from treatment of an acid chloride with the appropriate amine. The acid chloride is the product of the reaction of SOCI2 with a carboxylic acid that is formed by carboxylation of the Grignard reagent synthesized from the starting material. 

This transient intermediate decarboxylates under reaction conditions to afford the bis(enone) 154. Hydrogenation over platinum proceeds to give the saturated ketone (155). Treatment of 155 with benzylamine in the presence of cyanoborohydride leads to the product from reductive amination (156). Acylation with hydrocinnamoyl chloride affords the amide 157. ... 

The amine group in primary amines can be replaced by halogen by warming the benzoyl derivative with phosphorus pentachloride or phosphorus pentabromide. Oftentimes, the separation of the halide from the benzonitrile, which is also formed, is troublesome. The process has been applied mostly to high-moIecuIar-weight amines obtained by the Hofmann degradation of acid amides or by reduction of nitriles." Diamines lead to dihalogen derivatives." If N-benzoyl piperidines are treated, substituted pentamethylene halides are formed. An example is the synthesis of pentamethylene bromide by the action of phosphorus pentabromide on N-benzoyl piperidine (72%). ... 

Both aliphatic and aromatic esters may be converted to amides by electrochemical reduction of the ester in the presence of an amine in a divided cell as in Eq. (23) [95]. This reaction is not formally a reduction, but the reaction does not occur without passage of current. The mechanism is likely formation of an anion radical with abstracts a proton from ammonia to form amide ion. The amide ion subsequently displaces alkoxide in a chain reaction to form carboxamide. 

Acyloxaziridines are easily obtained from compounds unsubstituted at nitrogen by reaction with acid chlorides or isocyanates. Acylation proceeds so smoothly that, in the amination of carbonyl compounds, oxaziridine compounds are obtained in better yields on addition of acid chlorides than in the absence of the acylating agent. With aliphatic aldehydes, amination does not succeed at all except in the presence of benzoyl chloride. Proof of structure comes from reduction by iodide to give the acid amide and carbonyl compound. 

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