Ketones, amino reduction

The p-substituted amino ketones can be reduced readily to the more stable P-dialkylamino alcohols, many of which are useful local anaesthetics. Thus the local anaesthetic Tutocaine is made from the Mannich base derived from formaldehyde, methyl ethyl ketone and dimethylamine, followed by reduction and conversion into the p-aminobenzoate ... 

A partial explanation of the above findings must lie in the known ease of addition of nucleophilic reagents to the conjugated double bond of pregn-16-en-20-ones. The amide ion that is a by-product of the reduction probably adds to a portion of the unreduced pregn-16-en-20-one giving the lithium enolate of amino ketone (74). This enolate may well be relatively stable at — 33° and would be protonated to the free 16-amino-20-one during work-up... 

The use of primary amines instead of ammonia affords l,2-dialkyl-/l -pyrrolines or l,2-dialkyl-/l -piperideines. Amino ketones with a primary amino group are intermediates in the reduction of y-nitropropylalkyl ketones (14,15) or S-nitrobutylalkyl ketones (16-18) by catalytic hydrogenation over Raney nickel or with zinc and hydrochloric acid (Scheme 1). 

An interesting addition of ethyl acrylate has been reported in the case of l-methyl-2-ethylidenepyrrolidine. An unsaturated amino ketone 144 is formed, which rearranges to 1,7-dimethyloctahydroindole (145) on reduction with formic acid, as established by dehydrogenation to 1,7-dimethyl-indole (Scheme 12) 217). 

The intermediate formation of iminium salts is postulated in the reduction of (x-amino ketones by the Clemmensen method, occurring with concomitant ring enlargement or contraction (244-246). Reduction of l,2,2-trimethyl-3-piperidone (154) in this manner gave l-methyl-2-iso-propylpyrrolidine (155). 

The Knorr pyrrole synthesis involves the reaction between an a-amino ketone 1 and a second carbonyl compound 2, having a reactive a-methylene group, to give a pyrrole 3. The amine 1 is often generated in situ by reduction of an oximino group. 

A compound closely related to classical adrenergic agonists in which the para hydroxy function is however replaced by an amino group has been investigated for its activity as a growth promoter in domestic animals. Acylation of the aniline derivative 26 with chloracetyl chloride will afford acetophenone 27 the amino-ketone 28 is obtained on reaction with isopropylamine. Removal of the protecting group (29) followed by reduction of the ketone affords cimaterol (30) 5J. 

An unusual solvent system was chosen for the intramolecular reductive alkylation of the masked amino ketone (15). The purpose of the strongly acid system was to prevent cyclization of the deblocked amino ketone to 16, further hydrogenation of which gives the unwanted isomer 17 by attack at the convex face. The desired opposite isomer can be obtained by reduction of 16 with UAIH4 (52). 

N,N-Dibenzyl (z -amino a-chloroketimines 202 can be prepared from the corresponding ketones, which in turn are available by the addition of chloromethyllithium to esters of natural cz-amino acids. Reduction of 202 with sodium cyanoborohydride directly afforded a-aminoalkyl-substituted aziridines 203 with high syn diastereoselectivity, which was only moderately affected by the size of the substituent [96] (Scheme 30). A complemen-... 

Amino ketone (37) was needed for a study of the influence of nitrogen atoms on the Clemmensen reduction of ketones. How might it be synthesised ... 

R,2S)-2-[(Ethoxycarbonyl)amino]-l-phenyl-l-propanol [Bronsted Acid Promoted Reduction of an a-Amino Ketone to an Erythro a-Hydroxy... 

R, 25) -2- [(ethoxycarbonyl) amino] -1 -phenyl-1 -propanol [Brdnsted acid promoted reduction of c/-amino ketone to erythro a-hydroxy amine], 124-125... 

The electrochemical reduction of various bicyclic a-amino ketones such as quinolizidinone (n = 2) (Scheme 159) can involve a cleavage of the carbon-nitrogen bond giving a ring enlargement [275, 276]. 

The reaction involves formation of an imine through reaction of ammonia with the ketone, followed by reduction of this imine (see Section 7.7.1). As we noted earlier (see Section 15.1.1), nicotinamide coenzymes may also participate in imine reductions as well as aldehyde/ketone reductions, further emphasizing the imine-carbonyl analogy (see Section 7.7.1). The reverse reaction, removal of ammonia from glutamate, is also of importance in amino acid catabolism. 

The reduction of a dinitro ketone to an azo ketone is best achieved with glucose. 2,2 -Dinitrobenzophenone treated with glucose in methanolic sodium hydroxide at 60° afforded 82% of dibenzo[c,f [i 2]diazepin-l 1-one whereas lithium aluminum hydride yielded 24% of bis(o-nitrophenyl)methanol [575], Conversion of aromatic nitro ketones with a nitro group in the ring into amino ketones has been achieved by means of stannous chloride, which reduced 4-chloro-3-nitroacetophenone to 3-amino-4-chloroacetophenone in 91% yield [178]. A more dependable reagent for this purpose proved to be iron which, in acidic medium, reduced m-nitroacetophenone to m-aminoacetophenone in 80% yield and o-nitrobenzophenone to o-aminobenzophenone in 89% yield (stannous chloride was unsuccessful in the latter case) [903]. Iron has also been used for the reduction of o-nitrochalcone, 3-(o-nitrophenyl)-l-phenyl-2-propen-l-one, to 3-(o-aminophenyl)-l-phenyl-2-propen-l-one in 80% yield [555]. 

From the readily available benzotriazole derivative 76, Katritzky and Harris (90T987) prepared a diastereomeric mixture of the /3-amino ketone 77 with the lithium enolate of cyclohexanone. In the reduction of 77 with lithium aluminium hydride, a reductive cyclization took place, resulting in the two diastereomeric oxazinones 78 in a ratio of 5 2. This cyclization can be regarded as a variation of the chloroformate cyclization under alkaline conditions. 

Optimization of the previously reported Mannich-type reaction of trimethyl (pent-2-en-3-yloxy)silane with the sulfone Is derived from phenyl acetaldehyde (Table 5, entry 11) led to the corresponding (3-amino ketone in a good yield with moderate diastereoselectivity (2 mol% Bi(0Tf)3-4H20, yield = 84%, 24v/24v syn/anti = 72 28) (Scheme 8). Reduction of the major diastereoisomer 24v with lithium tri-ferf-butoxyaluminohydride afforded 25 as the only one diastereoisomer. Further cyclization of the latter with NaH afforded 4-benzyl-6-ethyl-5-methyl-l,3-oxazinan-2-one 26. The relative configuration of the six-membered carbamate was established as cis-cis by NMR analysis. 

One of the classical methods for the synthesis of pyrazines involves dimerization of an a-amino carbonyl compound and subsequent aromatization. Cyclic dimerization of the a-amino ketone, which is formed by reduction of a-azido ketone 149 with triphenylphosphine, leads to the formation of a pyrazine derivative 150 (Scheme 40) <1994JOC6828>. Reduced Te also dimerized a-keto azide 149 to give pyrazine 150 <2006JOG2797>. 

Macrocyclic 2-pyrones (113) and (114) are prepared from enamine (115) and ketene (75HCA2409). Reduction of cyano ketone (116) with LAH affords an amino ketone which spontaneously cyclizes to generate a tetrahydropyridine (117) dehydrogenation by palladium on charcoal produces the aromatized phane (118) (71TL671). 

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