Hydrogenation reductive amination

Table 5.8 Transfer hydrogenation, reductive amination and dehalogenation of water-soluble compounds with 24, 27 28, and hydrogen donors."...

Reasonable conversions of NPBA were observed when using ketones as solvents however, product analysis showed increased byproducts formation with the use of ketones. When acetone is used as solvent, GC/MS analysis identified 2-methylindoline and N-phenylisopropylamine as the two major byproducts, which are produced via a secondary reaction between aniline (product), acetone and hydrogen (reductive amination). Similar byproducts were observed when using methyl ethyl ketone (MEK) as a solvent. In a parallel experiment, about 13% of aniline reacted with acetone under the same reaction conditions except in the absence of a catalyst. Most of the reaction product, about 11%, is non-hydrogenated product 2-methylindoline (C9H11N). These results clearly demonstrate that ketones are the least preferred solvents for N-debenzylation due to the secondary reaction between the desired product and the ketones. 

Levuhnic acid is one of the products of selective dehydration of cellulosic biomass feedstocks. Levuhnic acid is produced when six-member ring carbohydrates derived from ceUulose are subjected to acid-catalyzed dehydration conditions (Fig. 9.6) [4, 43]. The other main product of this reaction is formic acid. Although levulinic acid has some potential use as a solvent or in the production of industrial and pharmaceutical chemicals, its current market is minimal [4]. Therefore, the conversion of levulinic acid to a directly usable biofuel has become an important area of interest. In particular, esterification, oxidation, hydrogenation, reductive amination, condensation, and enzymatic conversion have been tested as potential methods to produce useful compounds from levulinic acid [4,44,45]. 

A variation of the classical reductive amination procedure uses sodium cyanoboro hydride (NaBH3CN) instead of hydrogen as the reducing agent and is better suited to amine syntheses m which only a few grams of material are needed All that is required IS to add sodium cyanoborohydride to an alcohol solution of the carbonyl compound and an amine... 

Reductive amination of cyclohexanone using primary and secondary aHphatic amines provides A/-alkylated cyclohexylamines. Dehydration to imine for the primary amines, to endocycHc enamine for the secondary amines is usually performed in situ prior to hydrogenation in batch processing. Alternatively, reduction of the /V-a1ky1ani1ines may be performed, as for /V,/V-dimethy1 cyclohexyl amine from /V, /V- di m e th y1 a n i1 i n e [121 -69-7] (12,13). One-step routes from phenol and the alkylamine (14) have also been practiced. 

DCHA is normally obtained in low yields as a coproduct of aniline hydrogenation. The proposed mechanism of secondary amine formation in either reductive amination of cyclohexanone or arene hydrogenation iHurninates specific steps (Fig. 1) on which catalyst, solvents, and additives moderating catalyst supports all have effects. 

Amin omethyl-3,5,5-trimethyl cyclohexyl amine (21), commonly called isophoronediamine (IPD) (51), is made by hydrocyanation of (17) (52), (53) followed by transformation of the ketone (19) to an imine (20) by dehydrative condensation of ammonia (54), then concomitant hydrogenation of the imine and nitrile functions at 15—16 MPa (- 2200 psi) system pressure and 120 °C using methanol diluent in addition to YL NH. Integrated imine formation and nitrile reduction by reductive amination of the ketone leads to alcohol by-product. There are two geometric isomers of IPD the major product is ds-(22) [71954-30-5] and the minor, tram-(25) [71954-29-5] (55). 

Ethylamines. Mono-, di-, and triethylamines, produced by catalytic reaction of ethanol with ammonia (330), are a significant outlet for ethanol. The vapor-phase continuous process takes place at 1.38 MPa (13.6 atm) and 150—220°C over a nickel catalyst supported on alumina, siUca, or sihca—alumina. In this reductive amination under a hydrogen atmosphere, the ratio of the mono-, di-, and triethylamine product can be controlled by recycling the unwanted products. Other catalysts used include phosphoric acid and derivatives, copper and iron chlorides, sulfates, and oxides in the presence of acids or alkaline salts (331). Piperidine can be ethylated with ethanol in the presence of Raney nickel catalyst at 200°C and 10.3 MPa (102 atm), to give W-ethylpiperidine [766-09-6] (332). 

These reductions are not important for preparative purposes. The same can be said for reductions with LiAlH4, and with hydrogen over a catalyst, converting diaziridines to a mixture of amines including products of reductive amination of the former carbon atom of the diaziridine ring. 

Reductive amination (Section 22.10) Reaction of ammonia or an amine with an aldehyde or a ketone in the presence of a reducing agent is an effective method for the preparation of primary, secondary, or tertiary amines. The reducing agent may be either hydrogen in the presence of a metal catalyst or sodium cyanoborohy-dride. R, R, and R" may be either alkyl or aryl. 

Reductive amination (Section 22.10) Method for the preparation of amines in which an aldehyde or a ketone is treated with ammonia or an amine under conditions of catalytic hydrogenation. 

The prototype, amphetamine (52), is obtained by reductive amination of phenylacetone by means of ammonia and hydrogen. Isolation of the (+) isomer by resolution gives dextroamphetamine, a somewhat more potent stimulant than the racemate. 

Esters of diphenylacetic acids with derivatives of ethanol-amine show mainly the antispasmodic component of the atropine complex of biologic activities. As such they find use in treatment of the resolution of various spastic conditions such as, for example, gastrointestinal spasms. The prototype in this series, adiphenine (47), is obtained by treatment of diphenyl acetyl chloride with diethylaminoethanol. A somewhat more complex basic side chain is accessible by an interesting rearrangement. Reductive amination of furfural (42) results in reduction of the heterocyclic ring as well and formation of the aminomethyltetrahydro-furan (43). Treatment of this ether with hydrogen bromide in acetic acid leads to the hydroxypiperidine (45), possibly by the intermediacy of a carbonium ion such as 44. Acylation of the alcohol with diphenylacetyl chloride gives piperidolate (46). ... 

A variation on this theme consists in first displacement of the chlorine in 73 with ethylaminoethanol. Reductive amination of the ketone by means of ammonia in the presence of hydrogen gives the hydroxylated diamine (77). Use of this intermediate to effect displacement of the halogen at the 4 position of 70 affords hydroxychloroquine (78). ... 

Some workers avoid delay. Pai)adium-on-carbon was used effectively for the reductive amination of ethyl 2-oxo-4-phenyl butanoate with L-alanyl-L-proline in a synthesis of the antihyperlensive, enalapril maleate. SchifTs base formation and reduction were carried out in a single step as Schiff bases of a-amino acids and esters are known to be susceptible to racemization. To a solution of 4,54 g ethyl 2-oxO 4-phenylbutanoate and 1.86 g L-alanyl-L-proline was added 16 g 4A molecular sieve and 1.0 g 10% Pd-on-C The mixture was hydrogenated for 15 hr at room temperature and 40 psig H2. Excess a-keto ester was required as reduction to the a-hydroxy ester was a serious side reaction. The yield was 77% with a diastereomeric ratio of 62 38 (SSS RSS)((55). 

Amines can be synthesized in a single step by treatment of an aldehyde or ketone with ammonia or an amine in the presence of a reducing agent, a process called reductive amination. For example, amphetamine, a central nervous system stimulant, is prepared commercially by reductive amination of phenyl-2-propanone with ammonia, using hydrogen gas over a nickel catalyst as the reducing agent. 

Amino acids can be synthesized in racemic form by several methods, including ammonolysis of an a-bromo acid, alkylation of diethyl acetamido-malonate, and reductive amination of an cv-keto acid. Alternatively, an enantio-selective synthesis of amino acids can be carried out using a chiral hydrogenation catalyst. 

The reductive amination of ketones can be carried out under hydrogen pressure in the presence of palladium catalysts. However, if enantiopure Q -aminoketones are used, partial racemization of the intermediate a-amino imine can occur, owing to the equilibration with the corresponding enam-ine [102]. Asymmetric hydrogenation of racemic 2-amidocyclohexanones 218 with Raney nickel in ethanol gave a mixture of cis and trans 1,2-diamino cyclohexane derivatives 219 in unequal amounts, presumably because the enamines are intermediates, but with excellent enantioselectivity. The two diastereomers were easily separated and converted to the mono-protected cis- and trans- 1,2-diaminocyclohexanes 220. The receptor 221 has been also synthesized by this route [103] (Scheme 33). 

The direct reductive amination (DRA) is a useful method for the synthesis of amino derivatives from carbonyl compounds, amines, and H2. Precious-metal (Ru [130-132], Rh [133-137], Ir [138-142], Pd [143]) catalyzed reactions are well known to date. The first Fe-catalyzed DRA reaction was reported by Bhanage and coworkers in 2008 (Scheme 42) [144]. Although the reaction conditions are not mild (high temperature, moderate H2 pressure), the hydrogenation of imines and/or enam-ines, which are generated by reaction of organic carbonyl compounds with amines, produces various substituted aryl and/or alkyl amines. A dihydrogen or dihydride iron complex was proposed as a reactive intermediate within the catalytic cycle. 

Hydrogenation of Nitrogen-Containing Multiple Bonds and Reductive Amination... 

HYDROGENATION OF NITROGEN-CONTAINING MULTIPLE BONDS AND REDUCTIVE AMINATION... 

Amines can be synthesized by the treatment of a ketone or aldehyde with an amine in the presence of hydrogen and a noble metal catalyst. During this reductive amination, the intermediate loses water to give an imine that is reduced to yield the amine product (Scheme 5.4). 

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