Cyclohexanone reductive amination

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. 

The first example of this type of transformation was reported in 1974 [76]. Three catalysts were investigated, namely [Co2(CO)8], [Co(CO)g/PBu ], and [Rh6(CO)i6]. The [Co OJg/PBu ] catalyst showed activity for reductive animation using ammonia and aromatic amines. The [Rh6(CO)16] catalyst could be used for reductive animation using the more basic aliphatic amines that were found to poison the cobalt catalyst. This early report pointed out that the successful reductive animation of iso-butanal (Me2CCHO) with piperidine involves selective enamine hydrogenation, that reductive animation of cyclohexanone with isopropylamine probably involves imine hydrogenation, and that reductive amination of benzaldehyde with piperidine would presumably involve the reduction of a carbinolamine. 

Reductive amination. lnaproccdureofBorch, 4 g. of potassium hydroxide (pellets) is added in one portion to a magnetically stirred solution of 21 g. (0.25 mole) of dimethyl-amine. hydrochloride in 150 ml. of methanol in a 500-ml. round-bottomed flask. Precipitation of potassium chloride begins immediately but does not interfere with the reaction, When the pellets are completely dissolved, 20 ml. (0.20 molc)of cyclohexanone is added in one portion. The resulting suspension is stirred at room temperature for... 

Thus reaction of cyclohexanone, n-propylamine, and sodium cyanoborohydride in methanol at pH 6-8 at 25° for 24 hr. gives n-propyleyelohexylamine in 85 % yield. The reaction is general for ammonia and primary and secondary amines aromatic amines are somewhat sluggish. All aldehydes and relatively unhindered ketones can be reduc-tively aminated. Yields are improved by use of 3A molecular sieves to absorb the water generated in the reaction. Note that reductive amination of substituted pyruvic acids with ammonia leads to oi-amino acids. Thus alanine can be obtained from pyruvic acid in 50 % yield. A pH of 7 is optimum for. synthesis of a-amino acids. 

Table 9 Stereochemistry of Reductive Amination of Cyclohexanones with Amines and Hydride Reagents...

Another method for reductive amination of carbonyl compounds is based on the electroreduction of oximes in aqueous media. Thus, sugar oximes were reduced to their corresponding glycamines in good yields (Hg, KCl, acetate buffer). Similar reductions of oximes derived from furfural, salicylaldehyde, benzophenone and cyclohexanone have also been described, " but reports of preparative electrolyses in strictly aprotic media seem to be absent in the literature. 

Reductive amination of ketones yields amines containing a sec-a ky group such amines are difficult to obtain by ammonolysis because of the tendency for jec-alkyl halides to undergo elimination. For example, cyclohexanone is converted into cyclohexylamine in good yield, whereas ammonolysis of bromocyclohexane yields only cyclohexene. 

Show the mechanism of reductive amination of cyclohexanone and dimethylamine with NaBHaCN. 

Reductive amination. LiBH4 is said to be the reagent of choice for reductive amin-ation of substituted cyclohexanones. 

Complex 54 displayed a high activity in the reduction of cyclohexanone with a TOF value of 6000 h (Figure 13.7)." Tetrahydropyridoimidazolin-2-yli-dene-containing 55 was also evaluated for TH of acetophenone and cyclohexanone in z-PrOH/KOH. ° Cationic triazol-5-ylidene complexes 56 were found highly active for the TH of C=0 and C=C functions as well as for reductive amination of aldehydes. 

Dicyclohexylarnine may be selectively generated by reductive alkylation of cyclohexylamine by cyclohexanone (15). Stated batch reaction conditions are specifically 0.05—2.0% Pd or Pt catalyst, which is reusable, pressures of 400—700 kPa (55—100 psi), and temperatures of 75—100°C to give complete reduction in 4 h. Continuous vapor-phase amination selective to dicyclohexylarnine is claimed for cyclohexanone (16) or mixed cyclohexanone plus cyclohexanol (17) feeds. Conditions are 5—15 s contact time of <1 1 ammonia ketone, - 3 1 hydrogen ketone at 260°C over nickel on kieselguhr. With mixed feed the preferred conditions over a mixed copper chromite plus nickel catalyst are 18-s contact time at 250 °C with ammonia alkyl = 0.6 1 and hydrogen alkyl = 1 1. 

Other secondary amines such as pyrrolidine, di- -butylamine, tetrahydro-quinoline, n-benzylamine, and piperidine were also found to be capable of effecting this reduction. Interestingly, morpholine does not reduce enamines as readily (47) and its acid-catalyzed reaction with norbornanone was reported (45) to give only the corresponding enamine (93), although trace amounts of the reduction product were detected when cyclohexanone was treated with morpholine under these conditions (47a). The yield of morpholine reduction product was increased by using higher temperatures. 

In an analogous sequence, reductive alkylation of aminoalcohol, 46, with cyclohexanone affords the secondary amine (47). Acylation with benzoyl chloride affords hexylcaine (48) in a reaction that may again involve acyl migration. 

Aldol condensation of the methoxymethyl ether of m-methoxybenzaldehyde (83) with cyclohexanone affords the conjugated ketone 84. Michael addition of dimethyl amine leads to the ami noketone Reduction of the ketone... 

Alkylation lo yield a leriiary amine may occur easily if the formation involves cyclization (ii). Catalysts may have a marked influence. In reductive alkylation of ammonia wilh cyclohexanones, more primary amine was formed over Ru and Rh and more secondary amine over Pd and Pt. Reduction of the ketone to an alcohol is an important side reaction over ruthenium. 

Cyclohexanones may serve as precursors to aromatic amines in a reductive alkylation, the source of hydrogen being aromatization of the cyclohexanone (66). In a variation, an aromatic nitro compound acts as both an amine precursor and a hydrogen acceptor (64). 

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