Ketimines, hydrogenation

The reductive alkylation reaction consists of a sequence of steps in which the hydrogenation is preceded by chemical processes. For primary amines, one forms the alcoholamine, which could proceed on to the ketimine. Hydrogenation of either the alcoholamine or the ketimine produces the secondary amine product,... 

Other modifications of the polyamines include limited addition of alkylene oxide to yield the corresponding hydroxyalkyl derivatives (225) and cyanoethylation of DETA or TETA, usuaHy by reaction with acrylonitrile [107-13-1/, to give derivatives providing longer pot Hfe and better wetting of glass (226). Also included are ketimines, made by the reaction of EDA with acetone for example. These derivatives can also be hydrogenated, as in the case of the equimolar adducts of DETA and methyl isobutyl ketone [108-10-1] or methyl isoamyl ketone [110-12-3] (221 or used as is to provide moisture cure performance. Mannich bases prepared from a phenol, formaldehyde and a polyamine are also used, such as the hardener prepared from cresol, DETA, and formaldehyde (228). Other modifications of polyamines for use as epoxy hardeners include reaction with aldehydes (229), epoxidized fatty nitriles (230), aromatic monoisocyanates (231), or propylene sulfide [1072-43-1] (232). 

The Schiff reaction between chitosan and aldehydes or ketones yields the corresponding aldimines and ketimines, which are converted to N-alkyl derivatives upon hydrogenation with borohydride. Chitosan acetate salt can be converted into chitin upon heating [130]. The following are important examples of modified chitosans that currently have niche markets or prominent places in advanced research. 

The first example of an asymmetric reduction of C=N bonds proceeding via DKR was reported in 2005 by Lassaletta et al. In this process, the transfer hydrogenation of 2-substituted bicyclic and monocyclic ketimines could be accomplished via DKR by using a HCO2H/TEA mixture as the hydrogen source and a chiral ruthenium complex including TsDPEN ligand,... 

Ketimines were hydrogenated faster than aldimines, and electron-donating groups accelerated the rate of hydrogenation. The OH and RuH bonds are regenerated by hydrogen transfer to the unsaturated 16-electron Ru complex from isopropanol, generating acetone (Scheme 7.13). 

Kinetic studies were carried out by Backvall and coworkers at -54 °C on the hydrogenation of a ketimine, which produces a ruthenium complex with a bound amine (Eq. (46)) [77]. 

Examination of a series of imines of differing electronic properties showed that a change in the rate-determining step of this stoichiometric C=N hydrogenation occurs as the imine becomes more electron-rich. Hydrogenation of N-iso-propyl-(4-methyl)benzilidene amine led to an amine complex of ruthenium. In addition, the C=N hydrogenation was accompanied by isomerization of the imine to a ketimine (Eq. (47)). 

Various phenyl-substituted ketimines and aldimines react with metallocenes 1 and 2, in a manner that depends on the substituents present [41]. In all cases, elimination of the al-kyne is observed. Complex 2b reacts with PhN=CMePh to give the r 2-complex 64, which is stabilized by an additional pyridine ligand [41a], In the reactions of 1 or 2a with the ketimine HN=CPh2, hydrogen transfer generates complexes 65. Two molecules of the aldimine PhN=CHPh are coupled by 2a to give the cyclic diamido complex 66 [41b]. 

More recently, an important chiral titanium catalyst for the asymmetric reduction with hydrogen of /V-substi luted dialkyl ketimines to enantioenriched amines has been... 

Iridium-Catalyzed Asymmetric Hydrogenation of Olefins with Chiral N,P and C,N Ligands 71 Table 18 Asymmetric hydrogenation of acetophenone based A-aryl ketimines... 

Furthermore, the N-alkylation of 2-aminobenzyl alcohol 114 with ketones 115 in the presence of [IrCl(cod)]2 and KOH gave quinoline derivatives 116 (Equation 10.28) [52]. The reaction may be initiated by the formation of ketimine from 114 and 115, and the ketimine thus formed is oxidized by Ir catalyst and the 114 which serves as a hydrogen acceptor giving the corresponding aldehyde, which is eventually converted into quinoline 116 through intramolecular aldol-type condensation. 

For the reduction of ketimines with trichlorosylane via a possible hydrogen-bonding activation, see Maikov, A. V. Mariani, A. MacDougall, K. N. Kocovsky, P. Org. Lett. 2004, 6, 2253-2256. 

Ketimines are reduced to amines very easily by catalytic hydrogenation, by complex hydrides and by formic acid. They are intermediates in reductive amination of ketones (p. 134). An example of the reduction of a ketimine is conversion of 3-aminocarbonyl-2,3-diphenylazirine to the corresponding aziridine by sodium borohydride (yield 73%), by potassium borohydride (yield 71%) and by sodium bis (2-methoxyethoxy) aluminum hydride (yield 71%) [939]. 

PLP-dependent enzymes catalyze the following types of reactions (1) loss of the ce-hydrogen as a proton, resulting in racemization (example alanine racemase), cyclization (example aminocyclopropane carboxylate synthase), or j8-elimation/replacement (example serine dehydratase) (2) loss of the a-carboxylate as carbon dioxide (example glutamate decarboxylase) (3) removal/replacement of a group by aldol cleavage (example threonine aldolase and (4) action via ketimine intermediates (example selenocysteine lyase). 

The presence of a heteroatom directly connected to the nitrogen atom of the imine activates it toward hydrogenation, while creating a second coordination site for the catalyst. Indeed, some successful results have been achieved for the hydrogenation of N-acylhydrazone, sulfonimide, and N-diphenylphosphinyl ketimines. The Et-DuPhos-Rh complex is an efficient catalyst for the asymmetric hydrogenation of a variety of N-acyl- ... 

Whereas branched ketimines are metalated at the less substituted carbon, metalation and alkylation of unsymmetric imines leads to regioisomers2,4,27. For this reason, only symmetrical ketones and unsymmctrical ketones with one substituent having no a-hydrogens have been applied in alkylation reactions via imines (see Table 4). 

Padwa, Bergmark, and Pashayan were able to demonstrate that 22 and other ketimines are photochemically unreactive and that all of the reduction observed upon direct irradiation is due to hydrogen abstraction by the corresponding ketone formed either by hydrolysis or by oxidation of the imine.120 The results with 23 may have a similar explanation. 

---