Benzylamine imines

Bergbreiter and Newcomb have shown that the benzylamine imine of 3-pentanone is deprotonated by lithium diisopropylamide selectively at the benzylic position of a 2-azaallyllithium system that slowly isomerizes by a protonation-deprotonation sequence to afford the 1-azaallyl system (equation 46). ... 

Schiff bases, also known as imines, ate formed by the condensation of carbonyl compounds with ammonia or primary amines. Hydrogenation of the resulting Schiff bases forms amines, such as benzylamine and dibenzylamine. 

A later variation of the general method, which extends the scope to 20-ketones, involves reaction of the ketone with benzylamine to give the imine, followed by conversion to the A-acetyl derivative with acetic anhydride. Although the resulting compound also has a A -double bond, it does not react sufficiently fast with peracid, and a A -double bond can not be preserved. 

Modification of the Erlenmeyer reaction has been developed using imines of the carbonyl compounds, obtained with aniline," benzylamine or n-butylamine. Ivanova has also shown that an A-methylketimine is an effective reagent in the Erlenmeyer azlactone synthesis. Quantitative yield of 19 is generated by treatment of 3 equivalents of 2-phenyl-5(4ff)-oxazolone (2) (freshly prepared in benzene) with 1 equivalent of iV-methyl-diphenylmethanimine (18) in benzene. Products resulting from aminolysis (20), alkali-catalyzed hydrolysis (21), and alcoholysis (22) were also described. 

The Schlittler-Muller variation of the Pomeranz-Fritsch reaction involves reaction of diethoxyethanal 17 with benzylamine 16 to prepare the desired imine 18. Intermediate 18 is subsequently cyclised to substituted isoquinoline 19. The advantage here lies in the fact that the initial condensation can still take place between an aldehyde and an amine. 

Another route to the amido complexes originates from [(>j-Tp )W(CO) (PhC=CMe)(OTf)l and benzylamine and yields [(i -Tp )W(CO)(PhC=CMe) (NHCH2Ph)] (96JA6916). The latter can be protonated with tetrafluoroboric acid to give the amine derivative [(> -Tp )W(CO)(PhC=CMe)(NH2CH2Ph)](Bp4), and this process can be reversed by -butyllithium. Hydride abstraction by silver tetrafiuoroborate, molecular iodine, or PhsCPEe leads to the cationic imine derivatives [(> -Tp )W(CO)(PhC=CMe)(HN=CHPh)]". -Butyllithium deproto-nates the product and gives the neutral azavinylidene species [(> -Tp )W(CO) (PhC=CMe)(N=CHPh)]. The latter with silver tetrafiuoroborate forms the cationic nitrile species [(j -Tp )W(CO)(PhC=CMe)(N=CPh)](Bp4). 

Simple imines are poor dienophiles and must be activated by protonation or by attaching an electron-withdrawing group to the nitrogen atom. Scheme 6.10 illustrates the Diels-Alder reactions of benzyliminium ion 25, generated in situ from an aqueous solution of benzylamine hydrochloride and commercial aqueous formaldehyde, with methylsubstituted 1,3-butadienes [22]. This aqueous Diels-Alder reaction combines three components (an aldehyde, an amine... 

The Strecker reaction has been performed on the aldehyde 182 prepared from L-cysteine [86] (Scheme 28). The imine was formed in situ by treatment with benzylamine, then TMS cyanide was added to afford prevalently in almost quantitative yield the syn-diamine 183, which is the precursor of (-l-)-biotin 184. The syn selectivity was largely affected by the solvent, toluene being the solvent of choice. Since the aldehyde 182 is chemically and configurationally unstable, a preferred protocol for the synthesis of 183 involved the prehminary formation of the water-soluble bisulfite adduct 185 and the subsequent treatment with sodium cyanide. Although in this case the syn selectivity was lower, both diastereomers could be transformed to (-l-)-biotin. 

In 1997 the first asymmetric aza-Claisen rearrangement was reported by Overman et al. [55], which made use of diamines as bidentate ligands for Pd(II), allowing for moderate enantioselectivities. In the same year, Hollis and Overman described the application of the planar chiral ferrocenyl palladacycle 38 as a catalyst for the enantioselective aza-Claisen rearrangement of benzimidates 39 (Fig. 19) [56]. A related ferrocenyl imine palladacycle provided slightly inferior results, while a benzylamine palladacycle lacking the element of planar chirality was not able to provide any enantioselectivity [57]. 

Evidently this is a hydrogenation and the source of the hydrogen is benzylamine as indicated by the production of benzaldehyde and ammonia in equivalent amounts presumably the benzylamine is dehydrogenated to the imine C,HjCH =NH, which is then hydrolysed. In the absence of hexamine, the maximum yield of benzaldehyde is 50 per cent. When hexamine is added to the reaction mixture, the yield of aldehyde is increased and that of methylbenzylamine is decreased, and methyl-amine is present at the end of the reaction. Hexamine reacts as the methylene derivative of ammonia, CH2=NH, which is hydrogenated to methylamine. The fundamental stage of the Sommelet reaction may be written as ... 

Addition of A-mesityl benzimidazolyl carbene 720 to an a,/3-unsaturated aldehyde generates a homoenolate intermediate that undergoes an addition/acylation sequence with azomethine imine 719 to afford (3R, 5S, 6S )-177-pyrazolo[l,2- ]pyridazine-l,8(5//)-diones 721 with excellent diastereoselectivity. Compound 721 (Ar = R = Ph) treated with sodium hydoxide in methanol or benzylamine provided nearly quantitatively, ring-opened products 722a and 722b, respectively (Scheme 116) <2007JA5334>. 

The A-acetyl derivatives of the 2-alkylthio-l,3-thiadiazol-4-imines (124, R = SR, R = Ac) undergo nucleophilic displacement reaction with amines (benzylamine, cyclohexylamine, morpholine, or aniline) giving the 2-amino derivatives (124, R = NRj, R = Ac). The salt (126, R = R = Ph, R = R = H, X = Cl) reacts with aniline at room temperature giving 4-anilino-2-phenyl-l,3-thiazole (128), presumably by a mechanism involving cleavage of the heterocyclic ring. ... 

Kinetics and mechanisms of oxidation of amines by Ru porphyrin complexes (particularly TMP species) have been reviewed [42]. rranx-Ru(0)2(TMP)/02/ CgHg/50°C/24h oxidised primary and secondary amines in the oxidation of ben-zylamine frani-Ru(NHj)jCHjPh)2(TMP) was isolated and characterised crystallo-graphically. A mechanism involving a two-electron oxidation of benzylamine to A-benzylideneamine by tra i-Ru(0)2(TMP) was proposed with concomitant reduction of the latter to Ru (0)(TMP). This disproportionates to tranx-Ru "(0)2(TMP) and Ru"(TMP) the latter regenerates Ru" (0)(TMP) with O, while the second two-electron oxidation of the imine to the aldehyde is effected by tranx-Ru(0)2(TMP) [597], (Table 5.1) [598]. 

Aryl alkyl amines gave hydroxylamine 0-arylsulfonates when reacted with arylsul-fonyl peroxide. The products were later decomposed to azomethine and further hydrolysis results in the corresponding amine with one less carbon atom. Thus when p-methoxy-benzylamine was treated with p-nitrophenylsulfonyl peroxide at —78 °C in ethyl acetate, p-methoxybenzaldehyde and p-methoxyaniline were obtained . Cyclic amines with p-nitrophenylsulfonyl peroxide were converted to the Al-(p-nitrophenylsulfonyloxy)amine derivatives, which further rearranged to ring-expanded cyclic imines in good yields (equation 9 f. ... 

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