Preparation of Imines and Enamines

Preparation of imines and enamines from carbonyl compounds and amines can be achieved with a dehydrating agent under acid/base catalysis [563]. Basically, primary amines afford imines unless isomerization to an enamine is favored as a result of conjugation, etc (see Eq. 252), and secondary amines afford iminium salts or enamines. These transformations can be conducted efficiently with a catalytic or stoichiometric amount of a titanium salt such as TiCU or Ti(0-/-Pr)4. Equation (247) illustrates an advantageous feature of this method in the imination of a hindered ketone. f-Butyl propyl ketone resisted the formation of the imine even by some methods reported useful for sterically hindered ketones [564,565]. The TiCU-based method works well, however, for this compound, giving the desired imine in high yield within a relatively short reaction period [566]. Imine derivatives such as iV-sulfonylimines could be 

The imines thus formed are often not isolated but are, instead, reduced directly to amines. Although NaBH3(CN) is a very common reducing agent, NaBH4 or other reagents shown in Table 23 can also be used. When preparation and reduction of the imine are performed successively in the same apparatus, Ti(0-/-Pr)4 seems to be a more suitable reagent than TiCU for imine formation (Eq. 249) [573]. Preparation of several amines by use of this sequence is shown in Table 23. 

Treatment of aldehydes or ketones with secondary amines in the presence of Ti(0-i-Pr)4 generates (A, 0)-hemiacetals (or iminium salts) which can be reduced by NaBH4 [578] or NaBH3(CN) [579] to give tertiary amines, as shown in Eq. (250) [578]. 

Ketones and secondary amines furnish enamines in the presence of TiCl4 [580,581]. The preparation of a functionalized enamine shown in Eq. (251), in which the acetal moiety is retained in the product, illustrates the applicability of this reaction [582]. Enamines prepared by this method are summarized in Table 24. Application to an intramolecular reaction is also found in Table 24. If formation of the enamine is thermodynamically preferred to formation of the isomeric imine, the former becomes the product even in the reaction of a ketone, a primary amine, and TiCl4, as shown in Eq. (252) [583], in which the resulting enamine was, after acetylation, isolated as the enamide. 

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MW-expedited dehydration reactions using montmorillonite K 10 clay [70] (Schs. 6.20 and 6.21) or Envirocat reagent, EPZG [71] (Schs. 6.20 and 6.21) have been demonstrated in a facile preparation of imines and enamines via the reactions of primary and secondary amines with aldehydes and ketones, respectively. The generation of polar transition state intermediates in such reactions and their enhanced... 

MW-promoted acceleration of such dehydration reactions using montmorillonite K 10 clay 40) or Envirocat reagent 41), EPZG (Scheme 7, 8) has been demonstrated in the preparation of imines and enamines. Microwaves at 2450 MHz... 

The spiro compound 206 was prepared in five steps from (S)-l-naphthyl-ethylamine and was composed of a mixture of imine and enamine tautomers. Reduction of the imine function by sodium borohydride occurred on the less hindered si face, leading to the diamine with the R configuration of the newly formed stereo center, then the N-benzyl substituent was removed by hydrogenolysis to give 207 with good overall yield [98] (Scheme 30). 

A/ -Methoxycarbonyl-2-pyrroline undergoes Vilsmeier formylation and Friedel-Crafts acylation in the 3-position (82TL1201). In an attempt to prepare a chloropyrroline by chlorination of 2-pyrrolidone, the product (234) was obtained in 62% yield (8UOC4076). At pH 7, two molecules of 2,3-dihydropyrrole add together to give (235), thus exemplifying the dual characteristics of 2,3-dihydropyrroles as imines and enamines. The ability of pyrrolines to react with nucleophiles is central to their biosynthetic role. For example, addition of acetoacetic acid (possibly as its coenzyme A ester) to pyrroline is a key step in the biosynthesis of the alkaloid hygrine (236). 

The preparation of imines, enamines, nitroalkenes and N-sulfonylimines proceeds via the azeotropic removal of water from the intermediate in reactions that are normally catalyzed by p-toluenesulfonic acid, titanium(IV) chloride, or montmorillonite K 10 clay. A Dean-Stark apparatus is traditionally used which requires a large excess of aromatic hydrocarbons such as benzene or toluene for azeotropic water elimination. 

Despite the remarkable enantioselectivities observed with the Ti-ebthi catalyst for the imine and enamine hydrogenation, we consider its technical potential rather low. The ligand is difficult to prepare, the activation of the catalyst precursor is tricky, for the moment the catalytic activity is far too low for preparative purposes, and last - but not least - its tolerance for other functional groups is low. 

Stable secondary enamines (21) may be prepared in aprotic media by partial methanolysis of organo-tin (32a), magnesium (32b) or lithium (32c) salts of imines and can be transferred from the reaction mixture under reduced pressure and trapped at —80 °C. These compounds are characterized by their NMR spectra and show a... 

The preparation of imines, enamines, nitroalkenes and N-sulfonylimines proceeds via azeotropic removal of water from the intermediate in reactions that are nor-... 

Metal carbonyl catalysis improves the yields in the condensation of aldehydes with isocyanates to give imines. The utility of molecular sieves in the preparation of aldehyde and ketone di-s-alkyl acetals, enamines and ketimines has been noted. 

The SAMP/RAMP Method As early as 1976, azaenolates derived from A,A-dialkyl hydrazones were studied as an alternative to direct ketone and aldehyde enolate alkylations. These species were found to exhibit higher reactivity toward electrophiles, as well as better regioselectivity for C-alkylation than their parent carbonyl compounds. A,A-diaIkyl hydrazones are stable and are relatively easy to prepare, making them appealing from a practical point of view in comparison with imines and enamines, which can be difficult to form quantitatively and are hydrolytically unstable. Given these desirable attributes, Enders undertook the development of chiral nonrace-mic A,A-diaIkyl hydrazine auxiliaries for the asymmetric a-alkylation of ketones. The result of his efforts were (5)-and (R)-l-amino-2-methoxypyrrohdine hydrazine (1 and 2, respectively), now commonly known as the SAMP and RAMP auxiliaries, respectively (Figure 7.1). Over the years, the SAMP/RAMP method has come to be considered the state-of-the-art approach to asymmetric ketone... 

Several methods for asymmetric C —C bond formation have been developed based on the 1,4-addition of chiral nonracemic azaenolates derived from optically active imines or enamines. These methods are closely related to the Enders and Schollkopf procedures. A notable advantage of all these methods is the ready removal of the auxiliary group. Two types of auxiliaries were generally used to prepare the Michael donor chiral ketones, such as camphor or 2-hydroxy-3-pinanone chiral amines, in particular 1-phenylethanamine, and amino alcohol and amino acid derivatives. 

The imines are prepared by 16-12. The enamine salt method has also been used to give good yields of mono a alkylation of a,P-unsaturated ketones. Enamines prepared from aldehydes and butylisobutylamine can be alkylated by simple primary alkyl halides in good yields. N-alkylation in this case is presumably prevented by steric hindrance. 

Hydroamination of alkynes offers a straightforward preparation of a variety of amines, enamines, and imines.79 Numerous reports have appeared in the literature on this process. However, almost all these reactions have been carried out in organic solvents, which usually require the protection of functional groups or harsh conditions. Recently, Marinelli et al. have reported an Au(III)-catalyzed hydroamination of alkynes in... 

Generally, the imine substrates are prepared from the corresponding ketone and amine and are hydrogenated as isolated (and purified) compounds. However, reductive animation where the C = N function is prepared in situ is attractive from an industrial point of view, and indeed there are some successful examples reported below [18, 19]. It is reasonably certain that most catalysts described in this chapter catalyze the addition of H2 directly to the C=N bond and not to the tautomeric enamine C = C bond, even though enamines can also be hydrogenated enantioselectively. 

Cyclohexanone imines derived from a-(methoxyniethyl)benzeneethanamine7 8, erythro-fl-methoxy-a-phenylbenzeneethanamine 6, and the tert-butyl esters of valine and rm-leucine3,17, as well as valine and h /-/-leucine derived enamines of /i-oxo esters3, are prepared by refluxing the amine and the carbonyl compound in benzene solution under azeotropic water removal, in 80-100% yield (see Table 1). 

A simple preparation of electron-poor 2-azadienes and the preliminary study of their ability to participate in [4 + 2] cycloadditions was done almost simultaneously by out group (87CC1195) (Scheme 49). The preparation of 2-azadienes 212 with two appended methoxycarbonyl groups was achieved, in a multigram scale and in nearly quantitative yield, by the insertion reaction of N- trimethylsilyl imines 210 into the carbon—carbon triple bond of dimethyl acetylenedicarboxylate to give 211 followed by protodesilylation with CsF/MeOH. Azadienes 212 underwent at room temperature inverse-electron demand [4 + 2] cycloaddition with cyclic enamines to give exclusively exo-cycloadducts 213 in 82-95% yield. Acid hydrolysis of them resulted in their aromatization to yield 2-pyrindine (n = 1] and isoquinoline (n = 2) derivatives 214. 

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