Iminium activation Michael/aldol reactions

This dual enamine/iminium activation profile in cascade Michael/aldol reactions can also be found even in some early reports, mostly focused on the self-dimerization of enals catalyzed by proline or analogues derived thereof, which generally proceeded with low enantioselect vities. There is not a clear and definitive mechanistic pathway confirmed for these reactions, although the most widely accepted proposal for the dimerization of enals (Scheme 7.4) ° involved sequential activation of one molecule of the substrate as a dienamine (Michael donor) and another molecule as iminium ion (Michael acceptor). 

Scheme 7.66 Cascade triple Michael/Michael/aldol reaction combining H-bonding activation and iminium catalysis.

Jorgensen showed that the asymmetric synthesis of cyclohexene derivatives can also be accomplished by reaction of two equivalents of an enal with an active methylene compound. The sequence comprising two iminium-activated Michael additions followed by enamine-mediated aldol reaction afforded various cyclohexene carboxaldehydes (Scheme 8.20). 

Scheme 10.5 Domino Michael/aldol reaction through iminium-enamine activation mode.

The use of this catalyst allowed the same authors to elaborate an asymmetric domino Michael-Michael-aldol reaction, involving two aldehydes and a nitroalkene on the basis of an enamine-iminium-enamine activation. The corresponding cyclohexene-carbaldehydes were isolated with virtually complete diastereo- and enantioselectivities, as shown in Scheme 1.63. 

Since the early example of a proline-catalyzed asymmetric domino Michael-aldol reaction reported by Bui and Barbas in 2000 [57], a number of these reactions have been successfully developed by several groups. For example, Wang et al. have reported the synthesis of chiral densely functionalized cyclopentenes on the basis of a domino Michael-aldol reaction followed by dehydration between aromatic enals and dimethyl 2-oxoethylmalonate [67]. High yields (63-89%) and enanhose-lectivities (91-97% ee) were obtained by using (S)-diphenylprolinol sUyl ethers as catalysts. On the other hand, the condensation of P-nitroketones 36 onto enals in the presence of 8 was shown by Hong et al. to afford the corresponding domino Michael-aldol products 37 through the iminium-enamine activation mode [68]. 

With regard to the reaction mechanism of the asymmetric domino Michael-aldol reaction, it was proposed that the diphenylprolinol ether 34 formed the intermediate iminium ion 147a from a,p-unsaturated aldehyde (Scheme 1.56). 1,4-Addition then occurred with the tautomeric structure of 1,2-cyclohexadione, resulting in the Michael adduct 147b, an activated enamine that subsequently underwent an intramolecular aldol reaction. 

This catalytic cascade was first realized using propanal, nitrostyrene and cinnamaldehyde in the presence of catalytic amounts of (9TMS-protected diphenylprolinol ((.S )-71,20 mol%), which is capable of catalyzing each step of this triple cascade. In the first step, the catalyst (S)-71 activates component A by enamine formation, which then selectively adds to the nitroalkene B in a Michael-type reaction (Hayashi et al. 2005). The following hydrolysis liberates the catalyst, which is now able to form the iminium ion of the a, 3-unsaturated aldehyde C to accomplish in the second step the conjugate addition of the nitroalkane (Prieto et al. 2005). In the subsequent third step, a further enamine reactivity of the proposed intermediate leads to an intramolecular aldol condensation. Hydrolysis returns the catalyst for further cycles and releases the desired tetrasubstituted cyclohexene carbaldehyde 72 (Fig. 8) (Enders and Hiittl 2006). 

The process mechanism as shown in Figure 2.23 consists of an initial activation of the aldehyde (66) by the catalyst [(5)-67] with the formation of the corresponding chiral enamine, which then, selectively, adds to nitroalkene (65) in a Michael-type reaction. The following hydrolysis liberates the catalyst, which forms the iminium ion of the a,(3-unsaturated aldehyde (62) to accomplish the conjugate addition with the nitroalkane A. In the third step, another enamine activation of the intermediate B leads to an intramolecular aldol condensation via C. Finally, the hydrolysis of it returns the catalyst and releases the desired chiral tetra-substituted cyclohexene carbaldehyde (68). 

Alternatively, the iminium-activation strategy has also been apphed to the Mukaiyama-Michael reaction, which involves the use of silyl enol ethers as nucleophiles. In this context, imidazolidinone 50a was identified as an excellent chiral catalyst for the enantioselective conjugate addition of silyloxyfuran to a,p-unsaturated aldehydes, providing a direct and efficient route to the y-butenolide architecture (Scheme 3.15). This is a clear example of the chemical complementarity between organocatalysis and transition-metal catalysis, with the latter usually furnishing the 1,2-addition product (Mukaiyama aldol) while the former proceeds via 1,4-addition when ambident electrophiles such as a,p-unsaturated aldehydes are employed. This reaction needed the incorporation of 2,4-dinitrobenzoic acid (DNBA) as a Bronsted acid co-catalyst assisting the formation of the intermediate iminium ion, and also two equivalents of water had to be included as additive for the reaction to proceed to completion, which... 

There is also another similar case in which 5-oxohexanal was employed as functionalized Michael donor undergoing Michael addition/intramolecular aldol reaction with aromatic enals (Scheme 7.3), which also ended up with a final dehydration step leading to the formation of functionalized cyclohexenes. Under the optimized reaction conditions, the final compounds were obtained in moderate yields but with excellent enantioselect vities and as single diaster-eoisomers. It should be pointed out that, from the mechanistic point of view, a dual activation of the 5-oxohexanal via enamine formation) and the a,p-unsaturated aldehyde via iminium ion formation) might operate in this case in the catalytic cycle, although no mechanistic proposal was provided by the authors. 

In 2010, Enders and co-workers developed a quadruple cascade AFC/ Michael/Michael/aldol condensation reaction of indoles, acrolein, and nitroalkenes under the catalysis of diphenylprolinol TMS-ether catalyst (S)-104 following an iminium/enamine/iminium/enamine activation sequence (Scheme 6.42). " The reaction provided a straightforward and efficient entry to 3-(cyclohexenylmethyl)-indoles 105 bearing three stereogenic centers in moderate to excellent yields (23-82%) and excellent stereoselectivity (91 9->95 5 dr and 94->99% ee). 

An organocatalytic (j0rgensen-Hayashi catalyst 1) domino Micliael/Michael/aldol condensation was used to prepare a hexahydronaphtlialenone (+)-121 m route to the natural product (+)-galbulin (Scheme 7.22). In this case, it was proposed that an iminium salt 118 (activated from the re face) and an enamine species 117 were preformed. Following a kinetic asymmetric transformation (KAT) of the racemic precursor 115, the intermediate 119 is first formed through an intermolecular Michael reaction. A second intramolecular Michael reaction occurs and the intermediate 120 forms, and finally an acid-initiated aldol condensation... 

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