Nitroalkenes enamine activation

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). 

As has already been mentioned, the low reactivity of enamine nucleophiles needs a highly electrophilic Michael acceptor for the reaction to proceed with good conversions in an acceptable time. In this context, the Michael reaction of aldehydes and ketones with nitroalkenes can be regarded as one of the most studied transformations in which the enamine activation concept has been applied. This reaction furnishes highly functionalized adducts with remarkable potential in organic synthesis, due to the synthetic versatility of the nitro group and the presence of the carbonyl moiety from the donor reagent. 

Nevertheless, as was pointed out before, a straightforward solution to the rather limited substrate scope of the reaction with regard to the ketone reagent and also a good way to overcome the lack of reactivity of ketones toward enamine activation has been the use of primary amines as organocatalysts. In fact, literature examples indicate that primary amines are much more active catalysts for the Michael addition of both cyclic and acyclic ketones to nitroalkenes compared to the same reaction using a secondary amine catalyst like most of the proline-based derivatives already presented before. 

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). 

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. 

Catalytic reactions proceeding via enamines as intermediates. A DFT study at the B3LYP/6-31H-G(2df,p)//B3LYP/6-31G(d) level of the proline-catalysed Michael addition of ketones (via enamines) to nitroalkenes has revealed that the added benzoic acids play two major roles, namely assisting the proton transfer and activating the nitro group. °... 

Scheme 6.104 Key intermediates of the proposed catalytic cycle for the 100-catalyzed Michael addition of a,a-disubstituted aldehydes to aliphatic and aromatic nitroalkenes Formation of imine (A) and F-enamine (B), double hydrogen-bonding activation of the nitroalkene and nucleophilic enamine attack (C), zwitterionic structure (D), product-forming proton transfer, and hydrolysis.

Bronsted acid (Scheme 2.42) [26-28]. (For experimental details see Chapter 14.9.4). These catalysts mediate the addition of ketones to nitroalkenes at room temperature in the presence of a weak acid co-catalyst, such as benzoic acid or n-butyric acid or acetic acid. The acid additive allows double alkylation to be avoided, and also increases the reaction kinetic. The Jacobsen catalyst 24 showed better enantio- and diastereoselectivity with higher n-alkyl-ethyl ketones or with branched substrates (66 = 86-99% dr = 6/1 to 15/1), and forms preferentially the anti isomer (Scheme 2.42). The selectivity is the consequence of the preferred Z-enamine formation in the transition state the catalyst also activates the acceptor, and orientates in the space. The regioselectively of the alkylation of non-symmetric ketones is the consequence of this orientation. Whilst with small substrates the regioselectivity of the alkylation follows similar patterns (as described in the preceding section), leading to products of thermodynamic control, this selectivity can also be biased by steric factors. 

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). 

Depending of the catalyst structure, a dual catalyst activation mode may be involved in the process. For instance, in catalyst 42 (Fig. 2.4) [62] the presence of the trans-OH group in the 4-position of the pyrroUdine ring helps to activate the electrophile and also directs its approach from the less hindered face of the -enamine (B, Fig. 2.5). The bifunctional catalyst activation behavior is also suggested for other catalysts such as Jacobsen s thiourea 41 (Fig. 2.4) [61], where binding of the nitroalkene by the thioureamoiety allows the thermodynamically favorable E enamine to attain in close proximity for a highly diastereo- and enantioselective C-C bond-formation (C, Fig. 2.5). 

The simple chiral secondary amine (S)-70 activates the linear aldehyde 139 by enamine formation, which selectively attacks the nitroalkenes 140 in a Michael-type reaction without any interference by the a,p-unsaturated aldehyde 95. Indeed, the latter prefers to be activated as iminium ion by the catalyst (5)-70 and to undergo the subsequent conjugate addition to form the Michael adduct B (Scheme 2.41). 

The observed excellent stereoselectivities (dr=91 9 to >95 5, 94 to >99% ee) could be ascribed to the steric hindrance created by the employed catalyst in each step of the catalytic cycle reported below (Scheme 2.56). Once the chiral amine (S)-70 activates the acrolein 131 as electrophile by generating the vinylogous iminium ion A, the indole 171 performs an intermolecular Friedel-Crafts-type reaction. The resulting enamine B acts as nucleophile in the Michael addition of the nitroalkene 140 leading to the iminium ion D, which upon hydrolysis liberates the catalyst and yields the intermediate aldehyde 173. The latter compound enters in the second cycle by reacting with the iminium ion A, previously formed by the free catalyst. The subsequent intramolecular enamine-mediated aldol reaction of E completes the ring closure generating the intermediate F, which after dehydration and hydrolysis is transformed in the desired indole 172. 

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