Iminium ions Michael-additions

Application of an organocatalytic domino Michael addition/intramolecular aldol condensation to the preparation of a series of important heterocycles has recently received much attention [158] with methods being disclosed for the preparation of benzopyrans [159-161], thiochromenes [162-164] and dihydroquinolidines [165, 166]. The reports all use similar conditions and the independent discovery of each of these reactions shows the robust nature of the central concept. A generalised catalytic cycle which defines the principles of these reports is outlined in Fig. 10. Formation of iminium ion 102 is followed by an intermolecular Michael addition of an oxygen, sulfur or nitrogen based nucleophile (103) to give an intermediate... 

J0rgensen has also reported a sequential Michael/Michael/aldol condensation for the three component coupling of malonitrile 111 and a,P-unsaturated aldehydes that involves two iminium ion catalysed Michael additions followed by an intramolecular aldol condensation (Scheme 43) [170]. Using diarylprolinol ether 55 (10 mol%) in a concentrated toluene solution of malonitrile 111 and 3 equivalents of a,P-unsaturated aldehyde the reaction products can be isolated in just 1 8 h (57-89% yield 97-99% ee). The atom efficiency of this three component reaction is remarkable and the ability to prepare these complex products under... 

Barbas, one of the pioneers of enamine catalysis, has incorporated iminium ion intermediates in complex heterodomino reactions. One particularly revealing example that uses the complementary activity of both iminium ion and enamine intermediates is shown in Fig. 12 [188]. Within this intricate catalytic cycle the catalyst, L-proline (58), is actively involved in accelerating two iminium ion catalysed transformations a Knoevenagel condensation and a retro-Michael/Michael addition sequence, resulting in epimerisation. 

Cheap and readily available L-proline has been used numerous times for the intermediate and reversible generation of chiral iminium ions from a,/ -unsaturated carbonyl compounds. For example, Yamaguchi et al. reported in 1993 that the rubidium salt of L-proline catalyzes the addition of di-iso-propyl malonate to the acyclic Michael acceptors 40a-c (Scheme 4.13), with enantiomeric excesses as high as 77% [22], With 2-cycloheptenone and 2-cyclohexenone as substrates ca 90% yield and ee of 59% and 49% were obtained. Later the enantioselectivity of this process was increased to a maximum of 88% ee in the addition of di-tert-butyl malonate to the E-pentenone 40a in the presence of 20 mol% Rb-L-prolinate and 20 mol% CsF [23], Taguchi and Kawara employed the L-proline-derived ammonium salts 41a and... 

The MacMillan catalysts (42, 45), the Jorgensen catalyst (51), and proline itself can promote Michael additions by iminium ion formation with the acceptor enal or enone (A, Scheme 4.22). Secondary amines can also activate a carbonyl donor by enamine formation (Scheme 4.22, B) [36, 37]. 

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). 

Increasing importance has to be attributed to modem tandem (or cascade ) techniques—reaction sequences that can be performed as a one-pot procedure because the first reaction step creates the arrangement of functional groups needed for the second to occur. Schemes 5-7 present some in situ preparations for iminium species, which can then react further with appropriate nucleophiles that are already present (preferably in the same molecule). Most elegantly, in situ generation of iminium ions for tandem processes was performed by a 3,3-sigmatropic (aza-Cope-type) rearrangement (Scheme 5), but also by initial Michael-type addition reactions to vinyl-substituted Atio... 

Complex multi-ring heterocyclic molecules like 136 have been prepared in one pot and under mild conditions by combining a base-catalyzed intermolecular Michael addition reaction of an a,p-unsaturated carbonyl compound and a suitable p-ketoamide pronucleophile with an acid-catalyzed intramolecular N-acyl iminium ion cyclization of the resulting adduct (Scheme 3.40). 

Another newly introduced method generates the iminium ion intermediate by Michael addition of tryp-tamine to an activated alkyne in an acidic medium. Yields of the resulting 1-alkyltetrahydro-P-car-bolines range from good to excellent (Scheme 18). 

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. 

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