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Michael addition iminium

Furthermore, the asymmetric PS reaction has been applied as a key step in the cascade reaction to build up chiral polycyclic compounds. In 2009, Dixon and coworkers [71] developed a chiral phosphoric acid 8f-catalyzed cyclization cascade between tryptamines and enol lactones, leading to the products in good yields and with good to excellent enantioselectivities. This was further extended to the reaction of tryptamines and ketoacids, which were more readily available than enol lactones [72]. By using diarylprolinol silyl ether as catalyst, the other cascade transformations involving Michael addition, iminium formation and PS cyclization were also efficiently realized [73]. [Pg.325]

A hydroamination/N-sulfonyliminium cyclization cascade was carried out enantioselectively with gold and BINOL-phosphoric acid catalysts to generate fused indole 188. The method can also be extended to furnish lactams with up to 93% ee (13OL4330). Polycyclic indoline 189 was prepared via an indium/TFA-catalyzed tandem cycloannulation of P-oxodithioesters with tryptamine in yields up to 92% (130L1974). Dixon and colleagues utilized an enantioselective Michael addition/iminium ion cyclization of trypt-amine-derived ureas in the synthesis of tetracyclic indole 190 (22 examples, up to 78% yield and 96% ee) (130L2946). [Pg.176]

It is assumed that the overall process is initiated by a Michael addition of the 1,3-dicarbonyl compound onto the ci,(5-uri saturated carbonyl derivative. There follows the formation of either an aminal and an iminium intermediate which is followed by the formation of two N.O-acetals. [Pg.113]

Among the catalytic asymmetric alkyne additions to the sp carbon center, such as carbonyl, imines, and iminiums, truly metal-catalyzed alkyne addition to alkenes is rare. By using a PINAP derivative (Figure 5.4), Cu-catalyzed Michael addition... [Pg.135]

The elfectiveness of imidazolidinone of type 11 was confirmed by successful application to a broad range of chemical transformations, including cycloadditions, conjugate additions, Friedel-Crafts alkylations, Mukaiyama-Michael additions, hydrogenations, cyclopropanations, and epoxidations. A summary of these enantio-selective iminium catalyzed processes is provided by reaction subclass. [Pg.321]

The majority of the Michael-type conjugate additions are promoted by amine-based catalysts and proceed via an enamine or iminium intermediate species. Subsequently, Jprgensen et al. [43] explored the aza-Michael addition of hydra-zones to cyclic enones catalyzed by Cinchona alkaloids. Although the reaction proceeds under pyrrolidine catalysis via iminium activation of the enone, and also with NEtj via hydrazone activation, both methods do not confer enantioselectivity to the reaction. Under a Cinchona alkaloid screen, quinine 3 was identified as an effective aza-Michael catalyst to give 92% yield and 1 3.5 er (Scheme 4). [Pg.151]

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... [Pg.314]

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... [Pg.316]

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. [Pg.323]

Accentuation of the p-acceptor of an enone by substitution with an iminium moiety greatly contributes to the facile intramolecular Michael addition involving an enolate. The reactive components are generated from an enollactone and an ynamine [133],... [Pg.115]

The first highly regio-, chemo-, diastereo-, and enantio-selective vinylogous Michael addition of oqa-dicyanoalkenes to oq/S-unsaturated aldehydes employs salts of a,a-diarylprolinol (103) (20 mol%) as organocatalysts. The reaction presumably involves the formation of an iminium species from the aldehyde as the first step of the cascade.153... [Pg.346]

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]. [Pg.64]

Aliphatic amines can be readily oxidized by Pd(II) to imines or iminium salts and hydrido complexes. The latter can transfer hydrogen to alkenes, leading to the formation of alkanes as byproducts of the Heck reaction (last example, Scheme 8.18). Such reactions can be avoided by using alkali carbonates as base instead of aliphatic amines [148]. Treatment of stannanes or organoboron derivatives with electron-deficient alkenes under acidic reaction conditions can also lead to formal products of Michael addition instead of the products of a Heck-type reaction [149, 150] (Scheme8.19). [Pg.295]

MacMillan s catalysts 56a and 61 allowed also the combination of the domino 1,4-hydride addition followed by intramolecular Michael addition [44]. The reaction is chemoselective, as the hydride addition takes place first on the iminium-activated enal. The enamine-product of the reaction is trapped in a rapid intramolecular reaction by the enone, as depicted in Scheme 2.54. The intramolecular trapping is efficient, as no formation of the saturated aldehyde can be observed. The best results were obtained with MacMillan s imidazolidinium salt 61 and Hantzsch ester 62 as hydride source. As was the case in the cyclization reaction, the reaction affords the thermodynamic trans product in high selectivity. This transformation sequence is particularly important in demonstrating that the same catalyst may trigger different reactions via different mechanistic pathways, in the same reaction mixture. [Pg.91]

Hypothesizing that primary amine catalysts, due to their reduced steric requirements, might be suitable for the activation of ketones, we studied various salts of a-amino acid esters. (For pioneering use of primary amine salts in asymmetric iminium catalysis involving aldehyde substrates, see Ishihara and Nakano 2005 Sakakura et al. 2006 for the use of preformed imines of a, 3-unsaturated aldehydes and amino acid esters in diastereoselective Michael additions, see Hashimot et al. 1977.) We have developed a new class of catalytic salts, in which both the cation and the anion are chiral. In particular, valine ester phosphate salt 35 proved to be an active catalyst for the transfer hydrogenation of a variety of a, 3-unsaturated ketones 36 with commercially available Hantzsch ester 11 to give saturated ketones 37 in excellent enantiose-lectivities (Scheme 28 Martin and List 2006). [Pg.33]

The second procedure worth presenting involves the Michael addition of tryptophan ester (22) to pro-pynoate ester (33 R = H) to give (34 R = H), and subsequent acid-induced cyclization via the iminium salt (35 R = H Scheme 19), to afford tetrahydro-P-carboline (36 R = H), which could not be prepared by the simple Pictet-Spengler reaction with malonic hemialdehyde. Again, asymmetric induction can be achieved through the amino acid derived ester function. Extension of this procedure to... [Pg.739]

A number of phosphonate and phosphinate derivatives where the phosphorus atom is directly bonded to non-aromatic cyclic systems have been reported. The synthesis and reactions of a number of compounds with the general structure 103 have been reported. Enantiomerically pure cyclopropanephosphonic acids which are constrained analogues of the GABA antagonist phaclophen, have been prepared by stereocontrolled Michael addition of a-anions derived from chiral chloromethylphosphonamides 104 to a,P-unsaturated esters followed by in situ cyclisation. Other asymmetric syntheses include those of (/ )- and (S)-piper-idin-2-ylphosphonic acid (105) via the addition to trialkyl phosphites to iminium salt equivalents and 4-thiazolidinylphosphonate 106 by catalytic asymmetric hydrophosphonylation of 3-thiazoline. In the latter case both titanium and lanthanoid (which give much better e.e. values) chiral catalysts are used. [Pg.112]

In 2008, Ye and coworkers also developed a new type of multifunctional cinch-onidine-based catalyst, such as 119 having an additional primary amine moiety, for the Michael addition of nitroalkane to cydic enones [32], In the presence of an acid cocatalyst, the primary amine moiety of 119 can act as a Lewis base to activate the Michael acceptor via iminium formation. The catalysts 119a and 119b (5 mol%) provided quite excellent enantioselectivity (up to 98% ee) for the Michael addition of nitroalkanes to cyclohexenone (Scheme 9.40). The observed retardation of the reaction rate and the opposite sense of enantioselectivity obtained with the catalyst 119b indicated the importance of the configuration of the cydohexane... [Pg.273]

Chen and coworkers have reported a new domino Michael-Michael addition reaction between a,a-dicyanoalkene [26] derived from cyclohexanone and benzyli-deneacetone, resulting in a stepwise [4 + 2]-type cycloaddition to afford almost enantiopure bicyclic adduct 15. In contrast to the completely inert function of secondary ammonium salt, a primary amine, 9-amino-9-deoxyepiquinine lo [27], in combination with trifluoroacetic acid, was found to be highly efficient in the activation of the a, 3-unsaturated ketone by tandem iminium-enamine catalysis (Scheme 10.21) [28],... [Pg.313]

Scheme 10.21 Domino Michael-Michael addition by iminium-enamine catalysis. Scheme 10.21 Domino Michael-Michael addition by iminium-enamine catalysis.
See other pages where Michael addition iminium is mentioned: [Pg.107]    [Pg.107]    [Pg.107]    [Pg.107]    [Pg.147]    [Pg.56]    [Pg.46]    [Pg.174]    [Pg.324]    [Pg.327]    [Pg.329]    [Pg.264]    [Pg.1134]    [Pg.7]    [Pg.46]    [Pg.47]    [Pg.80]    [Pg.451]    [Pg.388]    [Pg.87]    [Pg.108]    [Pg.109]    [Pg.36]    [Pg.80]    [Pg.348]    [Pg.278]    [Pg.21]    [Pg.272]    [Pg.265]   
See also in sourсe #XX -- [ Pg.32 , Pg.33 , Pg.34 , Pg.35 , Pg.36 ]



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