Amine Michael reaction

N-Unsubstituted pyrazoles and imidazoles add to unsaturated compounds in Michael reactions, for example acetylenecarboxylic esters and acrylonitrile readily form the expected addition products. Styrene oxide gives rise, for example, to 1-styrylimidazoles (76JCS(P1)545). Benzimidazole reacts with formaldehyde and secondary amines in the Mannich reaction to give 1-aminomethyl products. 

The conjugate addition of a carbon nucleophile to an a./3-unsiituratcd acceptor is known as the Michael reaction. The best Michael reactions take place between unusually acidic donors (/3-keto esters or /3-diketones) and unhindered n,/3-unsaturated acceptors. Knamines, prepared by reaction of a ketone with a disu Instituted amine, are also good Michael donors. 

Coniine, molecular model of. 28 structure of, 294 Conjugate acid, 49 Conjugate base, 49 Conjugate carbonyl addition reaction, 725-729 amines and, 727 enamines and, 897-898 Gilman reagents and, 728-729 mechanism of, 725-726 Michael reactions and, 894-895 water and. 727 Conjugated diene, 482... 

Michael reaction, A1<9) octalone, 45, 82 N Mono- and N,N disubstitdted UREAS AND THIOUREAS 45, 69 N Monosubstituted thioureas from primary amines and silicon tetra-lsothiocyanate, 45, 69 N Monosubstituted ureas from primary amines and silicon tetraisocyan-ate, 46, 69... 

Scheldt and co-workers have also accessed enolate equivalents from enals to furnish cyclopentanes 236 asymmetrically. Formation of the enolate equivalent from enals 235 with the NHC, followed by an intramolecular Michael reaction and 0-acylation, gives the lactone products 236, which are readily opened by either alcohols or amines to generate functionalised cyclopentane derivatives 237 in excellent ee. 

Amines, thiols, eOH (p. 226), etc., will also add to the 0-carbon atom of 0-unsaturated carbonyl compounds and esters, but the most important reactions of C=C—C=0 systems are in Michael reactions with carbanions reactions in which carbon-carbon bonds are formed. A good example is the synthesis of l,l-dimethylcyclohexan-3,5-dione (dimedone, 100) starting from 2-methylpent-2-ene-4-one (mesityl oxide, 101) and the carbanion 0CH(CO2Et)2 ... 

Anionic domino processes are the most often encountered domino reactions in the chemical literature. The well-known Robinson annulation, double Michael reaction, Pictet-Spengler cyclization, reductive amination, etc., all fall into this category. The primary step in this process is the attack of either an anion (e. g., a carban-ion, an enolate, or an alkoxide) or a pseudo anion as an uncharged nucleophile (e. g., an amine, or an alcohol) onto an electrophilic center. A bond formation takes place with the creation of a new real or pseudo-anionic functionality, which can undergo further transformations. The sequence can then be terminated either by the addition of a proton or by the elimination of an X group. 

Yamamoto s group recently published a highly enantioselective chiral amine-catalyzed domino O-nitroso aldol/Michael reaction of 2-268 and 2-269 (Scheme 2.63) [141]. As products, the formal Diels-Alder adducts 2-271 were obtained with >98% 66, which is probably due to the selective attack of an enamine, temporarily formed from amine 2-270 and enone 2-268, onto the nitroso functionality. 

Reaction of phenyl vinyl ketone with cyclopentanone under thermal conditions resulted in a diastereomeric mixture of 1,5,9-triketones 374 via a double Michael reaction. Treatment of this mixture with ammonium formate in polyethyleneglycol-200 under microwave irradiation conditions led to the very fast and efficient formation of a 2 1 diastereomeric mixture of cyclopental flquinolizidines 375 and 376 <2002T2189>. When this reductive amination-cyclization procedure was carried out starting from the purified /ra r-isomer of 374, the result was identical to that obtained from the cis-trans mixture, showing the operation of thermodynamic control (Scheme 86). 

The direct, stereoselective conversion of alkynes to A-sulfonylazetidin-2-imines 16 by the initial reaction of copper(l) acetylides with sulfonyl azides, followed, in situ, by the formal [2+2] cycloaddition of a postulated A-sulfonylketenimine intermediate with a range of imines has been described <06AG(E)3157>. The synthesis of A-alkylated 2-substituted azetidin-3-ones 17 based on a tandem nucleophilic substitution followed by intramolecular Michael reaction of primary amines with alkyl 5-bromo-4-oxopent-2-enoates has been... 

Michael reaction of enamines of u-alkyl- -keto esters. The chiral lithioen-amine (1), prepared from (S)-valine /-butyl ester, does not react with methyl vinyl ketone or ethyl acrylate unless these Michael acceptors are activated by ClSi(CH3)3... 

A catalytic asymmetric amination reaction has been developed using Cu(2+) catalysts (246). The azodicarboxylate derivative 392 reacts with enolsilanes in the presence of catalyst 269c to provide the adducts in high enantioselectivity, Eq. 213. As observed in the Mukaiyama Michael reactions, alcoholic addends proved competent in increasing the rate of this reaction. Indeed, in the presence of tri-fluoroethanol as additive, the reaction time decreases from 24 to 3 h. 

Similar to the Mukaiyama Michael reaction, the amination is believed to proceed through a hetero-Diels-Alder manifold. The dihydrooxadiazene 397 intermediate is observed by in situ IR spectroscopy and assigned its structure based on a characteristic C=N stretch at 1687 cm-1 (246). This intermediate decomposes in the presence of the alcohol providing the amination adduct. 

It is significant to note that this reaction is highly unusual since the prochiral element resides entirely on the nucleophile. The chiral Lewis acid exerts control of en-antiofacial selectivity by proctor through tight control of the presumed heterocycloaddition transition state, Scheme 27. In effect, extremely high fidelity is necessary to orient the 2n component with respect to the 4ji component coordinated to the chiral Lewis acid. The factors that control the diastereoselectivity in the Mukaiyama Michael reaction of crotonylimides could also control enantioselectivity in the amination reaction. That selectivities on the order of 99% ee are observed in this reaction is testament to the level of control exerted by these catalysts. 

A final example, from the work of Trost (49), represents the only case in which an intramolecular Michael reaction has been catalyzed by a chiral amine. When the achiral cyclohexanone is treated with (- )-quinine and heated in toluene solution, the bicyclic ketone is formed in 83% chemical and 30% enantiomeric yield (eq. [8]). 

From the examples cited above, it is evident that a great deal of research remains to be done on the chiral-amine-catalyzed Michael reaction. All mechanistic proposals have been based solely on knowledge of the absolute configuration of the products, while kinetic data as well as steric factors have not been carefully delineated. Since the research thus far has been restricted entirely to products in which just one chiral center is formed, it is clear that there is no lack of problems to be studied. 

This same picture unfolds when we examine the use of chiral amines in base-catalyzed reactions. Although in several individual cases (91,92) such as epox-idations (84), one Michael reaction (36), and an intramolecular aldol reaction (93), amino acids (11) or polypeptides (84) are better catalysts than quinine, the range of usefulness of quinine appears to warrant the term miracle catalyst. ... 

Michael reactions are base catalyzed and reversible, and so it is common to use either the nitronate salt of the nitroalkane substrate or the nitroalkane in the presence of a catalytic amount of alkali metal hydroxide, alkoxide or amine base. 

In extending this concept to transformations that formally deliver Diels-Alder products, a one-pot three-component Mannich/Michael reaction pathway was developed in which simple cyclic enones, formaldehyde, and aryl amines were treated with catalytic amounts of proline (2) to provide regio-, diastereo-, and enantioselective bicyclic compounds in high yields (Scheme ll.lOb). Multicomponent domino... 

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