Nitroalkenes enamines

The Michael addition of enamines to nitroalkenes proceeds with high Yyn selectivity. The Yyn selectivity is explained by an acyclic synclinal model, in which there is some favorable interaction between the nitro group and the nitrogen lone pair of the enamine group CEq. 4.67i. Both Z- and E-nitrostyrenes afford the same product in over 90% diastereoselecdvity. 

The chiral enamines provide the opportunity for the enandoselecdve Michael addidon to nitroalkenes, as shown in Eq. 4.68, where the ketone is obtained as a single diastereomer with anee>90%. ... 

Node and Fuji have developed a new chiral synthesis of various alkaloids using chiral nitroalkene, fS -( - -3-methyl-3-( 3 -nitrovinyl -o-valerolactone Scheme 8 11 shows a total synthesis of f-i-physosdgmine, a principM alkriloid of the CMabar bean The key nitroalkene is prepared by asymmetric nitroolefinadon of ct-methyl-o-lactone using a chirM enamine fsee... 

Another pyrrole synthesis based on intramolecidar subsdnidon of the nitro group by amino funcdon is presented in Eq. 10.7, in which the Michael addidon of enamines to nitroalkenes is... 

All of these reacdons ptoceed in a similar pathway which involves the Michael type addidons of enamines to nitroalkenes or addidon of nitroalkanes to Imines and cyclizadon. This process has been achieved by solid-phase variadon fScheme 10.2. ... 

A high degree of syn selectivity can be obtained from the addition of enamines to nitroalkenes. In this case, the syn selectivity is largely independent of the geometry of the acceptor, as well as the donor, double bond. Next in terms of selectivity, are the addition of enolates. However, whether one obtains syn or anti selectivity is dependent on both the geometry of the acceptor and the enolate double bond, whereas anti selectivity of a modest and unreliable level is obtained by reaction of enol silyl ethers with nitroalkenes under Lewis acid catalysis. 

High syn selectivity can be obtained from the addition of enamines to nitroalkenes. The reaction of 4-(1-cyclohexenyl)morpholine with ( )-l-bromo-4-(2-nitroethenyl)benzene gives, after acid hydrolysis, exclusively the. ryw-adduct, the relative configuration of which was unequivocally... 

The enantiomeric (2/ ,l S)-nitro ketone was obtained starting from the corresponding enantiomeric (f )-enamine. The stereochemical outcome of these reactions was rationalized by assuming a transition state in which steric interactions between the enamine and the nitroalkene are minimized. 

Scheme 2.23 provides some examples of conjugate addition reactions. Entry 1 illustrates the tendency for reaction to proceed through the more stable enolate. Entries 2 to 5 are typical examples of addition of doubly stabilized enolates to electrophilic alkenes. Entries 6 to 8 are cases of addition of nitroalkanes. Nitroalkanes are comparable in acidity to (i-ketocslcrs (see Table 1.1) and are often excellent nucleophiles for conjugate addition. Note that in Entry 8 fluoride ion is used as the base. Entry 9 is a case of adding a zinc enolate (Reformatsky reagent) to a nitroalkene. Entry 10 shows an enamine as the carbon nucleophile. All of these reactions were done under equilibrating conditions. 

Valentin and coworkers have studied extensively the reaction of enamines with nitroalkenes. The reaction proceeds under mild conditions to give y-nitroketones, which are converted into 1,4-diketones by the Nef reaction (Eq. 4.65).M... 

The reaction of enaminones with nitroalkenes gives a pentalenone system via the Michael addition and aldol reaction (Eq. 4.66).85a Linear a-keto enamines react with nitroalkenes to afford [3 + 2] carbocyclized products.8515... 

The powerful nucleophilicity of enamines allows the addition of nitroalkenes to take place without the presence of Lewis acids. The isolation of secondary products, which can be explained by an initial Michael addition, suggests the participation of zwitterionic intermediates in the mechanism of the reaction (Eq. 8.97).154... 

The preparation of imines, enamines, nitroalkenes and N-sulfonylimines proceeds via the azeotropic removal of water from the intermediate in reactions that are normally catalyzed by p-toluenesulfonic acid, titanium(IV) chloride, or montmorillonite K 10 clay. A Dean-Stark apparatus is traditionally used which requires a large excess of aromatic hydrocarbons such as benzene or toluene for azeotropic water elimination. 

Reactions of nitroalkenes with enamines (43a) were studied in-depth (112-125). These reactions can produce Michael adducts (when nitroalkenes... 

The reactions of nitroalkenes (42) with various enols (43b) (vinyl ethers, silyl, and acyl enolates, ketene acetals) have been studied in most detail (110, 111, 125—154). As a mle, these reactions proceed smoothly to give the corresponding nitronates (35f) in yields from high to moderate. As in the reactions with enamines, the formation of compounds (44b) is attributed to the ambident character of the anionic centers in zwitterionic intermediates analogous to those shown in Scheme 3.43. 

Scheme 6.94 Typical products obtained from the 86-catalyzed Michael addition of aryl methyl-ketone-derived morpholine enamines to various aromatic nitroalkenes and subsequent acidic hydrolysis.

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.

Figure 6.32 Proposed intermediates in the 100-catalyzed Michael addition of ketones to nitroalkenes favored Z-enamine (A) and disfavored E-enamine (B).

Nitroalkenes can also be converted to nitronates by direct combination with an alkene. The nitronate is formed as a result of a [4 + 2] cycloaddition of the electron-deficient nitroalkene, wherein one of the N—O bonds of the nitro group participates as part of the 4n fragment (Eq. 2.19) (89). Because of the electron-deficient nature of the heterodiene, alkenes react in the order electron rich > electroneutral > electron poor. Therefore, the majority of dienophiles investigated are enamines (52,71,199-207) and vinyl ethers (99,208-213). 

The reaction of vinyl ethers and enamines with nitroalkenes is highly regiose-lective, with only the head-to-head adduct observed. The endo approach of the dienophile is preferred in the thermal cycloaddition, however, the mode of approach can be controlled by the choice of the Lewis acid promoter (214). Facial discrimination has been obtained by the use of chiral groups on the both the nitroalkene (215,216) and the enamine (217) or vinyl ether (218), as well as with chiral Lewis acids (46,66,94,219,220). 

Nitroalkenes can serve as the two-carbon fragment of a [3 + 2] cyclization involving enamines as nucleophiles (equation 86) (81LA1534). This reaction is presumably initiated by a conjugate addition of the enamine to the nitroalkene (equation 87). The most attractive formulation of the cyclization is via an intramolecular nucleophilic addition to the aci-form of the nitronate anion. This provides a reduced nitrogen substituent which could be eliminated to complete aromatization. This procedure has provided quite satisfactory yields over a range of structural types. 

Various approaches have been used to prepare pyrroles on insoluble supports (Figure 15.1). These include the condensation of a-halo ketones or nitroalkenes with enamines (Hantzsch pyrrole synthesis) and the decarboxylative condensation of N-acyl a-amino acids with alkynes (Table 15.3). The enamines required for the Hanztsch pyrrole synthesis are obtained by treating support-bound acetoacetamides with primary aliphatic amines. Unfortunately, 3-keto amides other than acetoacetamides are not readily accessible this imposes some limitations on the range of substituents that may be incorporated into the products. Pyrroles have also been prepared by the treatment of polystyrene-bound vinylsulfones with isonitriles such as Tosmic [28] and by the reaction of resin-bound sulfonic esters of a-hydroxy ketones with enamines [29]. 

A pyrrolidine-thiourea organocatalyst (69) facilitates Michael addition of cyclohexanone to both aryl and alkyl nitroalkenes with up to 98% de and ee 202 The bifunctional catalyst (69) can doubly hydrogen bond to the nitro group, leaving the chiral heterocycles positioned for cyclohexyl enamine formation over one face of the alkene. 

The highly enantioselective direct conjugate addition of ketones to nitroalkenes has been promoted by a chiral primary amine-thiourea catalyst (7).31 The observed anti diastereoselectivity has suggested participation of a (Z)-enamine intermediate, given (g) the complementary diastereoselectivity obtained in analogous reactions involving (E)-enamines generated from secondary amine catalysts. 

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