Conjugated nitroolefins

Enamines (e.g. 377) have been shown to react with conjugated nitroolefins 378 to give mainly dihydro-l,2-oxazine A -oxide derivatives 379 as products of kinetic control (sometimes a cyclobutane ring is formed in these reactions see Section II.B). The stability of these heterocycles is largely dependent on the parent enamine and the type of substituent used on the nitro olefin as has been extensively studied by Valentin and coworkers " . Usually they open into the corresponding nitroalkylated enamines 380 (equation 82), in particular in a solution of methanol or deuteriated chloro-and often an equilibrium between the two forms is established. Stable 1,2-oxazine A -oxides have been obtained in the reaction of 2-nitro-l,3-dienes with cyclic enamines . 

Kumaran G, Kulkami GH. Effect of the a-alkyl substituent of conjugated nitroolefins on the formation of cyclic nitronic esters vs. nitrocyclopropanes in their reaction with sulfur ylides. Synthesis 1995 1545-1548. 

The diolefin 1064 gives rise to the isoxazoline 1065, which cannot eliminate tri-methylsilanol 4 [122]. Cychzation of the co-nitroolefin 1066 with trimethylchloro-silane (TCS) 14/triethylamine at -35 °C then HCl-induced removal of trimethyl-silanol 4 leads, in 85% yield, to the dimer 1067, which is converted in two more steps into racemic pyrenophorin 1068 [112] (Scheme 7.39). Further cyclizations of co-nitroolefins [109] to monomeric or dimeric isoxazolines have been described. Conjugated dienes such as butadiene afford a mixture of the mono or bis adducts [115-117]. 

Silylation of Products of Conjugated Addition of Nucleophiles to a-Nitroolefins Nitroalkane anions can be generated not only by deprotonation of nitroalkanes (various modifications of these process were considered above) but also by the conjugated addition of nucleophiles 56 to a-nitroalkenes (42) (Scheme 3.56, Table 3.2). 

The use of strongly stabilized nucleophiles, for example, of [(EtO)2P(0)CHX] Li+ 58a-d, where X is a powerful EWG group, such as Me02C, CN, S02Me, or P(O) (OEt)2, in the conjugated addition with a-nitroolefins gives rise to more complex processes (201b) (Scheme 3.58). 

The enantioselective conjugate addition of dialkylzinc to nitroalkenes using other phosphoramidite,79,79a 83a sulfonamide,84 and binaphthol-based thioether ligands65 has also been studied in the past few years. Particularly noteworthy are the efficient chiral monodentate phosphoramidite ligands (S,R,R)-29 and (A,A)-55 developed by Feringa et al. and Alexakis et al., respectively, for this reaction. (S,R,R)-29 provided excellent enantioselectivities (up to 98% ee) for acyclic nitroalkenes (Scheme 25).80 It also worked well for other nitroolefin substrates such as 3-nitrocoumarin 7068 and methyl 3-nitropropenoate 7185. 

Alexakis et al. showed that under optimized experimental conditions, the enantioselectivity of the Cu-catalyzed conjugate addition of dialkylzinc to cyclic nitroolefin was improved to 95% with both (A,A)-55 and (R,S,S)-29.79,79a Biphenol-based phosphoramidite ligand (S,S)-55 also provided acyclic nitroalkenes adducts with 95-96% ee.42... 

Sewald and Wendisch (170) applied the Feringa system to the conjugate addition of diethylzinc to nitroolefins. Optimal selectivities were found for the acetal-substituted nitroethylene (234) providing adduct 235 in 86% ee and quantitative conversion, Eq. 136. 

Since the trapping of the lactam enolate with electrophiles should not be limited to nitroolefins, extension to conjugate additions to alkenylsulfones, the ring opening of N-tosylaziridines, alkylation with functionalized halides, and silylation with chlorotrimethylsilane were explored. 

Grignard additions, 9, 66 radical addition of zincs, 2, 401 zinc-containing reagent additions, 2, 398 Nitroolefins, enantioselective conjugate additions, 10, 382 (Nitrophenylthio)osmocenes, preparation, 6, 634 (Nitrophenylthio)ruthenocenes, preparation, 6, 634 Nitropyridines, reductive aminocarbonylation, 11, 543 Nitroso aldol reaction... 

Conjugate addition of indole to nitroolefins was carried out by thermal heating in a sealed tube or by addition of indolyl magnesium iodide or microwave irradiation. The results indicated that the microwave technique is most efficient with respect to time and yield (Scheme 26) [97]. 

Aluminum salen complexes have been identified as effective catalysts for asymmetric conjugate addition reactions of indoles [113-115]. The chiral Al(salen)Cl complex 128, which is commercially available, in the presence of additives such as aniline, pyridine and 2,6-lutidine, effectively catalyzed the enantioselective Michael-type addition of indoles to ( )-arylcrolyl ketones [115]. Interestingly, this catalyst system was used for the stereoselective Michael addition of indoles to aromatic nitroolefins in moderate enantiose-lectivity (Scheme 36). The Michael addition product 130 was easily reduced to the optically active tryptamine 131 with lithium aluminum hydride and without racemization during the process. This process provides a valuable protocol for the production of potential biologically active, enantiomerically enriched tryptamine precursors [116]. 

Modified cinchona alkaloids 18 and 19, derived from quinine and quinidine, respectively, were utilized by Deng and co-workers for the catalytic asymmetric Michael additions of malonates to nitroolefins [49]. These catalysts effectively promoted the conjugate additions of methylmalonate to a variety of aromatic (90-99% yield 96-98% ee), heteroaromatic (97-99% yield 96-98% ee) and aliphatic (71-86% yield 94% ee) -substituted nitroolefins (Table 6.7). As the two alkaloids... 

The mechanism of this cyclization involves a conjugate addition of the enamine (100) to the nitroallyl ester (101) to give 102, which on elimination produced 103. The immonium salt 103 undergoes proton transfer to give enamino nitro olefin 104, which cyclizes to an enamine (107) via 105 and 106. Hydrolysis of 107 produces the ketone (108). Depending on the reaction conditions and the structure of the enamine and nitroolefin components employed, intermediates can be isolated (equation 19). 

Other motifs can be eliminated besides sulfonyls in order to introduce an unsaturation. Nitrogen dioxide is a good leaving group in a radical sense and, since nitroolefins are excellent Michael acceptors, it is easy to prepare /3-nitro xanthates by conjugate addition of a xanthate salt. Exposure of these compounds to an equivalent amount of lauroyl peroxide furnishes the corres-... 

Addition of the hydroperoxy anion to the double bond in conjugation is promoted not only by the carbonyl group, but by other electron-attracting groups too. Good yields can be attained from nitroolefins (Eqs. 22 and23). ... 

Nitroalkenes (nitroolefins) are marked by the conjugation of double bonds with those of the nitro group. They show a high intensity absorption band due to JT —transition within the range 220-250 nm. The n — tt band is strongly overlapped there by the intense red shifted absorption band. The... 

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