Nitroalkenes ketone reactions

Acceptor-substituted alkenes that are employed as substrates in Michael additions include a./l-unsaturated ketones (for example, see Figure 10.59), a,/3-unsaturated esters (Figure 10.60), and a,/3-unsaturatcd nitriles (Figure 10.61). The corresponding reaction products are bifunctional compounds with C=0 and/or C=N bonds in positions 1 and 5. Analogous reaction conditions allow Michael additions to vinyl sulfones or nitroalkenes. These reactions lead to sulfones and nitro compounds that carry a C=0 and/or a O N bond at the C4 carbon. 

Nitroalkenes. Pieparation of nitroalkenes by reaction of CH,NO, with aldehydes and ketones is not generally useful, even when catalyzed by primary amines. The reaction of 17-ketosteroids is further complicated by steric hindrance. This reaction can be effected... 

The reaction of conjugated nitroalkenes v/ith a,fi-unsaturated esters, ketones, nitnles, and sulfones is catalyzed by TMG to give the Michael adduct of allyiic nitro compounds fEq. 4.108. -... 

The direct conversion of nitroalkenes into ketones is especially useful for the preparation of arylacetones. They are readily prepared by the condensation of aromatic aldehydes with nitroethane and by the subsequent Nef reaction. "Typical examples are presented in Eq. 6.22 and Eq. 6.23 the product of Eq. 6.23 is used for total synthesis of perylenequinone, calphosdn D, which is a potent inhibitor of protein kmase C. "... 

The stereochemical outcome of the addition of lithium enolates of aldehydes and ketones to nitroalkenes is dependent upon the geometry of the nitroalkene and the enolate anion. The synjanti selectivity in the reaction of the lithium enolates of propanal, eyelopentanone and cyclohexanone with ( )- and (Z)-l-nitropropene has been reported1. 

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. 

Allylic nitro compounds are obtained by the reaction of cyclic ketones with nitromethane in the presence of 1,2-diaminoethane (1 mol%) as catalyst. Because exo-cyclic nitroalkenes are rearranged to the endo-cyc c p,y-nitroalkenes, allylic nitro compounds are selectively produced (Eq. 3.21).31... 

Nitroalkenes prepared from aromatic aldehydes are especially useful for natural product synthesis. For example, the products are directly converted into ketones via the Nef reaction (Section 6.1) or indoles (Section 10.2) via the reduction to phenylethylamines (Section 6.3.2). The application of these transformations are discussed later here, some examples are presented to emphasize their utility. Schemes 3.3 and 3.4 present a synthesis of 5,6-dihydroxyindole66 and asperidophytine indole alkaloid,67 respectively. 

The nitro-aldol approach is impractical for the synthesis of 2,2-disubstituted 1-nitroalkenes due to the reversibility of the reaction when ketones are employed as substrates. Addition-elimination reactions are used for the preparation of such nitroalkenes (see Chapter 4). 

The addition-elimination reaction of hetero-atom-substituted nitroalkenes provides functionalized derivatives of unsaturated nitro compounds.26 Nitroenamines are generally prepared from a-nitro ketones and amines (see Chapter 5 regarding acylation of nitro compounds).26... 

Nitroalkenes react with lithium dianions of carboxylic acids or with hthium enolates at -100 °C, and subsequent treatment of the Michael adducts with aqueous acid gives y-keto acids or esters in a one-pot operation, respectively (Eq. 4.52).66 The sequence of Michael addition to nitroalkenes and Nef reaction (Section 6.1) provides a useful tool for organic synthesis. For example, the addition of carbanions derived from sulfones to nitroalkenes followed by the Nef reaction and elimination of the sulfonyl group gives a,P-unsaturated ketones (Eq. 4.53).67... 

The conversion of primary or secondary nitro compounds into aldehydes or ketones is normally accomplished by use of the Nef reaction, which is one of the most important transformations of nitro compounds. Various methods have been introduced forthis transformation (1) treatment of nitronates with acid, (2) oxidation of nitronates, and (3) reduction of nitroalkenes. Although a comprehensive review is available,3 important procedures and improved methods published after this review are presented in this chapter. The Nef reaction after the nitro-aldol (Henry reaction), Michael addition, or Diels-Alder reaction using nitroalkanes or nitroalkenes has been used extensively in organic synthesis of various substrates, including complicated natural products. Some of them are presented in this chapter other examples are presented in the chapters discussing the Henry reaction (Chapter 3), Michael addition (Chapter 4), and Diels-Alder reaction (Chapter 8). 

The Nef reaction is accelerated by the presence of silicon atom at y-position of nitro functions, as shown in Eq. 6.3. The presence of the y-silicon is essential for such smooth reaction.6 The conversion of 5-nitrobicyclo[2.2.1]heptenes to the corresponding ketones via the Nef reaction is very complicated by the degradation of the product. Thus, (3-trimethylsilyl ketones can be prepared by a one-flask method via the addition of Grignard reagents containing trimethylsilyl groups to nitroalkenes and the subsequent hydrolysis, as shown in Eq. 6.4. 

The conversion of nitroalkanes to ketoximes can be achieved by the reduction with Zn in acetic acid,112 or Fe in acetic acid.113 Nitroalkenes are direcdy reduced into saturated ketoximes by these reagents, which are precursors for ketones (see Section 6.1.4 Nef reaction). Reduction of 3-O-ace-ty lated sugar 1 -nitro-1 -alkenes with Zn in acetic acid gives the corresponding 2,3-unsaturated sugar oximes in high yield, which is a versatile route to 2,3-unsaturated sugar derivatives (Eq. 6.58).114... 

The tandem Michael and cyclopropanation reaction of lithium enolates with nitroalkenes gives tricyclic ketones in one pot, as shown in Eq. 7.42.43... 

The condensation of nitroalkenes with enamino- ketones or enamino-esters (Grob-Camenisch reaction) has been widely used for pyrrole synthesis (Eq. 10.4).6a This process is now carried out with resin-bound enamino-ketones for combinatorial syntheses of pyrroles.6b... 

The cycloaddition, reduction and oxidation reactions emanating from a,/J-unsatu-rated nitroalkenes provide easy access to a vast array of functionalities that include nitroalkanes, N-substituted hydroxylamines, amines, ketones, oximes, and a-substi-tuted oximes and ketones [73-75], Consequently, there are numerous possibilities of using these in situ generated nitroalkenes for the preparation of valuable building blocks and synthetic precursors. 

Individual aspects of nitrile oxide cycloaddition reactions were the subjects of some reviews (161 — 164). These aspects are as follows preparation of 5-hetero-substituted 4-methylene-4,5-dihydroisoxazoles by nitrile oxide cycloadditions to properly chosen dipolarophiles and reactivity of these isoxazolines (161), 1,3-dipolar cycloaddition reactions of isothiazol-3(2//)-one 1,1-dioxides, 3-alkoxy- and 3-(dialkylamino)isothiazole 1,1-dioxides with nitrile oxides (162), preparation of 4,5-dihydroisoxazoles via cycloaddition reactions of nitrile oxides with alkenes and subsequent conversion to a, 3-unsaturated ketones (163), and [2 + 3] cycloaddition reactions of nitroalkenes with aromatic nitrile oxides (164). 

In this approach, the SENA skeleton is assembled from nitroalkene (42) and nucleophile 56.With the exception of two examples (entries 1 and 2 in Table 3.2), the reaction does not stop at SENA 51, which either undergoes intramolecular cyclization through [3 + 2]-cycloaddition to give fused heterocycles (as a rule after elimination of trimethylsilanol) (198-200) or is involved in [3+ 2]-cycloaddition with specially added methyl vinyl ketone or methyl acrylate to form (after elimination of silanol) substituted isoxazolines in rather high yields (201). 

The first example of asymmetric rhodium-catalyzed 1,4-addition of organoboron reagents to enones was described in 1998 by Hayashi and Miyaura. Significant progress has been made in the past few years. This asymmetric addition reaction can be carried out in aqueous solvent for a broad range of substrates, such as a,/ -unsaturated ketones, esters, amides, phosphonates, nitroalkenes. The enantioselectivity is always very high (in most cases over 90% ee). This asymmetric transformation provides the best method for the enantioselective introduction of aryl and alkenyl groups to the / -position of these electron-deficient olefins. 

Besides rhodium catalysts, palladium complex also can catalyze the addition of aryltrialkoxysilanes to a,(3-unsaturated carbonyl compounds (ketones, aldehydes) and nitroalkenes (Scheme 60).146 The addition of equimolar amounts of SbCl3 and tetrabutylammonium fluoride (TBAF) was necessary for this reaction to proceed smoothly. The arylpalladium complex, generated by the transmetallation from a putative hypercoordinate silicon compound, was considered to be the catalytically active species. 

The nucleophilic addition of nitroalkane to carbonyl groups is known as the Henry reaction. The products of the Henry reaction are 2-nitroalkanols,115 which are useful intermediates for nitroalkenes, 2-amino alcohols, and 2-nitro-ketones. However, this does not always give high yields because of the possible O-alkylation in preference to C-alkylation during the Henry reaction. 

Diketones are produced from nitroalkenes and the lithium enolates of ketones. Equation 132 shows the reaction of the enolate of 2-hexanone with 2-nitropropene in the presence of acetic anhydride. The resulting betaine 409, a greenish-blue liquid, is hydrolysed to the diketone by successive treatment with boron trifluoride and water441. 

The first organocatalyzed conjugate addition of a-substituted p-ketoester to a,P-unsaturated ketones was presented by Deng et al. [42] (Scheme 3). Although traditional Cinchona alkaloids were efficient catalysts for conjugate addition of carbon nucleophiles to nitroalkenes and sulfones, replacement of the C(9)-OH with an ester group (Q-7b) showed great improvement in stereoselectivity. The reaction is applicable to a variety of cyclic and acyclic enones (16,18). 

Figure 6.61 Bifunctional hydrogen-bonding pyrrolidine-(thio)ureas utilized for Michael reactions of ketones with nitroalkenes.

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