Nitro compounds aldol reaction

Other substances possessing an addic methylene group have been incorporated in aldol-type reactions. These materials include ethyl cyanoacetate and ethyl acetoacetate, as well as phenylacetonitrile, benzyl ketones, and aliphatic nitro compounds. The reaction is often run in benzene or toluene solvent, so that the water formed can be continuously removed. Other cocatalysts, besides carboxylic adds, are various ammonium salts, such as ammonium... 

Thus, various kmds of bases are effective in inducing the Henry reaction The choice of base and solvent is not crucial to carry out the Henry reaction of simple nitroalkanes v/ith aldehydes, as summarized in Table 3 1 In general, sterically hindered carbonyl or nitro compounds are less reactive not to give the desired ni tro-aldol products in good yield In such cases, self-condensation of the carbonyl compound is a serious side-reaction Several mochfied procedures for the Henry reaction have been developed... 

The Knoevnagel reaction of 6-methoxytetralc nediamine followed by the nitro-aldol reach allylic nitro compounds Subsequent group Base catalyzed cyclizadon gives the I by radical denitration fsee Section 7 2 ... 

The addition reaction of enolates and enols with carbonyl compounds is of broad scope and of great synthetic importance. Essentially all of the stabilized carbanions mentioned in Section 1.1 are capable of adding to carbonyl groups, in what is known as the generalized aldol reaction. Enolates of aldehydes, ketones, esters, and amides, the carbanions of nitriles and nitro compounds, as well as phosphoms- and sulfur-stabilized carbanions and ylides undergo this reaction. In the next section we emphasize the fundamental regiochemical and stereochemical aspects of the reactions of ketones and aldehydes. 

Chiu et al. developed the first example of a reductive intramolecular Henry reaction induced by Stryker s reagent (Scheme 30) [53]. The conjugate reduction of keto-nitroalkenes with [Ph3PCuH]6 (150 mol%) triggers spontaneous nitro-aldol reaction at - 40 °C to produce (f-hydroxy nitro compounds in moderate yield. 

The nitro-aldol reaction between nitroalkanes and carbonyl compounds to yield [3-nitro alcohols was discovered in 1895 by Henry.1 Since then, this reaction has been used extensively in many important syntheses. In view of its significance, there are several reviews on the Henry reaction.2-5 These reviews cover synthesis of (3-nitro alcohols and their applications in organic synthesis. The most comprehensive review is Ref. 3, which summarizes the literature before 1970. More recent reviews are Refs. 4 and 5, which summarize literatures on the Henry reaction published until 1990. 

The heterobimetallic asymmetric catalyst, Sm-Li-(/ )-BINOL, catalyzes the nitro-aldol reaction of ot,ot-difluoroaldehydes with nitromethane in a good enantioselective manner, as shown in Eq. 3.78. In general, catalytic asymmetric syntheses of fluorine containing compounds have been rather difficult. The S configuration of the nitro-aldol adduct of Eq. 3.78 shows that the nitronate reacts preferentially on the Si face of aldehydes in the presence of (R)-LLB. In general, (R)-LLB causes attack on the Re face. Thus, enantiotopic face selection for a,a-difluoroaldehydes is opposite to that for nonfluorinated aldehydes. The stereoselectivity for a,a-difluoroaldehydes is identical to that of (3-alkoxyaldehydes, as shown in Scheme 3.19, suggesting that the fluorine atoms at the a-position have a great influence on enantioface selection. 

The diastereoselectivity is observed in the Henry reaction using optical active nitro compounds or a-heteroatom substituted aldehydes. For example, the reaction of O-benzyl-D-lactal-dehyde with methyl 3-nitropropionate in the presence of neutral alumina leads to a mixture of three nitro-aldol products from which D-ribo isomer is isolated by direct crystallization. D-Ribo... 

Jager and coworkers have used the TBAF catalyzed-stereoselective nitro-aldol reaction for the synthesis of cyclic amino alcohols such as iminopolyols, imino sugars, and cyclic amino acids. They are important classes of compounds and have the potential utility as anti-diabetic,... 

Another application of diastereoselective nitro-aldol reactions catalyzed by Bu4NF-3H20 is demonstrated in a simple synthesis of l,4-dideoxy-l,4-imino-D-mannitol (DIM) and amino analogues (Eq. 3.85).134 The nitro-aldol reaction of nitro compounds bearing a-oxy or a-amino function with glyceraldehyde leads to nitrohexitols, which can be reduced to the corresponding amino compounds. Cyclization gives iminopolyols, as shown in Eq. 3.85. 

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). 

Aliphatic nitro compounds are versatile building blocks and intermediates in organic synthesis,14 15 cf. the overview given in the Organic Syntheses preparation of nitroacetaldehyde diethyl acetal.16 For example, Henry and Michael additions, respectively, lead to 1,2- and 1,4-difunctionalized derivatives.14 18 1,3-Difunctional compounds, such as amino alcohols or aldols are accessible from primary nitroalkanes by dehydration/1,3-dipolar nitrile oxide cycloaddition with olefins (Mukaiyama reaction),19 followed by ring cleavage of intermediate isoxazolines by reduction or reduction/hydrolysis.20 21... 

Other groups beside nitro can be reduced in the same step. So the diamine 19, needed for polyamine manufacture, could come from the unsaturated nitro compound 20 that would in turn come from an aldol reaction between the anion of nitromethane 1 and the aldehyde 21. This has a 1,5-diX relationship and acrylonitrile 23 is excellent at conjugate addition (chapter 21) so we can use isobutyraldehyde 24 as a starting material. 

Now the first conjugate addition, an intramolecular reaction between the nitroalkane and unsaturated ester in 92 is followed by conjugate addition of some aryl metal derivative to the unsaturated nitro-compound 93. Both the unsaturated nitro-compound and ester could be made by aldol or Wittig reactions but there is clearly a potential selectivity problem. 

Nitroalkanes having an a-hydrogen atom undergo aldol-type condensation with aldehydes and ketones in the presence of a base to give p-hydroxy nitro compounds or nitroethylene compounds. The reaction is known as the Henry reaction " or nitroaldol reaction. 

Sitro-aldol reaction fl-amino alcohols. Primary nitro compounds form silyl nitronates (1) when treated in sequence with LDA (THF, -78°) and then a silylating reagent. These silyl nitronates undergo aldol condensation with aldehydes in the presence of tetra-n -butylammonium fluoride (there is no reaction in the absence of the catalyst). The products 2 are reduced to /3-amino alcohols (3) in good yield by lithium aluminum hydride (equation 1). Secondary nitroalkanes undergo the same reaction sequence, but the silyl nitronates are less stable and are obtained in only... 

In place of active methylene compounds having a nitrile group, malonates, 13-ketoesters, 1,3-diketones, 1,1-disulfones, nitro compounds, Mel drum acid, and anthrone can also be used as the Michael donors for these ruthenium-catalyzed aldol and Michael reactions. The reaction proceeds well in acetonitrile under mild and neutral conditions (Eq. 9.59) [83]. 

When aliphatic nitro compounds are used instead of aldehydes or ketones, no reduction occurs, and the reaction has been referred to as a Tollens reaction (see 16-43). However, the classical condensation of an aliphatic nitro compound with an aldehyde or ketone is usually called the Henry reaction or the Kamlet reaction, and is essentially a nitro aldol reaction. A variety of conditions have been reported, including the use of a silica catalyst, Mg—A1 hydrotalcite, a tetraalkylam-monium hydroxide,proazaphosphatranes, " or an ionic liquid.A solvent free Henry reaction was reported in which a nitroalkane and an aldehyde were reacted on KOH powder. Potassium phosphate has been used with nitromethane and aryl aldehydes. The Henry reaction has been done using ZnEt2 and 20%... 

Conversion of the nitro compound to the ketone by hydrolysis of the enol derivative is followed J- Froborg and G. Magnusson, J. by an extremely good intramolecular aldol reaction giving the fused five-membered ring. 1978,100, 6728. 

All the steps in the Henry reaction are completely reversible. The first step of the mechanism is the deprotonation of the nitroalkane by the base at the a-position to form the corresponding resonance stabilized anion. Next, an aldol reaction (C-alkylation of the nitroalkane) takes place with the carbonyl compound to form diastereomeric P-nitro alkoxides. Finally the P-nitro alkoxides are protonated to give the expected p-nitro alcohols. 

The conjugate bases of carbonyl compounds, enolates, react with ketones and aldehydes in the aldol reaction. The reaction is usually executed in two stages. First, the enolate is generated, usually by deprotonation of the carbonyl compound at low temperature with a strong base such as LDA, KHMDS, or LiHMDS, but not always. Then the electrophilic carbonyl compound is added to the reaction mixture. Under these conditions, the reaction usually stops at the /3-hydroxycarbonyl stage. The nucleophilic component may be any carbonyl compound, or even a nitrile, a sulfonyl compound, or a nitro compound (honorary members of the carbonyl family). 

The high-pressure technique even promotes the diastereoselective catalytic asymmetric Henry (nitro-aldol) reaction of optically active a-aminoaldehydes with nitro-derivatives, which is one of the most valuable methods for ready access to non-natural 3-amino-2-hydroxy acids and 1,3-diamino-2-hydroxy compounds. ... 

The Henry (or nitro-aldol) reaction is one of the powerful carbon-carbon bond formation reactions frequently used in organic synthesis, providing access (via coupling between a carbonyl compound and an alkylnitro compound) to P-nitroalcohols, useful synthons in organic synthesis (Scheme 16.26) [160]. 

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