Henry reaction alcohols

When the nitroalkene 125 was subjected to the three-step procedure of Michael addition of propargyl alcohol, Henry reaction, and intramolecular radical cyclization, the Incyclic structure 126 was obtained,... 

The nitro-dldolredcdon between nitrodlkdnes and carbonyl compounds to yieldfi-nitro alcohols was discovered in 1895 by Henry. Since dien, diis reaction has been used extensively in many important syndieses. In view of its significance, diere are several reviews on die Henry reaction." These reviews cover syndiesis of fi-nitro alcohols and dieir 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 synthedc ndlity of the Henry reaction is shovm in Scheme 3.1, where fi-nitro alcohols are converted into fi-amino alcohols, amino sugars, ketones and other important compounds. 

The basc-eatalyzcd addition of nilroalkancs to carbonyl compounds is a reversible reaction and proceeds under thermodynamic control. Thus low (R, R )/(R, S ) selectivities arc observed in the classical Henry reaction which leads to the silylated x-nitro alcohols 2. 

The nitroaldol reaction or Henry reaction is a powerful and highly versatile carbon-carbon bond-forming reaction, allowing a plethora of key molecular frameworks, such as p-hydroxynitroalkanes, 1,2-amino alcohols or a-hydroxy carboxylic acids to be synthesised in a straightforward manner. Therefore, the development of practical catalytic asymmetric versions of this reaction is still largely desirable. The first catalytic asymmetric nitroaldol reaction was reported in 1992, " but despite its long history, relatively few chiral ligands have... 

Scheme 10.32 Cu-catalysed Henry reactions with thiolated amino alcohol ligands.

In general, the Henry reaction gives a mixture of diastereomers and enantiomers. The lack of selectivity is due to the reversibility of the reaction and the easy epimerization at the nitro-substituted carbon atom. Existing reviews have hardly mentioned the stereochemistry of the Henry reaction. Recently, Shibasaki has found that the modification of the Henry reaction can control the stereochemistry to give (3-nitro alcohols with high diastereo- and enantio-selectivity.6 In Section 3.3, the progress of the stereoselective Henry reaction and its application to biologically active compounds are discussed. 

The 3-nitro alcohols are generally obtained in good yield by the reaction of aldehydes with nitroalkanes in the presence of a catalytic amount of base. When aryl aldehydes are used, the (3-nitro alcohols formed may undergo elimination of water to give aryl nitroalkenes. Such side reactions are not always disadvantageous, for nitroalkenes are sometimes the ultimate target for the Henry reaction. The choice of reaction conditions is important to stop the reaction at the stage of 3-nitro alcohols in aromatic cases. 

Table 3.1. Preparation of p-nitro alcohol by the Henry reaction...

A more effective catalyst for the Henry reaction is a polymer-supported base such as amberlyst A-21. Various P-nitro alcohols can he obtained with the help of amberlyst with or without solvent (Eq. 3.14).25 A recent report claims that amberlite IRA-420 (OH-form) or DOWEX-1 (OH-form) is more effective for the Henry reaction than amberlyst A-21.26 Poly-... 

Nitro alcohols prepared by the Henry reaction are important precursors for (3-amino alcohols. The reduction of the nitro group to the amino function is commonly carried out by hydrogenation in the presence of Raney Ni in EtOH or Pd/C in THF and MeOH (see Section 4.2). The conversion into 3-amino alcohols is also described in the Sections 3.2.5 and 3.3. 

P-Nitro alcohols can be hydrogenated to the corresponding amino alcohols with retention of configuration the stereoselective Henry reaction is a useful tool in the elaboration of pharmacologically important P-amino alcohol derivatives including chloramphenicol, ephedrine, norephedrine, and others. Some important P-amino alcohols are listed in Scheme 3.11.107... 

In general, the Henry reaction proceeds in a non-selective way to give a mixture of anti (erythro) and syn (threo) isomers. Ab initio calculations on the Henry reaction suggest that free nitronate anions (not influenced by cations) react with aldehydes via transition states in which the nitro and carbonyl dipoles are antiperiplanar to each other. This kind of reaction yields anti-nitro alcohols. The Henry reaction between lithium nitronates and aldehydes is predicted to occur via cyclic transition states yielding syn-nitro alcohols as major products (Eq. 3.64).108... 

They react with a wide range of aliphatic and aromatic aldehydes in the presence of catalytic amounts of tetrabutylammonium fluoride (TBAF) to give the trialkylsilyl ethers of P-nitro alcohols with high anti-selectivity (98%). The diastereoselective Henry reaction is summarized in Table 3.2. The products are reduced to P-amino alcohols using Raney Ni-H2 with retention of the configuration of P-nitro alcohols (Scheme 3.12). 

Allylic nitro compounds undergo [2.3]sigmatropic rearrangement to afford rearranged alcohols, as shown in Eq. 7.4346 and Eq. 7.44 47 Because the allylic nitro compounds used in these reactions are readily prepared either by the Henry reaction or the Michael addition, these reactions may be useful in organic synthesis. 

The Henry reaction of nitroalkanes followed by denitration is a good method for the preparation of alcohols. This methodology has been applied in carbohydrate chemistry. For... 

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. 

The classical Henry reaction conditions (base catalyzed addition) have some drawbacks sometimes the nitro alcohols are obtained in low yields and diastereoselectivities are not always high. To improve these results, a number of modifications were introduced. One of them is the Seebach s silyl nitronate method,25 that involves a reaction between an aldehyde with a silyl nitronate prepared by metalation of the corresponding nitro alkane with LDA, followed by reaction of the resulting nitronate with tert-butyldimethylsilyl chloride.26... 

The Henry reaction of nitro sugars and sugar aldehydes is a powerful tool for the formation of C-glycosydic bonds. A recent example is the preparation of disaccharide precursor 60 stated in Scheme 21.45 It involves a Henry reaction of nitro sugar 58 and aldehyde 59 in acetonitrile in the presence of catalytic potassium fluoride, to give nitro alcohol 60, a precursor of the corresponding C-disaccharide. 

For example, the 0,C-trisaccharide 153 was obtained by a Henry reaction of nitro disaccharide 151 and sugar aldehyde 150 followed by the dehydration of (3-nitro alcohol 152 and reduction of the resulting nitroolefin, to give nitro sugar 153. Finally, a radical elimination of the nitro group afforded the target 154 (Scheme 47).105... 

Polynitroaliphatic alcohols are invaluable intermediates for the synthesis of energetic materials (see Section 1.11). The most important route to /i-nitroalcohols is via the Henry reaction where a mixture of the aldehyde and nitroalkane is treated with a catalytic amount of base, or the nitronate salt of the nitroalkane is used directly, in which case, on reaction completion, the reaction mixture is acidified with a weak acid. Reactions are reversible and in the presence of base the salt of the nitroalkane and the free aldehyde are reformed. This reverse reaction is known as demethylolation if formaldehyde is formed. 

The nitroaldol (Henry) reaction constitutes a powerful C-C bond-forming process in organic chemistry, providing efficient access to valuable functionalized organic compounds such as 1,2-amino-alcohols, a-hydroxy-carboxylic acids and 3-hydroxy-nitroalkanes [215, 216]. 

Reactions where NLE have been discovered include Sharpless asymmetric epoxi-dation of allylic alcohols, enantioselective oxidation of sulfides to sulfoxides, Diels-Alder and hetero-Diels-Alder reactions, carbonyl-ene reactions, addition of MesSiCN or organometallics on aldehydes, conjugated additions of organometal-lics on enones, enantioselective hydrogenations, copolymerization, and the Henry reaction. Because of the diversity of the reactions, it is more convenient to classify the examples according to the types of catalyst involved. 

Nitroaldol (Henry) reactions of nitroalkanes and a carbonyl were investigated by Hiemstra [76], Based on their earlier studies with Cinchona alkaloid derived catalysts, they were able to achieve moderate enantioselectivities between aromatic aldehydes and nitromethane. Until then, organocatalyzed nitroaldol reactions displayed poor selectivities. Based on prior reports by Sods [77], an activated thionrea tethered to a Cinchona alkaloid at the quinoline position seemed like a good catalyst candidate. Hiemstra incorporated that same moiety to their catalyst. Snbsequently, catalyst 121 was used in the nitroaldol reaction of aromatic aldehydes to generate P-amino alcohols in high yield and high enantioselectivities (Scheme 27). 

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