Enolates nitroalkanes

The a-arylation of carbonyl compounds (sometimes in enantioselective version) such as ketones,107-115 amides,114 115 lactones,116 azlactones,117 malonates,118 piperidinones,119,120 cyanoesters,121,122 nitriles,125,124 sul-fones, trimethylsilyl enolates, nitroalkanes, esters, amino acids, or acids has been reported using palladium catalysis. The asymmetric vinylation of ketone enolates has been developed with palladium complexes bearing electron-rich chiral monodentate ligands.155... 

The principle classes of acidic compounds are listed in Table 9.1 (Column 3). The distinction between true acids and the weakly acidic pseudo acids (e.g. phenols, enols, nitroalkanes) should be made by observing the nature of the reaction with sodium hydrogen carbonate. To ensure that evolution of carbon dioxide does not go unnoticed in those cases where reaction appears sluggish, add a solution of the compound in methanol carefully to a saturated solution of sodium hydrogen carbonate solution, when a vigorous effervescence at the interface will be observed. 

Chemoselective C-alkylation of the highly acidic and enolic triacetic acid lactone 104 (pAl, = 4.94) and tetronic acid (pA, = 3.76) is possible by use of DBU[68]. No 0-alkylation takes place. The same compound 105 is obtained by the regioslective allylation of copper-protected methyl 3,5-dioxohexano-ate[69]. It is known that base-catalyzed alkylation of nitro compounds affords 0-alkylation products, and the smooth Pd-catalyzed C-allylation of nitroalkanes[38.39], nitroacetate[70], and phenylstilfonylnitromethane[71] is possible. Chemoselective C-allylation of nitroethane (106) or the nitroacetate 107 has been applied to the synthesis of the skeleton of the ergoline alkaloid 108[70]. 

Other compounds with reactive methylene and methyl groups are completely analogous to the nitroalkanes. Compounds with ketonic carbonyl groups are the most important. Their simplest representatives, formaldehyde and acetone, were considered for many decades to be unreactive with diazonium ions until Allan and Podstata (1960) demonstrated that acetone does react. Its reactivity is much lower, however, than that of 2-nitropropane, as seen from the extremely low enolization equilibrium constant of acetone ( E = 0.9 x 10-7, Guthrie and Cullimore, 1979 Guthrie, 1979) and its low CH acidity (pK = 19.1 0.5, Guthrie et al., 1982). ... 

As previously described, in basic conditions the proUne-derived a-sulfonyl amide 141 generates the imine function, which afterwards undergoes addition by a nucleophile, e.g., a nitronate ion see the diastereoselective synthesis of the diamino nitroalkane derivative 172, which is the precursor of the piperazine-2-carboxyUc acid 173, through a Nef reaction [45]. Similarly, the addition of the Uthium enolate of ethyl acetateto the a-sulfonyl amide 174 gave the diamino ester derivative 175, wich was then converted to (-)-l-aminopyrrolizidine 176 (Scheme 27). 

The generation of other heteroq cles from Bfx and Fx has been the subject of exhaustive investigation. The most important transformation of Bfx to other heterocycles has been described by Haddadin and Issidorides, and is known as the Beirut reaction . This reaction involves a condensation between adequate substituted Bfx and alkene-type substructure synthons, particularly enamine and enolate nucleophiles. The Beirut reaction has been employed to prepare quinoxaline 1,4-dioxides [41], phenazine 5,10-dioxides (see Chap. Quinoxahne 1,4-dioxide and Phenazine 5,10-dioxide. Chemistry and Biology ), 1-hydroxybenzimidazole 3-oxides or benzimidazole 1,3-dioxides, when nitroalkanes have been used as enolate-producer reagent [42], and benzo[e] [ 1,2,4]triazine 1,4-dioxides when Bfx reacts with sodium cyan-amide [43-46] (Fig. 4). 

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. 

Because the a-nitroketones are prepared by the acylation of nitroalkanes (see Section 5.2), by the oxidation of (3-nitro alcohols (Section 3.2.3), or by the nitration of enol acetates (Section 2.2.5), denitration of a-nitro ketones provides a useful method for the preparation of ketones (Scheme 7.10). A simple synthesis of cyclopentenone derivatives is shown in Eq. 7.66.76... 

Another important part of Organic 11 is carbonyl chemistry. We look at the basics of the carbonyls in Chapter 9. It s like a family reunion where 1 (John, one of your authors) grew up in North Carolina — everybody is related. You meet aldehydes, ketones, carboxylic acids, acyl chlorides, esters, cimides, and on and on. It s a quick peek, because later we go back and examine many of these in detail. For example, in Chapter 10 you study aldehydes and ketones, along with some of the amines, while in Chapter 11 we introduce you to other carbonyl compounds, enols and enolates, along with nitroalkanes and nitriles. 

A number of species, such as nitroalkanes and nitriles, have an acidic a-hydrogen atom. These compounds can lose a hydrogen ion to produce an anion that is analogous to and reacts like an enolate ion. 

The enolates of other carbonyl compounds can be used in mixed aldol condensations. Extensive use has been made of the enolates of esters, thioesters, amides, nitriles, and nitroalkanes. Scheme 2.4 gives a selection of such reactions. 

Kinetic template effects have been postulated in more typical organic aldol condensations, where metals such as lithium and zinc are likely to coordinate both the enolate or enamine nucleophile and the aldehyde in the transition state. The examples shown in Schemes 58184 and 59185 are illustrative of these reactions and the degree of selectivity obtained. The carboxylation of ketones and nitroalkanes by methyl magnesium carbonate to produce P-keto acids and a-nitro acids respectively provides early examples of similar reactions (Scheme 60).186 187 See also Section 61.1.4.4. 

An unsuccessful attempt has been made to determine the separate electronic and steric effects of alkyl groups on the acidities of hydrocarbons, acetophenone derivatives, and acetone derivatives CH3COCHR1R2 (at either site) by multivariational analyses of experimental and theoretical acidities for each set.15 A thermodynamic cycle has been used to estimate the aqueous phase p/C, = 22.7 1.0 for the methyl group of acetic acid and p/C, = 3.3 1.0 for the corresponding enol.16 Equilibrium acidities have been determined for several nitroaryl substituted nitroalkanes and cyanomethanes, 2,4,6-TNT, and 9-cyanofluorene17 in acetonitrile the influence of common cation BH+ on the electronic spectra of the anions obtained in the presence of strong guanidine bases (B) has been attributed to formation of two types of ion pair.18... 

In cases where there is strong solvation of the carbanion, as for example hydrogen bonding solvation of enolate or nitronate ions in hydroxylic solvents, the intrinsic barrier is increased further because the transition state cannot benefit significantly from this solvation. This is the reason why AG for the deprotonation of nitroalkanes in water is particularly high, i.e., much higher than in dipolar aprotic solvents, see, e.g., entry 11 versus 15 and entry 13 versus 16 in Table 1. These solvation effects will be discussed in more detail below. 

Solvation can have a large effect on intrinsic barriers or intrinsic rate constants, especially hydrogen bonding solvation of nitronate or enolate ions in hydroxylic solvents. Table 4 reports intrinsic rate constants in water and aqueous DMSO for a number of representative examples.19,20,23 25,40,54 56 Entries 1-4 which refer to nitroalkanes show large increases in ogka when... 

Other alkylation reactions are observed in the condensation of cyclo-propanium ions (generated in situ) with ketones 89.92)> enamines6, nitroalkanes 93>, dimethylmalonate 92>, and phenol. 92> Thus, 7-hydroxy-7-pyrrolidinobicyclo[4.1.0]heptane (56) as well as the 7,7-dipyrrolidino derivative (54) react with acetone to give the amino ketone 113. 89> This reaction may be pictured as an addition of the enol form of the ketone to the reactive iminium salt formed from the carbinol amine. In like manner, phenol undergoes ortho substitution with the carbinol amine 114 formed from cyclopropanone and dimethyl amine. 

The Beirut reaction has also been employed to prepare 1-hydroxybenz-imidazole 3-oxides or benzimidazole 1,3-dioxides, when nitroalkanes have been used as enolate-producer reagent [46,47], and benzo[e][l,2,4]triazine 1,4-dioxides when Bfx reacts with sodium cyanamide [48-50]. 

For the quantitative deprotonation of nitroalkanes and active-methylene compounds, there is no need to employ the heavy artillery of lithium amides. Rather, it suffices to employ alkaline earth metal alkoxides or alkaline earth metal hydroxides. In addition, equilibrium reactions between these C,H acids and amines form enough enolate to initiate enolate reactions. 

The enolate A or the nitronate A, respectively, initially adds to the C=0 double bond of the aldehyde or the ketone. The primary product in both cases is an atkoxide, D, which contains a fairly strong C,H acid, namely, of an active-methylene compound or of a nitroalkane, respectively. Hence, intermediate D is protonated at the atkoxide oxygen and the C-fi atom is deprotonated to about the same extent as in the case of the respective starting materials. An OH-substituted enolate C is formed (Figures 13.52 and 13.53), which then undergoes an Elcb elimination, leading to the condensation product B. The Knoevenagel condensation and the aldol condensation have in common that both reactions consist of a sequence of an enolate hydroxy alkylation and an Elcb elimination. 

A Michael addition consists of the addition of the enolate of an active-methylene compound, the anion of a nitroalkane, or a ketone enolate to an acceptor-substituted alkene. Such Michael additions can occur in the presence of catalytic amounts of hydroxide or alkoxide. The mechanism of the Michael addition is shown in Figure 13.67. The addition step of the reaction initially leads to the conjugate base of the reaction product. Protonation subsequently gives the product in its neutral and more stable form. The Michael addition is named after the American chemist Arthur Michael. 

On the other hand, Russell and coworkers have proposed that the substitution and enolate dimerization products, formed in the reactions of 2-substituted-2-nitropropanes (XCMe2N02, X = Cl, N02, / -MePhS02) with nucleophiles that easily lose one electron, such as the mono enolate anions ArC(OLi)=CHR (R = Me, Et, z -Pr, zz-Bu) and t-BuC(OLi)=CH2, can be rationalized on the basis of a free radical chain mechanism involving bimolecular substitution or ET reactions between the enolate anion and the intermediate nitroalkane radical anion62. An S 2 -type mechanism has also been recently suggested for the reaction of pentafluoronitrobenzene with several nucleophiles in aqueous media65. 

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