Nitronates acylation

In summary, reactions of nitronates with acid anhydrides or acyl chlorides give the O-acylated products, and reactions with acyl imidazoles, phenyl esters, acyl nitriles, and enol-lactones gives the C-acylated products, (see Eq. 5.13).25 The C/O selectivity of nitronate acylation by RCOX is qualitatively correlated with strength (pKJ of the acid HX conjugated to the leaving group X .25... 

Most other acylating agents act on salts of either primary or secondary nitroparaffins by O-acylation, giving first the nitronic anhydrides which rearrange to give, eg, nitrosoacyloxy compounds (28). 

Rearrangement involving cleavage of the C—O bond is also observed with the phenyl isocyanate adduct (59). In place of an O-acylated nitrone its product (60) of acyl migration is isolated (67JPR(36)86). 

While pyridine N-oxide does not react with enaniines in the absence of an acylating agent, other nitrone systems have formed adducts (615,616). 

In order to overcome the poor electrophilicity ofimines, nitrones arc used as partners for reaction with iron acyl enolates 428. Benzaldehyde phenylnitrone (5) reacts rapidly with the aluminum-based enolate at —78 C to give a crude /J-hydroxyamino iron acyl 6 (68% yield). Treatment with aqueous titanium trichloride in tetrahydrofuran at room temperature causes a selective reduction of the N—O bond and affords the /1-amino iron acyl 7 with inverse configuration compared to the addition ofimines (99% yield d.r. 11 23). 

Allylation of acyloyl-imidazoles and pyrazoles61 with allyl halide mediated by indium in aqueous media provides a facile regioselective synthesis of P, y-unsaturated ketones (Scheme 11.1), which has been applied to the synthesis of the monoterpene artemesia ketone. The same product can be obtained by indium-mediated allylation of acyl cyanide (Eq. 11.35).62 Samarium, gallium, and bismuth can be used as a mediator for the allylation of nitrones and hydrazones to give homoallylic hydroxylamine and hydrazides in aqueous media in the presence of Bu4NBr (Scheme 11.2).63 The reaction with gallium and bismuth can be increased dramatically under microwave activation. 

Acylation of the nitronate 9-71 leads to the iminium ion 9-72 which, by the addition of an isocyanide, forms the cation 9-73. Following two acyl group migrations, the compound 9-75 is obtained via 9-74. The best results were obtained when allylic nitro derivatives were used, as these can form the corresponding enolate in the presence of NEt3. Aliphatic nitro compounds could also be employed, but in these cases it was necessary to use the more basic DBU. 

Nitronate anions react with (jl-allyl)cobalt complexes prepared from acylation of 1,3-dienes by acetylcobalt tetracarbonyl to produce nitro enones (Eq. 5.50).74... 

Bis(oxazolinyl)pyridine-Ce(IV) triflate complex 78 catalyzed the enantioselective 1,3-DC of acyclic nitrones with a, 3-unsaturated 2-acyl imidazoles. For example, C-phenyl 7V-benzyl nitrone reacted with 77 in the presence of 78 to give the adduct 79 with excellent diastereo-and enantioselectivity. Isoxazolidine 79 was then converted into P -hydroxy-P-amino acid derivatives by hydrogenation of the N-0 bond in the presence of Pd(OH)2/C and cleavage of the 2-acyl imidazole with MeOTf in MeCN <06OL3351>. 

Convincing evidence was found that the majority of acyclic aldo-nitrones exist in the Z-form, by investigating the ASIS-effect (aromatic solvent induced shift effect) (399). However, in some cases, specified by structural factors and solvent, the presence of both isomers has been revealed. Thus, in C -acyl-nitrones the existence of Z -and -isomers was detected. Their ratio appears to be heavily dependant on the solvent polar solvents stabilize Z-isomers and nonpolar, E-isomers (399). A similar situation was observed in a- methoxy-A-tert-butylnitrones. In acetone, the more polar Z-isomer was observed, whereas in chloroform, the less polar E-isomer prevailed. The isomer assignments were made on the basis of the Nuclear Overhauser Effect (NOE) (398). /Z-Isomerization of acylnitrones can occur upon treatment with Lewis acids, such as, MgBr2 (397). Another reason for isomerization is free rotation with respect to the C-N bond in adduct (218) resulting from the reversible addition of MeOH to the C=N bond (Scheme 2.74). The increase of the electron acceptor character of the substituent contributes to the process (135). 

The formation of derivatives of 2,3,6,8-tetraazabicyclo-[3.2.1]3-octene (425) arises from an intramolecular nucleophilic addition to the nitrone group of hydra-zone (424). Compound (424) was prepared by reaction of 2-acyl-3-imidazoline-3-oxides (423) with hydrazine. From the cis- and frans-derivatives (424), exo- and enr/o-isomers (425) were obtained (Scheme 2.197). The reaction of intramolecular cyclization does not occur in cases with monosubstituted hydrazones (316). 

Regio- and stereospecific 1,3-cycloaddition of di-tert-butylated acyl nitrone (548), generated in situ from (547), with Z-2-cyclodecanone and subsequent aromatization is the key step in the synthesis of biomimetic pyridomacrolidin... 

It has been reported that diiron acyl complexes (564) undergo stereo- and regioselective 1,3- cycloadditions with a variety of nitrones (Scheme 2.260). These complexes are then oxidatively converted to synthetically useful thio esters (769). 

Finally, the fourth approach (path d) involves the generation of conjugated nitro olefins C from the starting AN by known methods. The latter are involved in the conjugated [1,4]-addition to give target nitronates. This process is of most importance for the synthesis of six-membered cyclic nitronates (see Section 3.2.1.2.2). This method was also used to prepare a small series of boryl-, silyl-and acyl nitronates (see Sections 3.2.3 and 3.2.4). It is beyond reason to believe that all possibilities of the approach (d) are exhausted by these examples. 

In 1981, it was demonstrated (70) that anions of nitro compounds can be involved in C,C-coupling with allyl acetates at the allylic carbon atom with the use of metal complex catalysis. For many years, this observation did not come to the attention of chemists interested in the synthesis of cyclic nitronates. However, Trost demonstrated (71) that this process can be used in the synthesis of five-membered cyclic nitronates from olefins (18) containing two acyl groups in the different allylic positions (Scheme 3.21). 

The reactions of nitroalkenes (42) with various enols (43b) (vinyl ethers, silyl, and acyl enolates, ketene acetals) have been studied in most detail (110, 111, 125—154). As a mle, these reactions proceed smoothly to give the corresponding nitronates (35f) in yields from high to moderate. As in the reactions with enamines, the formation of compounds (44b) is attributed to the ambident character of the anionic centers in zwitterionic intermediates analogous to those shown in Scheme 3.43. 

Synthesis of Acyl Nitronates The most general approach to the synthesis of acyl nitronates is based on the reactions of anions of the corresponding AN with acyl halides or carboxylic acid anhydrides in the presence of bases. Here, we will not consider a series of studies, where the formation of intermediate O-acyl nitronates was postulated without conclusive proof or by detection of their decomposition products. 

Acyl nitronates (63) derived from primary AN are characterized by two types of such transformations the rearrangement into a-acetoxy aldoximes (219) and elimination of the corresponding carboxylic acids to form nitrile oxides (Scheme 3.63). 

As a rule, acyl nitronates derived from secondary AN are more stable. For example, the reaction of acetic anhydride with the Na salt of 2-nitropropane in the presence of K2CO3 afforded the corresponding acyl nitronate in a yield lower... 

More recently, the synthesis of relatively stable chiral acyl nitronates by the reactions of acetic anhydride and pyridine with secondary nitro sugar derivatives has been documented (221). 

Approximately at the same time, Shevelev and coworkers studied the reactions of trinitromethane and 1,1-dinitroethane salts with RCOC1 (R=Me or Ph) and detected the corresponding acyl nitronates on the basis of decomposition products and by trapping with various E—X reagents (222) (Scheme 3.64). 

There is also evidence that conjugation of the nitronate fragment with jt systems can stabilize acyl nitronates. For example, Perekalin and coworkers (224) isolated a very stable nitronate (63a), which was prepared by acetylation of l,4-dinitrobut-2-ene salts (65) in a mixture with the corresponding C-acylation product (66) (Scheme 3.66), by column chromatography. 

Even more stable acyl nitronates (68) were prepared from conjugated nitro-alkenes (67) (Scheme 3.67) (224). Nitronates (68) were characterized by elemental analysis, mass, and IR spectroscopy. 

However, taking into account the unusually high stability of the resulting acyl nitronates shown in Schemes 3.66 and 3.67, additional data are required to confirm their structures. 

An interesting approach to the synthesis of acyl nitronates was developed by the Japanese research group headed by Yoshikoshi (226-228) (Scheme 3.68). 

Stability of Acyclic Alkyl and Acyl Nitronates A weak point of acyclic alkyl nitronates is their thermal instability because these compounds can be involved in two electrocyclic reactions presented in Scheme 3.72. 

Table 3.6 Physical characteristics of typical acyl nitronates...

Since many of these processes occur through six-membered cyclic transition states, they can be highly stereoselective. However, for these reactions to proceed, not only high steric demands but also good leaving groups X are required. In this respect, silyl and acyl nitronates are a priori most preferable. 

Acyl Nitronates In spite of the fact that acyl nitronates have been known for many years (Jones, Am.Chem.J20, 1 (1898)), the chemistry of these compounds remains poorly developed. This is most probably due to the very low stability of acyl nitronates derived from primary and a-functionalized nitro compounds (for more details, see Section 3.3.1.1). 

For acyl nitronates of the general formula RCH=N(0)OAc, two types of rearrangements were suggested (Scheme 3.102), which are associated, respectively, with 1,2-migrations of the N-oxide oxygen atom (223) or the OAc fragment (219). 

The chemistry of acyl nitronates derived from secondary AN has received much more attention. Yoshikoshi and coworkers (226-228) developed a reliable procedure for the synthesis of these derivatives from readily available precursors (ketones and a-nitroalkenes), they demonstrated that the resulting acyl nitronates (123) are convenient reagents for the preparation of various heterocyclic and acyclic derivatives (226) (Scheme 3.104). 

For example, the reaction of nitronates (123) with a zinc copper pair in ethanol followed by treatment of the intermediate with aqueous ammonium chloride a to give an equilibrium mixture of ketoximes (124) and their cyclic esters 125. Heating of this mixture b affords pyocoles (126). Successive treatment of nitronates (123) with boron trifluoride etherate and water c affords 1,4-diketones (127). Catalytic hydrogenation of acyl nitronates (123) over platinum dioxide d or 5% rhodium on aluminum oxide e gives a-hydroxypyrrolidines (128) or pyrrolidines 129, respectively. Finally, smooth dehydration of a-hydroxypyrrolidines (128) into pyrrolines (130f) can be performed. 

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