Regioselective nitrone formation

Another approach toward protection against overoxidation of primary amines is based on a three-step sequence involving selective mono-cyanomethylation of a primary amine such as 133 (equation 90) to cyanomethyl secondary amine 134, regioselective nitrone 135 formation using MCPBA and hydroxylaminolysis " of the resultant nitrones releasing hydroxylamine 136 (equation 90). 

The addition of mesityl nitrile oxide to stable derivatives of a germanethi-one21 and a germaneselone22 is closely related to the addition of nitrones. The reaction is regioselective again, with formation of the germanium-oxygen bond. 

As for the regioselectivity of the nitrone cycloaddition to MCP and its alkyl or aryl derivatives, a tendency of the three-membered ring to end up at the 4-position of the final isoxazolidine ring clearly emerges from the experimental findings. This result is particularly noteworthy if compared to regiospecific formation of the 5,5-disubstituted isoxazolidines in the reactions of nitrones, not... 

Formation of nitrones can be achieved in the first stage of a Krohnke type reaction in which p-n trosodi methy 1 an dine reacts with 2-oo-bromoacetylphenoxathiin in alkaline medium (336). The synthesis of a series of cyclic nitrones of structure (182) has been achieved by regioselective, and by an unusual [3 + 2] cycloaddition of a-nitrosostyrenes (181) to 1,3-diazabuta-l,3-dienes (180) (Scheme 2.64) (337a). Theoretical studies of the substitution effect at the imine nitrogen on the competitive [3 + 2] and [4 + 2] mechanisms of cycloaddition of simple acyclic imines with nitrosoalkenes have been reported (337b). 

Asymmetric syntheses of (3- amino acids result from the addition of chiral enolates (399) to nitrone (400) via A-acyloxyiminium ion formation (642, 643). Regioselective convergence is obtained in the reactions of chiral boron- and titanium- enolates (399a,b), (401), and (402). This methodology was used in preparing four stereoisomers of a-methyl- 3-phenylalanine (403) in enantiomeric pure form (Scheme 2.179) (644). 

Recently, an example of green chemistry in the formation of a nitrone in aqueous medium, using a surfactant, was reported in 1,3-dipolar cycloadditions to ethyl acrylate (776). The control of regioselectivity in this reaction favors the formation of trans -5-substituted isoxazolidines. 

The theoretical interpretation of the results was made (334) in terms of the molecular orbital perturbation theory, in particular, of the FMO theory (CNDO-2 method), using the model of the concerted formation of both new bonds through the cyclic transition state. In this study, the authors provided an explanation for the regioselectivity of the process and obtained a series of comparative reactivities of dipolarophiles (methyl acrylate > styrene), which is in agreement with the experimental data. However, in spite of similar tendencies, the experimental series of comparative reactivities of nitronates (249) toward methyl acrylate (250a) and styrene (250b) are not consistent with the calculated series (see Chart 3.17). This is attributed to the fact that calculation methods are insufficiently correct and the... 

While monosubstituted alkenes usually react with high regioselectivity, it is not true for disubstituted alkenes. Formation of mixtures of type 163 and 164 (equation 105) has been observed in most cases when unsymmetrical alkenes bearing two different substituents possess similar stereoelectronic properties. In general, regioselectivity is controlled by a combination of HOMO-LUMO interactions, steric effects and hydrogen bonding between suitable substituents in both alkene and nitrone molecules . ... 

The 1,3-dipolar cycloaddition of nitrones to alkenes has been shown to be very useful in the field of synthesis of alkaloids. The reaction is normally efficient and the inherent features of carbon-carbon bond formation, oxygen transfer and nitrogen incorporation have been joined by high regioselectivity and even stereoselectivity (79ACR396). The... 

The addition of ZnBi 2 to die tandem 1,3-azaprotio cyclotransfer-cycloaddition of a ketoxime with divinyl ketone results in rate enhancement and the exclusive formation of l-aza-7-oxabicyclo[3.2.1]octan-3-ones.79 The 1,3-dipolar cycloaddition of 1-aza-l-cyclooctene 1-oxide with alkenes produces the corresponding isoxazolidines in high yields with a minimum of polymeric material.80 The cycloaddition of thiophene-2 -carbaldehyde oxime with acetonitrile and methyl acrylate produces the 1,3-dipolar adduct, substituted isoxazolidines, and not the previously reported 4 + 2-adducts.81 Density functional theory and semi-empirical methods have been used to investigate the 3 + 2-cycloaddition of azoxides with alkenes to produce 1,2,3-oxadiazolidines.82 The 3 + 2-cycloaddition of a-nitrosostyrenes (62) with 1,3-diazabuta-l,3-dienes (63) and imines produces functionalized cyclic nitrones (64) regioselectively (Scheme 22).83... 

Nitrone 1 reacts with the parent 3,3,3-trifluoropropenc and with various 3,3,3-trifluoro-propenes which arc substituted in the 1-position with another electron-withdrawing group (ester, nitro or sulfone). Regioselectivity depends on the LUMO coefficient of C2 which is larger for sulfones and nitro compounds. However, with 3,3,3-trifluoropropene the predominant formation of the 5-(trifluoromethyl)isoxazolidine is not explained by orbital coefficients, but by stcric hindrance. 

Nitrone cycloaddition reactions promoted by dichlorotitanium TADDOLate can be improved by using A(-(2-alkenyl)succinimides as the dipolarophiles. Regioselective and enantioselective formation of cyclopentenecarboxylic esters is observed using 8 to catalyze the [3+2]cycloaddition of 2,3-butadienoates with electron-deficient alkenes. ... 

In contrast to the complete regioselectivity observed in the 1,3-dipolar cycloaddition of nitronate 16b and methyl crotonate 42 or methyl cinnamate 44 shown in Scheme 9.14, the [3 -t 2] cycloaddition of yS-nitrostyrene (15a) and nitronate intermediate 16a was not completely regioselective. Regio-isomers 46 and 47 were formed in 83 % yield, as mixtures of diastereomers, in a 7 3 ratio after the high pressure-promoted domino cycloaddition of enol ether 14 with 2 equiv. fi-nitrostyrene (15a) (15 kbar, RT, 18 h, Scheme 9.15). The formation of regio-isomer 46 as major product was rather unexpected, since comparable 1,3-dipolar cycloadditions of nitrones and nitroalkenes [25] showed the opposite regio-isomer to be formed predominantly. This nitroso acetal (46) was converted to )S-lactam (48) via a base-catalyzed rearrangement (Scheme 9.16). This conversion appeared applicable to different hi- and tricyclic nitroso acetals and led to the formation of a novel class of bi- and tricyclic yS-lactams [26]. 

---