Dipolarophiles ethyl acrylate

Mangalagiu studied the regioselectivity of the 1,3-dipolar cycloaddition of several pyridazinium methylides 105 to ethyl acrylate, ethyl propiolate, and acrylonitrile. The reaction is HOMO controlled from ylides and only one regioisomer 106 (major isomer as and minor isomer trans) or 107 is formed, namely the one in which the ylide carbanion makes a new bond with the most electrophilic carbon of the 1,3-dipolarophile. In some cases oxidation of 106 to 107 is observed in the reaction mixture in contact with the air (Scheme 23), which can be avoided by working in N2 atmosphere <1996T8853, 1997ACS927, 1999EJO3501>. 

The number of investigations on the enantioselective dipolar cycloaddition of nitronates is still rather limited. In the case of simple alkyl nitronates, the facial selectivity is controlled solely by the steric environment about the two faces of the chiral unit. For example, the reaction of steroid dipolarophile 270 proceeds with the nitronate approaching the Re face of the alkene (Eq. 2.23) (234). The facial selectivity is controlled by the C(19) methyl group, which blocks the Si face of the dipolarophile. Similarly, exposure of 279 to ethyl acrylate at 40 °C for 24 h, provides a single nitroso acetal (Scheme 2.21) (242). The facial selectivity is presumed to arise from steric shielding by the menthol group, however the full stereostructure has not been established. 

The 4-phospha-1,3-butadiene 77/80 serves as an effective synthon for the unknown H-substituted nitrile ylide 79 in [3 + 2]-cycloaddition reactions with a range of electron-poor dipolarophiles (e.g., reaction with DMAD gave 78 in 80% yield). Similar yields were also obtained using methyl propiolate, azodicaboxylic esters, ethyl acrylate, and acrylonitrile (39). The reactant was generated under very mild conditions from 75 as shown below. 

When acrylonitrile or ethyl acrylate was used as the dipolarophile, the azomethine adducts (134) and (135) were formed no thiocarbonyl ylide addition products were isolable in refluxing toluene or xylene, although the isoindoles (136a) and (136b) derived from them were isolated. In contrast to the reactions with fumaronitrile or AT-phenylmaleimide, the azomethine adducts (134) and (135) were still present at higher reaction temperatures — almost 50% in toluene and 4-5% in xylene. Under the same reaction conditions other electron-deficient dipolarophiles like dimethyl fumarate, norbornene, dimethyl maleate, phenyl isocyanate, phenyl isothiocyanate, benzoyl isothiocyanate, p-tosyl isocyanate and diphenylcyclopropenone failed to undergo cycloaddition to thienopyrrole (13), presumably due to steric interactions (77HC(30)317). 

Facile reaction of electron-deficient olefins (dipolarophiles) such as rra/i5-dibenzoylethylene, dimethyl fumarate, furanonitrile, methyl vinyl ketone, ethyl crotonate, ethyl acrylate, ethyl methacrylate, and dimethyl maleate with a mesoionic compound containing a masked thiocarbonyl ylide skeleton gives stable 1 1 cycloadducts. The structure of the cycloadduct was established by its carbonyl absorption in IR spectra and the molecular ion peak [M]. The stereochemistry of the cycloadducts was, however, secured by NMR spectra (74JOC3631) (Scheme 100). 

Both with olefinic dipolarophiles such as A-arylmaleimide, acrylonitrile, or ethyl acrylate and with azirines, stable 1 1 adducts are formed. 

This group " also diverted the usual Diels-Alder cycloaddition pathway of Reissert salts with olefinic esters to a 1,3-dipolar cycloaddition pathway by the addition of triethylamine. Thus treatment of munchnone imine 364 with ethyl acrylate and triethylamine affords the 1,3-dipolar cycloaddition product 366 (30%) as the major product, formed by fragmentation of cycloadduct 365 (Fig. 4.121). The Diels-Alder product (not shown) is formed in 15% yield. Similar products to 366 are formed with dimethyl and diethyl maleate and fumarate. Laude and coworkers " also were able to trap munchnone imine 367 with dipolarophiles to furnish 368 (Fig. 4.122). No Diels-Alder cycloadducts derived from the oxazolium salt were detected. In contrast, fumarate and acrylate esters give only Diels-Alder cycloadducts from the tautomeric oxazolium salt (not shown). However, benzo-quinones and 1,4-naphthoquinone react in a 1,3-dipolar fashion with munchnone imine 372 derived from Reissert compound 369 to give 373 (Scheme 4.11). " Diels-Alder cycloadducts derived from oxazolium salt 371 were not observed. In a... 

A competition experim Qt involving isomunchnone 502 and ethyl acrylate and ethyl vinyl ether afforded both cycloadducts, 505 and 506, although the former predominated (Fig. 4.153)- The authors concluded that similar FMO energetics are operating for both electron-rich and electron-deficient dipolarophiles in their 1,3-dipolar cycloaddition reactions with isomunchnones. 

The influence of electronic factors on the regioselective cycloadditions of nitrones (551), and (583) to (585) to acrylates has been demonstrated by using dipolarophiles with electrophilic substituents at the P-carbon of the alkene in y-bromo a, 3-unsaturated esters and lactones (774) and in ethyl 2-hydroperfluoro-2-alkenoates (586) (775). The reactions of enoates (586) with nitrones are regio-specific and afford isoxazolidines with the CC>2Et and R/, groups in C-4 and C-5... 

In addition, phenylsufonylallene (110), a,(3-unsaturated phosphonates (111), and alkenes with perfluorinated substituents (112) are all useful dipolarophiles. The yields observed with methyl 2-propenoate are significantly lower than those with the corresponding acrylate (entries 7 and 9), because of the additional substituent. On the other hand, the dipolar cycloadditions with either ethyl vinyl ether, 1-hexene, cyclohexene, or a trisubstituted dipolarophile provide the corresponding isoxazolidines in either low yields or not at all (18). 

A large variety of alkenes have been used as dipolarophiles, dienes, allylsilanes, ethyl and methyl acrylates, styrenes, methylene cyclopropanes, vinylketones, polyfunctionalized acrylates, etc., giving... 

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