Methyl acrylate 3 + 2 cycloaddition reactions

Hydrazones have also been used as azomethine imine precursors to achieve cycloadditions.157 Proto-nated hydrazones act under suitable conditions as quasi-azomethine imines in polar [3+ + 2] cycloadditions. Thus, r.cetaldehyde phenylhydrazone (201) was found to react with styrene in the presence of sulfuric acid in a regiospecific manner to give pyrazolidine (203 Scheme 47) as a diastereomeric mixture.157 The most commonly used azomethine imine has a phenyl group attached to one end of the dipole and hence has a raised HOMO relative to the unsubstituted system. Because the coefficients at the terminal atoms of the dipole are smaller in the LUMO than they are in the HOMO, the phenyl group does not lower the energy of the LUMO as much as it raises the energy of the HOMO. With electron-deficient di-polarophiles like methyl acrylate, the reaction is dipole HOMO-controlled, and mixtures can be expected. In fact, a 1 1 mixture of regioisomers was obtained in the reaction of (201) with acrylonitrile (equation 9).157... 

The last examples included in this section are dipolar cycloadditions with dipolarophiles that are conjugated carbonyls. The first one is the 1,3-dipolar cycloaddition of nitrones with methyl acrylate. The reaction is supposed to be catalyzed by both Au(I) and Au(III) species and experiments that discarded the coordination of gold to the nitrone were performed, which may support a carbonyl-Au mechanism, although it still remains elusive. More recently, the enantioselective cycloaddition of mimchnones to acrylates catalyzed by a chiral catalyst has been developed. 

Vinyl ethers undergo many cycloaddition reactions similar to those which take place with enamines. In general, however, these cycloaddition reactions with vinyl ethers take place less readily than those with enamines. These reactions include cycloaddition of vinyl ethers with ketene (200-205), phenyl isocyanate (206), sulfene (207,208), methyl acrylate (209), diethyl acetylenedicarboxylate (210), and diphenylnitrilimine (183). 

Evans s bis(oxazolinyl)pyridine (pybox) complex 17, which is effective for the Diels-Alder reaction of a-bromoacrolein and methacrolein (Section 2.1), is also a suitable catalyst for the Diels-Alder reaction of acrylate dienophiles [23] (Scheme 1.33). In the presence of 5 mol% of the Cu((l )-pybox)(SbF5)2 catalyst with a benzyl substituent, tert-butyl acrylate reacts with cyclopentadiene to give the adduct in good optical purity (92% ee). Methyl acrylate and phenyl acrylate underwent cycloadditions with lower selectivities. 

The cycloaddition reaction of diazomethane 4 and an olefin, e.g. methyl acrylate 5, leads to a dihydropyrazole derivative 6 ... 

It has been established that alkoxy alkenylcarbene complexes participate as dienophiles in Diels-Alder reactions not only with higher rates but also with better regio- and stereoselectivities than the corresponding esters [95]. This is clearly illustrated in Scheme 51 for the reactions of an unsubstituted vinyl complex with isoprene. This complex reacts to completion at 25 °C in 3 h whereas the cycloaddition reaction of methyl acrylate with isoprene requires 7 months at the same temperature. The rate enhancement observed for this complex is comparable to that for the corresponding aluminium chloride-catalysed reactions of methyl acrylate and isoprene (Scheme 51). 

The reaction of methyl acrylate and acrylonitrile with pentacarbonyl[(iV,iV -di-methylamino)methylene] chromium generates trisubstituted cyclopentanes through a formal [2S+2S+1C] cycloaddition reaction, where two molecules of the olefin and one molecule of the carbene complex have been incorporated into the structure of the cyclopentane [17b] (Scheme 73). The mechanism of this reaction implies a double insertion of two molecules of the olefin into the carbene complex followed by a reductive elimination. 

Good yields and high diastereoselectivities were obtained by using zeolites in combination with Lewis-acid catalyst [21]. Table 4.7 illustrates some examples of Diels-Alder reactions of cyclopentadiene, cyclohexadiene and furan with methyl acrylate. Na-Y and Ce-Y zeolites gave excellent results for the cycloadditions of carbocyclic dienes, and combining these zeolites with anhydrous ZnBr2 further enhanced the endo diastereoselectivity of the reaction. An exception is the cycloaddition of furan that occurred considerably faster and with better yield, in comparison with the classic procedure [22], when performed in the presence of sole zeolites. 

Cycloaddition reactions of (E)-l-acetoxybutadiene (18a) and (E)-l-methoxy-butadiene (18b) with the acrylic and crotonic dienophiles 19 were studied under high pressure conditions [9] (Table 5.1). Whereas the reactions of 18a with acrylic dienophiles regioselectively and stereoselectively afforded only ortho-enJo-adducts 20 in fair to good yields, those with crotonic dienophiles did not work. Similar results were obtained in the reactions with diene 18b. The loss of reactivity of the crotonic dienophiles has been ascribed to the combination of steric and electronic effects due to the methyl group at the )S-carbon of the olefinic double bond. 

The aqueous medium also has beneficial effects on the diastereoselectivity of the Diels-Alder reactions. The endo addition that occurs in the classical cycloadditions of cyclopentadiene with methyl vinyl ketone and methyl acrylate is more favored when the reaction is carried out in aqueous medium than when it is performed in organic solvents (Table 6.4) [2b, c]. 

Benzodiazepin-2-ones are converted efficiently into the 3-amino derivatives by reaction with triisopropylbenzenesulfonyl (trisyl) azide followed by reduction <96TL6685>. Imines from these amines undergo thermal or lithium catalysed cycloaddition to dipolarophiles to yield 3-spiro-pyrrolidine derivatives <96T13455>. Thus, treatment of the imine 50 (R = naphthyl) with LiBr/DBU in the presence of methyl acrylate affords 51 in high yield. 

Scheme 3.7 1,3-dipolar cycloaddition reaction of N-benzyl-C(2-Pyridyl) nitrone and methyl acrylate. 

In 1987, Vaultier and coworkers [27] developed a combination of a [4+2] cycloaddition of a bora-1,3-diene to provide an allylborane, which then reacts with an aldehyde to give a highly functionalized alcohol. The Lallemand group, as well as Hall and colleagues, has recently used this procedure. In an approach for the synthesis of the antifeedant natural product clerodin (4-83), Lallemand and coworkers performed a three-component domino reaction of 4-80, 4-81 and methyl acrylate to give 4-82 (Scheme 4.18) [28]. 

A sequential cycloaddition, tandem cycloreversion-cycloaddition process is more efficient than the direct cycloaddition, especially in case of aliphatic aldehydes, where the corresponding ylides are rather unstable. The cycloreversion strategy lowers the concentration of the free ylide in the reaction mixture and avoids side reactions such as self-condensation of this reactive species. In some cases, this tandem cycloreversion-cycloaddition sequence provides improved chemical yields without any loss of diastereoselectivity. For example, compound 476 treated with methyl fumarate, methyl maleate, and methyl acrylate provides acceptable yields of compounds 477-479 (Scheme 80) <2000S1170, 2002S1885>. 

Jug and co-workers investigated the mechanism of cycloaddition reactions of indolizines to give substituted cycl[3,2,2]azines <1998JPO201>. Intermediates in this reaction are not isolated, giving evidence for a concerted [8+2] cycloaddition, which was consistent with results of previous theoretical calculations <1984CHEC(4)443>. Calculations were performed for a number of substituted ethenes <1998JPO201>. For methyl acrylate, acrylonitrile, and ethene, the concerted [8+2] mechanism seems favored. However, from both ab initio and semi-empirical calculations of transition states they concluded that reaction with nitroethene proceeded via a two-step intermolecular electrophilic addition/cyclization route, and dimethylaminoethene via an unprecedented two-step nucleophilic addition/cyclization mechanism (Equation 1). 

Similarly, in the cycloaddition of cydopentadiene (23) with methyl acrylate (34), described by Gedye, microwave radiation does not alter the endo/exo selectivity and the observed changes can be explained on the basis of the reactions under micro-wave conditions occurring at higher temperatures than those occurring under reflux and under pressure (Scheme 9.8) [49]. 

This regioselectivity is practically not influenced by the nature of subsituent R. 3,5-Disubstituted isoxazolines are the sole or main products in [3 + 2] cycloaddition reactions of nitrile oxides with various monosubstituted ethylenes such as allylbenzene (99), methyl acrylate (105), acrylonitrile (105, 168), vinyl acetate (168) and diethyl vinylphosphonate (169). This is also the case for phenyl vinyl selenide (170), though subsequent oxidation—elimination leads to 3-substituted isoxazoles in a one-pot, two-step transformation. 1,1-Disubstituted ethylenes such as 2-methylene-1 -phenyl-1,3-butanedione, 2-methylene-1,3-diphenyl- 1,3-propa-nedione, 2-methylene-3-oxo-3-phenylpropanoates (171), 2-methylene-1,3-dichlo-ropropane, 2-methylenepropane-l,3-diol (172) and l,l-bis(diethoxyphosphoryl) ethylene (173) give the corresponding 3-R-5,5-disubstituted 4,5-dihydrooxazoles. 

Dipolarophile D6. A complete theoretical study of the 1,3-dipolar cycloaddition reaction of D-glyceraldehyde nitrone (N) to methyl acrylate (MA) has been... 

Chiral nitrones derived from L-valine (62a-c) react with methyl acrylate to afford the corresponding diastereomeric 3,5-disubstituted isoxazolidines (565a-c) to (568a-c). The dibenzyl substituted nitrone (62a) also gave 3,4-disubstituted isoxazolidine (569) in 4% yield. The stereoselectivity was dependent on the steric hindrance of the nitrone and on reaction conditions. High pressure decreased the reaction time of the cycloadditions. The major products were found to have the C-3/C-6 erythro and C-3/C-5 Irons configuration (Scheme 2.262) (771). 

Dipolar cycloaddition reactions between three A-benzyl-C-glycosyl nitrones and methyl acrylate afforded key intermediates for the synthesis of glyco-syl pyrrolidines. It was found that furanosyl nitrones (574) and (575) reacted with methyl acrylate to give mixtures of all possible 3,5-disubstituted isoxazolidines (577) and (578). On the other hand, the reaction with pyranosyl nitrone (576) was much more selective and cycloaddition at ambient temperatures afforded only one of the possible Re-endo adducts (579a). The obtained isoxazolidines were transformed into the corresponding (V-benzyl-3-hydroxy-2-pyrrolidinones (580—582) on treatment with Zn in acetic acid (Scheme 2.264) (773). 

In this approach, the SENA skeleton is assembled from nitroalkene (42) and nucleophile 56.With the exception of two examples (entries 1 and 2 in Table 3.2), the reaction does not stop at SENA 51, which either undergoes intramolecular cyclization through [3 + 2]-cycloaddition to give fused heterocycles (as a rule after elimination of trimethylsilanol) (198-200) or is involved in [3+ 2]-cycloaddition with specially added methyl vinyl ketone or methyl acrylate to form (after elimination of silanol) substituted isoxazolines in rather high yields (201). 

On the basis of available experimental data, it is impossible to choose a definite pathway of elimination of silanol. However, study of silylation of methyl P -nitropropionate (411) with BSA in the presence of trapping agents rigorously proved that silyl nitronate D is initially formed. This compound can be detected in the [3 + 2]-cycloaddition reaction with methyl acrylate product (413). If silylation of AN (411) is performed in the presence of ethyl vinyl ether, a-nitrosoalkene E can be successfully trapped in as heterodiene a Diels-Alder reaction. Dihydroox-azine (414) is formed, and its silylation affords isolable product (415). 

If X = AcO, intermediate SENA can be trapped by methyl acrylate in the [3+ 2]-cycloaddition reaction (isoxazolidine (416)). If X=C1, attempts to trap silyl nitronate failed however, nitroethylene was detected in a Diels-Alder reaction. By contrast, SENAs, in which X=OSiMe3 or NHPh, are quite stable. Therefore, the substituents X can be arranged in the following series of increasing elimination rates of SiX Cl > AcO > > PhNH. 

In reactions in which methyl acrylate is used as the dienophile (Scheme 6.33), cycloadditions occur with lower levels of enantioselection (23% ee, as compared to 53 % observed for acrolein), but with significantly higher degrees of diastereoselectivity (17 1, endo-.exo). Improved levels of endo selectivity are observed in the case of the methyl ester (Scheme 6.33) this is perhaps because, at least in part, the dienophile p-system is oriented towards the t-butoxy ligand, where the steric influence of the bulky substituent is expected to be more pronounced. As before, formation of the endo isomer may occur to a greater extent, since the transition structure that leads to the exo isomer would involve energetically unfavorable interactions between the diene... 

Epoxidation of amidoallenes with dimethyldioxirane leads to allene oxides as reactive intermediates which can be trapped with dienes in a [4+ 3]-cycloaddition reaction. Exposure of a mixture of amidoallene 177 with cydopentadiene to a small excess of dimethyldioxirane at -45 °C produced endo-bicydooctanone 178 in 60% yield (Eq. 13.60) [69]. The allene oxide is electrophilic, since no reaction takes place with methyl acrylate. 

Pasto and colleagues studied the stereochemical features of the [2 + 2] cycloadditions of chiral allenes. The formation of a diradical intermediate in the cycloadditions of enan-tiomerically enriched 1,3-dimethylallene (10) with acrylonitrile (11a) and methyl acrylate (lib) (equation 4) was shown to be irreversible. 1,3-Dimethylallene recovered from the reaction mixture was shown to have the same ee as the starting material. Interestingly,... 

Hawkins and Loren225 reported simple chiral arylalkyldichloroborane catalysts 352 which were effectively used in the cycloadditions of acrylates lib and 350 to cyclopen-tadiene, affording adducts 351a and 351b, respectively (equation 99). A crystal structure of the molecular complex between methyl crotonate and the catalyst allowed the authors to rationalize the outcome of the reaction. One face of methyl crotonate is blocked by tt-tt donor-acceptor interactions, as becomes clear from the structure of complex 353. The cycloadduct of methyl acrylate and cyclopentadiene (5 equivalents) was obtained with 97% ee, using the same catalyst. Three years later, the authors reported that the cycloadduct was obtained with 99.5% ee in the presence of 10 equivalents of cyclopentadiene226. 

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