Methyl acrylate reduction

The formation of an enamine from an a,a-disubstituted cyclopentanone and its reaction with methyl acrylate was used in a synthesis of clovene (JOS). In a synthetic route to aspidospermine, a cyclic enamine reacted with methyl acrylate to form an imonium salt, which regenerated a new cyclic enamine and allowed a subsequent internal enamine acylation reaction (309,310). The required cyclic enamine could not be obtained in this instance by base isomerization of the allylic amine precursor, but was obtained by mercuric acetate oxidation of its reduction product. Condensation of a dihydronaphthalene carboxylic ester with an enamine has also been reported (311). 

Electrochemical reduction of oxazolinium salts 36 gives the anions 37, which add efficiently to alkyl halides or, in the presence of McsSiCl, to methyl acrylate, methyl vinyl ketone, and acrylonitrile. Simple acid hydrolysis then gives the ketone products 38 and 39, and this method is quite general since the starting salts are readily prepared from carboxylic acids, R C02H (87TL4411). 

Thus, condensation of isoniazide with acetone at the basic nitrogen gives the corresponding Shiff base (8). Catalytic reduction affords the antidepressant, iproniazid (9). Addition of the same basic nitrogen to methyl acrylate by Michael condensation leads to the 3-amino ester (10). This is converted to the amide, nialamide (11), on heating with benzylamine. 

By using this technique acrylamide, acrylonitrile, and methyl acrylate were grafted onto cellulose [20]. In this case, oxidative depolymerization of cellulose also occurs and could yield short-lived intermediates [21]. They [21] reported an electron spin resonance spectroscopy study of the affects of different parameters on the rates of formation and decay of free radicals in microcrystalline cellulose and in purified fibrous cotton cellulose. From the results they obtained, they suggested that ceric ions form a chelate with the cellulose molecule, possibly, through the C2 and C3 hydroxyls of the anhy-droglucose unit. Transfer of electrons from the cellulose molecule to Ce(IV) would follow, leading to its reduction... 

ATBN - amine terminated nitrile rubber X - Flory Huggins interaction parameter CPE - carboxylated polyethylene d - width at half height of the copolymer profile given by Kuhn statistical segment length DMAE - dimethyl amino ethanol r - interfacial tension reduction d - particle size reduction DSC - differential scanning calorimetry EMA - ethylene methyl acrylate copolymer ENR - epoxidized natural rubber EOR - ethylene olefin rubber EPDM - ethylene propylene diene monomer EPM - ethylene propylene monomer rubber EPR - ethylene propylene rubber EPR-g-SA - succinic anhydride grafted ethylene propylene rubber... 

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. 

One interesting example of this type of synthesis has been reported. 6-Phenyl-5//-5,7(6F/)-pyrrolo[3,4-/>]pyrazine (515) underwent electrolytic reduction in the presence of chlorotrimethylsilane to give the (unisolated ) substrate (516) that reacted with methyl acrylate (minimal detail) to afford a mixture of methyl 8-anilino-5-oxo-l,5-dihydro-6-quinoxalinecarboxylate (517) and methyl 5-ani-lino-8-oxo-4,8-dihydro-6-quinoxalinecarboxylate (517a) (17% and 21%, respectively, after separation). 

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. 

Electroorganic synthesis will be covered in section 4.5.4. It is appropriate, however, to make a reference here to the role of u/s in electroorganic processes. Atobe et al. (2000) have reported the effect of u/s in the reduction of acrylonitrile and mixtures of acrylonitrile and methyl acrylate. The selectivity for adiponitrile in the reduction of acrylonitrile was significantly increased under u/s irradiation with a power intensity over the u/s cavitation threshold ( 600 cm ). This favourable influence of u/s can be attributed to the improved mass transfer of acrylonitrile to the electrode interface by the cavitational high-speed jet-stream. 

In 2000, Morken et al. reported the first examples of catalytic asymmetric reductive aldol reactions [21]. Using Rh(BINAP) (5mol%) as catalyst and Et2MeSiH as reductant, the syn-selective (1.7 1) coupling of benzalde-hyde and methyl acrylate produced the diastereomers 35-syn and 35-anti in 91% ee and 88% ee, respectively. Using phenyl acrylate as the nucleophilic partner, a favorable yield of 72% was obtained for the aldol product 36 (Scheme 12). Several aldehydes were examined, which exhibit higher levels of syn-selectivity. Expanding the scope of substrates and acrylates under... 

Riant et al. in 2006 reported an enantioselective reductive aldol reaction of acetophenone and methyl acrylate mediated by PhSiH3 (140 mol %) and catalyzed by a complex generated in situ from [CuF(Ph3P)3]2MeOH (1-3 mol %) and a chiral bisphosphine (1-3 mol %) [57]. According to Mori s... 

Isayama described the coupling reaction of N-methylimine 157 and ethyl crotonate catalyzed by Co(acac)2 and mediated by PhSiH3 to produce Mannich product 158 in 82% with syn-selectivity (Scheme 41) [71]. The (i-laclam 159 was readily synthesized by heating 158. In 2002, Matsuda et al. reported cationic Rh complex [Rh(COD) P(OPh)3 2]OTf (1 mol%) as an active catalyst for the reductive Mannich reaction [72]. N-Tosylaldiminc 160 was coupled with methyl acrylate and Et2MeSiH (200 mol%) at 45 °C to give the b-amino ester 161 in 96% with moderate anti-selectivity 68%. 

Matsuda et al. applied aryl isocyanates as acceptors in reductive couplings to methyl acrylate (Scheme 44) [77]. The cationic Rh complex [Rh(COD) P(OPh)3 2]OTf (1 mol%) and Et2MeSiH (200 mol%) catalyze the reaction in refluxing CH2C12 to provide products of hydrocarbamoylation,... 

Methoxyphenylurea, 31,10,13 Methyl -acetylbenzoate, 32, 81 Methyl acrylate, 30, 65 32, 86 y-Methylallophanate, 32, 62 Methylamine, 30, 60 4 -Methyl-2-aminobenzophenone, 32,12 N-Methylaniline, 30, 62 31,110 N-Methylarylamines, preparation by reductive alkylation, 30, 59, 60 Methylation, of e-caprolactam, 31, 72 of quinacetophenone, with dimethyl sulfate, 31, 91 with methyl iodide, 31, 90 2-Methyl-3,l,4-benzoxaz-4-one, 32, 12 N-Methyl-a-bromo-n-butyranilide, 30, 63... 

In yet another example of an in situ reductive generation of an enolate, fi-amido esters are formed via the reaction of an o, /3-unsaturated ester with a silane in the presence of an isocyanate (Eq. 294).475 The yields obtained using methyl acrylate and methyl crotonate as substrates are generally excellent. 

Scheme 10 Activity reduction in ethylene-methyl acrylate copolymerizations due to the formation of stable chelate 1.30...

The first iridium-catalyzed reductive aldol reaction was reported in 2001.422 Methyl acrylate reacts with certain aldehydes and diethylmethylsilane with high enantio- and diastereoselectivies (Equation (69)). 

Next, we examined the reduction of cation pools in the presence of radical acceptors. The radical that is formed by one-electron reduction of the cation is expected to add to a carbon-carbon double bond. The electrochemical reduction of 2 in the presence of methyl acrylate gave the expected addition product 16 (Scheme 9). A mechanism involving addition of radical 14 to the acrylate to generate radical 17 followed by subsequent reduction of anion 18, which is protonated to give 16 has been suggested. 

Examples are known of hydrocoupling between methyl acrylate and ketones in both protic and aprotic solvents. Reaction in acid solution is thought to involve reduction of the protonated ketoneto a radical, which adds to acrylate. In aprotic solvents, the ketone is more difficult to reduce and electron addition occurs on methyl acrylate. Modest yields of coupling product, dimethylbutanolide, are obtained from acetone and methyl acrylate in dimethylformamide [134]. Better results are obtained by reduction of methyl acrylate and an exces of the carbonyl compound in dimethyIformamide in the presence of chlorotrimethylsilane [135]. This process is useful for the synthesis of butenolides and some examples are given in Table 3.8. 

Kragl 13) pioneered the use of membranes to recycle dendritic catalysts. Initially, he used soluble polymeric catalysts in a CFMR for the enantioselective addition of Et2Zn to benzaldehyde. The ligand a,a-diphenyl-(L)-prolinol was coupled to a copolymer prepared from 2-hydroxyethyl methyl acrylate and octadecyl methyl acrylate (molecular weight 96,000 Da). The polymer was retained with a retention factor > 0.998 when a polyaramide ultrafiltration membrane (Hoechst Nadir UF PA20) was used. The enantioselectivity obtained with the polymer-supported catalyst was lower than that obtained with the monomeric ligand (80% ee vs 97% ee), but the activity of the catalyst was similar to that of the monomeric catalyst. This result is in contrast to observations with catalysts in which the ligand was coupled to an insoluble support, which led to a 20% reduction of the catalytic activity. 

Miki and Hachiken reported a total synthesis of murrayaquinone A (107) using 4-benzyl-l-ferf-butyldimethylsiloxy-4fT-furo[3,4-f>]indole (854) as an indolo-2,3-quinodimethane equivalent for the Diels-Alder reaction with methyl acrylate (624). 4-Benzyl-3,4-dihydro-lfT-furo[3,4-f>]indol-l-one (853), the precursor for the 4H-furo[3,4-f>]indole (854), was prepared in five steps and 30% overall yield starting from dimethyl indole-2,3-dicarboxylate (851). Alkaline hydrolysis of 851 followed by N-benzylation of the dicarboxylic acid with benzyl bromide and sodium hydride in DMF, and treatment of the corresponding l-benzylindole-2,3-dicarboxylic acid with trifluoroacetic anhydride (TFAA) gave the anhydride 852. Reduction of 852 with sodium borohydride, followed by lactonization of the intermediate 2-hydroxy-methylindole-3-carboxylic acid with l-methyl-2-chloropyridinium iodide, led to the lactone 853. The lactone 853 was transformed to 4-benzyl-l-ferf-butyldimethylsiloxy-4H-furo[3,4- 7]indole 854 by a base-induced silylation. Without isolation, the... 

H and Me yields were in the order of 75% while R = OMe or Me, R = Ph or H gave yields >80%. However, =C1 and R = H gave a reduction in yield to 52%, although the reaction still proceeded with complete stereocontrol, with methyl acrylate. The reaction could also be conducted, with complete stereocontrol, in the presence of TiCl(0/-Pr)a and EtaN, as outlined by Grigg, although with a... 

Isoxazolines can be transformed into a,p-enones by several methods from the initial aldol product. This strategy was applied by Barco et al. (285) toward the synthesis of ( )-pyrenophorin (98), a macrocychc fow(enone-lactone) with antifungal properties. The hydroxy group was introduced from the nitrile oxide component (95), while the carboxy function was derived from the acrylate dipo-larophile. Thus, cycloaddition of the optically active nitropentyl acetate 94 to methyl acrylate 95 afforded isoxazoline 96 as a mixture of optically active diastereomers. Reductive hydrolysis using Raney nickel/acetic acid gave p-hydro-xyketone (97), which was subsequently utilized for the synthesis of (—)-pyreno-phorin (98) (Scheme 6.63) (285). 

In an indirect synthesis of four-membered rings, xof-bipyridylnickelacyclopentane (3) was synthesized in 83% yield from bis(cycloocla-1,5-dtene)nickel(0), ,x -bipyridyl and 1,4-dibromobu-tane. The treatment of x.a -bipyridylnickeiacyclopentane (3) with either methyl acrylate or maleic anhydride triggered a reductive elimination process which gave cyclobutane in 57 and 75% yield,... 

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