Dicarboxylate, acetylene

The Diels-Alder Reaction consists in the direct combination of a compound containing a conjugated diene system u ith a reagent which possesses a double or triple bond activated bj suitable adjacent groups. Examples of such reagents are maleic anhydride, p-benzoquinone, acraldehyde and acetylene dicarboxylic esters. Combination always occurs at the 1,4 positions of the diene system ... 

Reactivity of 2-Amino Selenazoles with Ethyl Propiolate (54) and Dimethyl Acetylene Dicarboxylate... 

R SiH and CH2= CHR interact with both PtL and PtL 1. Complexing or chelating ligands such as phosphines and sulfur complexes are exceUent inhibitors, but often form such stable complexes that they act as poisons and prevent cute even at elevated temperatures. Unsaturated organic compounds are preferred, such as acetylenic alcohols, acetylene dicarboxylates, maleates, fumarates, eneynes, and azo compounds (178—189). An alternative concept has been the encapsulation of the platinum catalysts with either cyclodextrin or in thermoplastics or siUcones (190—192). 

Ethyl 3-anilinocrotonate (82) undergoes reaction with dimethyl acetylene-dicarboxylate (57) with the formation of two products, ethyl 5-anilino-3,4-dicarbomethoxy-trfl s,cM-2,4-hexadienoate (83) and ethyl 5-anilino-3,4-dicarbomethoxy-ci5, cw-2,4-hexadienoate (84). 

Aryl amine 31 was found to react readily with acetylene dicarboxylate 32 to yield fumarate 33. Several similar reactions were reported and found to be general. The... 

More importantly, Peet and coworkers reported the reaction of o-nitroaniline 35 with acetylene dicarboxylate 32 to provide fumarate 36. Subsequent cyclization proved difficult under thermal conditions and only a 35% yield of quinolone 37 was isolated. Use of PPA for the cyclization improved the yield of 37 significantly. Using this modification allowed enamino-ester formation with a nitro-group attached to the arylamine. 

In the case of 1,3-diphenylisoindole (29), Diels-Alder addition with maleic anhydride is readily reversible, and the position of equilibrium is found to be markedly dependent on the solvent. In ether, for example, the expected adduet (117) is formed in 72% yield, whereas in aeetonitrile solution the adduet is almost completely dissociated to its components. Similarly, the addition product (118) of maleic anhydride and l,3-diphenyl-2-methjdi.soindole is found to be completely dissociated on warming in methanol. The Diels-Alder products (119 and 120) formed by the addition of dimethyl acetylene-dicarboxylate and benzyne respectively to 1,3-diphcnylisoindole, show no tendency to revert to starting materials. An attempt to extrude carbethoxynitrene by thermal and photochemical methods from (121), prepared from the adduct (120) by treatment with butyl-lithium followed by ethyl chloroform ate, was unsuccessful. 

Reversible interaction of the carbonyl group with an azine lone-pair (cf. 245) should facilitate substitution adjacent to the heteroatom by the anion of a )3-hydroxyethyl ketone. A similar cyclic intermediate (246) is presumably responsible for the cyclization of acetylene dicarboxylic esters with azines. Similar cyclic intermediates... 

A triazolium ylide reacts with acetylene dicarboxylate to produce compound 105 via a pyrrolotriazole (83JCS(P1)1317), and 2-methoxypyridine can react with the tetrazole 106 to give either a triazolopyridine or a pyridopyrazine (93AP (326)427). 

For the ordinary Diels-Alder reaction the dienophile preferentially is of the electron-poor type electron-withdrawing substituents have a rate enhancing effect. Ethylene and simple alkenes are less reactive. Substituent Z in 2 can be e.g. CHO, COR, COOH, COOR, CN, Ar, NO2, halogen, C=C. Good dienophiles are for example maleic anhydride, acrolein, acrylonitrile, dehydrobenzene, tetracya-noethylene (TCNE), acetylene dicarboxylic esters. The diene preferentially is of the electron-rich type thus it should not bear an electron-withdrawing substituent. 

Bamford and Mullik [23] have also investigated a new photoinitiating system composed of Mn2(CO)io or Re2(CO)io with acetylene, acetylene dicarboxylic acid, diethyl fumarate, diethyl maleate, or maleic anhydride. It was concluded that the primary radical responsible... 

Substituted 1-benzoxepins can be obtained by the cycloaddition of activated acetylenes to the benzofuran system. When 2-(Af-mcthylanilino)benzofurans is treated with dimethyl acetylene-dicarboxylate, substituted 1-benzoxepins 1 are obtained in reasonable yield.180,181 This reaction presumably involves a 2a,7b-dihydrocyclobuta[6]bcnzofuran as an intermediate (see Section 4.2).182... 

Iodine azide, generated in situ from an excess of sodium azide and iodine monochloride in acetonitrile, adds to ethyl l//-azepine-l-carboxylate at the C4 — C5 and C2 —C3 positions to yield a 10 1 mixture of the rw-diazidodihydro-l//-azepines 1 and 2, respectively.278 The as stereochemistry of the products is thought to be the result of initial trans addition of the iodine azide followed by an SN2 azido-deiodination. The diazides were isolated and their stereochemistry determined by conversion to their bis-l,3-dipolar cycloadducts with dimethyl acetylene-dicarboxylate. 

A = Acrylonitrile B = Benzoquinone C = Naphthoquinone D = 5,8-Quinolinequinone E = Methyl vinyl ketone F = Dimethyl acetylene dicarboxylate G = Methyl acrylate ... 

Af-Ethylhydrazino)quinoxaline 4-oxide (277, R = Et) and dimethyl acetylene-dicarboxylate gave dimethyl 1-ethyl-l,2-dihydropyridazino[3,4-/ ]quinoxa-line-3,4-dicarboxylate (278, R = Et) (EtOH, reflux, 3 h 77%) the 1-methyl homolog (278, R = Me) (70%) was made similarly. ... 

To avoid problems with the separation of regiomers, dimethyl acetylene dicarboxylate (DMAD) was chosen as a dienophile. The intermolecular Diels-Alder reactions were performed in refluxing dichlorobenzene (bp 132 °C), while the intramolecular reaction of alkyne tethered pyrazinone required a solvent with a higher boiling point (bromobenzene, bp 156 °C). In the case of 3-methoxy or 3-phenyl pyrazinones a mixture of pyridinones and pyridines was obtained, while for the alkyne tethered analogue only the di-hydrofuropyridinone was isolated as the single reaction product. 

Scheme 24 Unusually high reactivity of the triple bond of acetylene dicarboxylate in the bromination...

Triphenylphosphine gives Michael additions to the activated triple bond of acetylene dicarboxylic esters in presence of acidic compounds HY (Scheme 1). The reactions take place easily at room temperature, even at -10°C [1], through formation of intermediate activated vinylic phosphonium salts, which undergo a subsequent Michael addition of HY. The reactions afford various stabilized ylides which can be isolated in high yields or undergo possibly evolution, for example by intramolecular Wittig reaction [2]. 

A related preparation of specific stabilized phosphonium yUdes corresponds to the reaction of triarylphosphines with acetylene dicarboxylic esters in presence of fullerene, which affords a cyclopropanyl-fullerene substituted stabilized phosphonium ylide [9] or the corresponding evolution products [10]. 

Diels-Alder reaction between the Danishefsky triene 1659 and excess dimethyl-acetylene dicarboxylate or methylpropiolate in boiling benzene proceeds, via 1660 and 1661, with loss of trimethylsilanol 4, to give 1662 a and 1662b in 51 and 37% yield, respectively these are transsilylated with methanol to give 1663a and 1663b [40] (Scheme 10.18). 

The reaction of triphenylphosphine with an excess of dimethyl acetylene-dicarboxylate gives not only the phosph(v)ole (32) but also a cyclo-pentenylidenephosphorane (33). 

A. Preparation.—The first reverse Wittig olefin synthesis has been reported. Triphenylphosphine oxide and dicyanoacetylene at 160 °C gave the stable ylide (1 78%) the reaction was reversed at 300 °C. No comparable reaction was observed with a variety of other activated acetylenes but tri phenyl arsine oxide gave the corresponding stable arsoranes with dicyanoacetylene (— 70 °C), methyl propiolate, hexafluorobut-2-yne, dimethyl acetylene dicarboxylate, and ethyl phenylpropiolate (130 °C). 

For the formation of ylides from triphenylphosphine with dimethyl acetylene dicarboxylate and with halonitroalkenes see Chapter 1, Section 2. 

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