Acetylene reaction with enamines

Trimethylsilylketene reacts similarly with carbonyl isocyanates to give [4+2] cycloadducts, which undergo a Diels-Alder reaction with acetylenes or enamines to give 2-pyridones. A theoretical study of the reaction of silylketenes with carbonyl isocyanates and subsequent Diels-Alder reaction with ynamines was conducted recently. ... 

Terminal alkynes with no electron-withdrawing group next to the acetylenic linkage when treated with enamines merely add across the double bonds of the enamines (9i). But electrophilic alkynes (those with an electron-withdrawing group next to the acetylenic linkage) undergo cycloaddition reactions with enamines. 

The formation of adducts of enamines with acidic carbon compounds has been achieved with acetylenes (518) and hydrogen cyanide (509,519,520) (used as the acetone cyanohydrin). In these reactions an initial imonium salt formation can be assumed. The addition of malonic ester to an enamine furnishes the condensation product, also obtained from the parent ketone (350,521). 

Similar reactions with primary and secondary amines result in the formation of 3-aUcylamino- or 3-dialkylamino-l-butyne in 30-80% yield (TON = 3-9) [243-247]. In one example, the TOP could be estimated as 0.2 h" [246]. Enamines were proposed as reaction intermediates. It was later shown that enamines effectively react with terminal aUcynes, including acetylene, to afford the expected aminoalkynes without catalyst or, more rapidly, sometimes exothermically, in the presence of CujCf [248]. Aromatic amines do not react under the same conditions. However, in the presence of organic acids, e.g. acetic acid, 3-arylamino-l-butynes can be isolated in moderate yields (Eq. 4.59) [246, 247, 249]. 

As already mentioned, CAAC ligands can stabilize electron-deficient metal centers such as in cationic gold complexes. Complex 29 catalyzes a very unique reaction of enamines with acetylene, which produces a cumulene and an imine... 

Hendrickson and co-workers have used the reaction of a-amino-ketones with acetylenic esters for synthesizing pyrrole derivatives. Thus, in the reaction of a-aminopropiophenone with DMAD, an intermediate enamine adduct (56) is formed, which ultimately gives rise to the pyrrole 57 in presence of methanolic HCl [Eq. (16)]. Pandit and Huisman have shown the generality of this scheme in the synthesis of polycyclic pyrrole derivatives. 

Several reactions of enamines with acetylenic esters are reported. " In general, [2 + 2] mode of addition leads to cyclobutene intermediates, which undergo ring opening, yielding dienamines. (V,A(-Dimethyl-isobutenylamine (227) with DMAD, for example, gives the dienamine... 

High temperature, pressure, and catalyst are required to achieve addition of ammonia to alkynes. Acetylene and ammonia yield a complex mixture of heterocyclic nitrogen bases.311,312 Ethylideneimines, thought to form through the intermediate enamines, are the products of the reaction of acetylene with primary alkylamines in the presence of catalysts.313... 

Several cycloaddition reactions of 2,5-dihydrothiophene derivatives have been reported. Compounds possessing an enamine system undergo [2 + 2] cycloaddition with acetylene-dicarboxylic ester (Scheme 215) (77AHC(2l)253). Diels-Alder addition of the 2,5-di-hydrothiophene-3-carboxylic ester (557) with butadiene, followed by desulfurization, leads to the trisubstituted cyclohexane (558) (B-74MI31404). 

Louerat, F., Bougrin, K., Loupy, A., Ochoa de Retana, A.M., Pagalday, J. and Palacios, F., Cycloaddition reactions of azidomethyl phosphonate with acetylenes and enamines. Synthesis of triazoles, Heterocycles, 1998, 48, 161-170. 

The reaction of enamines with acetylenic compounds has been the subject of intensive studies. In general, alkyl acetylenedicarboxylates and propiolates undergo initial cycloaddition (Chapter 18) to form cyclobutene derivatives. These cyclobutenes rearrange, in most cases spontaneously, to form products whose structures depend on the starting enamine and on the reaction conditions126-128 (Scheme 45). 

Reaction with enamines and related substances. Brannock el al. found that the enamines derived from acyclic aldehydes and ketones react with dimethyl acetylene-dicarboxylate to give products derived by rearrangement of cyclobutenes initially formed by 1,2-cycloaddition. Thus, N,N-dimethylisobutcnylamine (1) reacts with dimethyl acetylenedicarboxylate in refluxing ether to give dimethyl 2-dimethylamino-methylenc-3-isopropylidencsuceinate (2) in 49 % yield. 

To understand the carbanion mechanism in flavocytochrome 62 it is useful to first consider work carried out on related flavoenzymes. An investigation into o-amino acid oxidase by Walsh et al. 107), revealed that pyruvate was produced as a by-product of the oxidation of )8-chloroalanine to chloropyruvate. This observation was interpreted as evidence for a mechanism in which the initial step was C -H abstraction to form a carbanion intermediate. This intermediate would then be oxidized to form chloropyruvate or would undergo halogen elimination to form an enamine with subsequent ketonization to yield pyruvate. The analogous reaction of lactate oxidase with jS-chlorolactate gave similar results 108) and it was proposed that these flavoenzymes worked by a common mechanism. Further evidence consistent with these proposals was obtained by inactivation studies of flavin oxidases with acetylenic substrates, wherein the carbanion intermediate can lead to an allenic carbanion, which can then form a stable covalent adduct with the flavin group 109). Finally, it was noted that preformed nitroalkane carbanions, such as ethane nitronate, acted as substrates of D-amino acid oxidase 110). Thus three lines of experimental evidence were consistent with a carbanion mechanism in flavoenzymes such as D-amino acid oxidase. 

Enamines of cyclic ketones react with acetylenic esters in an apolar solvent via [2 + 2] cycloaddition leading to cyclobutenes, which normally undergo a sigmatropic ring opening to a 1,3-diene at room temperature - . Nevertheless, cycloadducts have been isolated, such as cyclobutenes 46 and 47, which are stable solids in inert solvents, or cycloadduct 48 obtained by reaction of a -nitro enamine with dimethyl acetylenedi-carboxylate. ... 

Cycloadducts with more than six carbon atoms have been obtained by reaction of enamines of cyclic ketones (e.g. 14) with acetylenic esters such as 189 in apolar solvents. The reaction involves formation of the [2 + 2] cycloadduct 190 followed by thermal electrocyclic reaction of the cw-fused cyclobutene (see Section It has been... 

The thermal and photochemical [4 + 2] cycloadditions of o-quinones with olefinic and acetylenic dienophiles have been extensively reviewed4,5,200 and include their 4tt heterodiene Diels-Alder reactions with olefins,201-204 vinyl ethers,205 enamines,206 selected dienes,207-209 dipheny-lketenimines,210 ketenes,209,210 fulvenes,211 and selected heterocycles including furan,207-209,212 benzofuran,209,212,215 indoles,213 azepines,214 and 1,2-diazepines.214 The tetrahalo-substituted o-quinones, tetrachloro- and tetrabromo-o-quinone, generally participate in heterodiene [4 + 2] cycloadditions at an increased rate over the unsubstituted systems and generally provide higher overall yields of the Diels-Alder products.4,5 With simple olefins, the dienophile geometry is maintained in the course of the thermal [4 4- 2] cycloadditions [Eq. (52)],203,204... 

Early extensive accounts of the 4v participation of a,/)-unsaturated carbonyl compounds in [4 + 2] cycloadditions detailed their reactions with electron-deficient dienophiles including a,/3-unsaturated nitriles, aldehydes, and ketones simple unactivated olefins including allylic alcohols and electron-rich dienophiles including enol ethers, enamines, vinyl carbamates, and vinyl ureas.23-25 31-33 Subsequent efforts have recognized the preferential participation of simple a,/3-unsaturated carbonyl compounds (a,/3-unsaturated aldehydes > ketones > esters) in inverse electron demand [4 + 2] cycloadditions and have further explored their [4 + 2]-cycloaddition reactions with enol ethers,34-48 acetylenic ethers,48 49 ke-tene acetals,36-50 enamines,4151-60-66 ynamines,61-63 ketene aminals,66 and selected simple olefins64-65 (Scheme 7-1). Additional examples may be found in Table 7-1. 

AAAcylimines, e.g., 4, are the most widely recognized and the most extensively investigated hetero-2-azadiene system capable of participation in Diels-Alder reactions, and comprehensive reviews have been published.7,71 In general, substituents X and Y are strongly electron-withdrawing groups and consequently the AAacylimines participate as electron-deficient partners in cycloaddition reactions with electron-rich dienophiles. Diels-Alder reactions of electron-deficient /V-acylimines with vinyl ethers, enamines, olefins, sulfenes, acetylenes, and the carbon-carbon or carbon-oxygen double bond of ketenes have been detailed.57 71 This 47t participation of electron-deficient AAacylimines does complement the ability of many simple AAacylimines to behave as 2ir dienophile components in Diels-Alder reactions with typical electron-rich dienes.6... 

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