Amines acetylene carbonyl reaction

The successful synthesis of 2-thienyl and substituted 2- and 3-thienyl-acetylenes in yields as high as 60-80% opened a wide variety of synthetic applications. Various addition reactions with carbonyl compounds or epoxides could be carried out with ease. Aliphatic as well as aromatic amine addition reactions, or condensation reactions with hydrazine or hydroxylamine could be easily performed. 

All the above-mentioned initiators are very sensitive towards substances with active hydrogen. Care must therefore be taken to exclude acids, water, thiols, amines, and acetylene derivatives. Oxygen, carbon dioxide, carbon monoxide, carbonyl compounds, and alkyl halides which can react with the initiator, also interfere with the reaction. Careful purification and drying of the starting materials and apparatus is, therefore, absolutely essential, especially when dealing with living polymers (see Example 3-19). 

Carbonylations of olefins, acetylenes, halides, alcohols, amines, nitro compounds, etc., promoted by transition metal complexes are very important in both industrial and laboratory organic syntheses. The mechanisms of those reactions have been studied extensively, especially for those associated with commercial processes. " The research... 

Many such activated acyl derivatives have been developed, and the field has been reviewed [7-9]. The most commonly used irreversible acyl donors are various types of vinyl esters. During the acylation of the enzyme, vinyl alcohols are liberated, which rapidly tautomerize to non-nucleophilic carbonyl compounds (Scheme 4.5). The acyl-enzyme then reacts with the racemic nucleophile (e.g., an alcohol or amine). Many vinyl esters and isopropenyl acetate are commercially available, and others can be made from vinyl and isopropenyl acetate by Lewis acid- or palladium-catalyzed reactions with acids [10-12] or from transition metal-catalyzed additions to acetylenes [13-15]. If ethoxyacetylene is used in such reactions, R1 in the resulting acyl donor will be OEt (Scheme 4.5), and hence the end product from the acyl donor leaving group will be the innocuous ethyl acetate [16]. Other frequently used acylation agents that act as more or less irreversible acyl donors are the easily prepared 2,2,2-trifluoro- and 2,2,2-trichloro-ethyl esters [17-23]. Less frequently used are oxime esters and cyanomethyl ester [7]. S-ethyl thioesters such as the thiooctanoate has also been used, and here the ethanethiol formed is allowed to evaporate to displace the equilibrium [24, 25]. Some anhydrides can also serve as irreversible acyl donors. 

Stable, isolable metallacycles are also obtained from reaction of complexes that serve as sources of the CpCo fragment (e.g. CpCo(PPh3)2) and alkynes. Upon carbonylation diese typically give high yields of cobalt-complexed cyclopentadienones. Direct reaction of CpCo(CO)2 with alkynes is similarly useful. The cycloaddition of di(t-butoxy)acetylene upon photolysis with CpCo(CO)2 is an example (Scheme 5). In all these systems the final complexes lack coordinated CO, and therefore amine oxides are not suitable reagents for liberating the stable cyclopentadienones. Tetra(t-butoxy)cyclopentadienone is accessible on a preparative scale via controlled electrochemical oxidation. Other oxidants such as Cr have been used as well in other systems. 

Many ring-fused imidazole derivatives have been synthesized by various methods. Domino Michael addition retro-ene reaction of 2-alkoxyiminoimidazolidines and acetylene carboxylates provided a synthesis of 2,3-dihydroimidazo[l,2-a]pyrimidin-5-(l//)-ones <05T5303>. A single step synthesis of 3,5-dialkyl-9-nitroimidazo[l,2-c]quinazolin-2(3//)-ones from simple carbonyl compounds, primary amines or amino acid methyl esters and 2-azido-5-nitrobenzonitrile has been published <05TL5778>. Diels-Alder reaction of azadienes and benzimidazole-4,7-diones afforded imidazo[4,5-g ]quinoline-4,9-dione derivatives <05EJ01903>. Reaction between isocyanides and dialkyl acetylenedicarboxylates in the presence of 4,5-diphenyl-l,3-dihydro-2//-imidazol-2-one provided a one-pot synthesis of 5//-imidazo[2,l-ft][l,3]oxazine derivatives <05T2645>. Microwave irradiation was employed in the synthesis of 1-ary 1-3-acetyl-1,4,5,6-... 

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. 

General experimental details are as follows.697b It is usual first to mix the carbonyl component with the amine, which is presented as, e.g., hydrochloride or acetate. An appropriate hydrogen ion concentration must be maintained. For the preparation of aminoalkyl compounds that are liable to hydrolysis it is recommended that the water produced be removed by a drying agent or by azeotropic distillation. Dioxan is a suitable solvent, but it is often recommended that acetic acid be added to it. Ketones react better in alcohol with paraformaldehyde. Copper chloride or iron chloride is said to be a useful addition in reactions of acetylenes. Reactions of amines, phenols, and furans, even under mild conditions, may be accompanied by multiple condensation or resinification. 4-Hydroxybenzylamine is reported706 to be obtained in 92% yield when ammonia is led into a mixture of phenol and formaldehyde. 

No 2 1 adducts could be detected in the complex mixtures produced by interaction of the nitroxide with perfluorinated acetylenes, although they are believed to be formed initially the main reaction paths proposed in the case of perfluorobut-2-yne, which yields the two mono-carbonyl products (43) and (44) as well as perfluorobiacetyl, are presented in Scheme 29. Acetylene itself, stated previously to yield AlV-bistrifluoromethylhydroxyl-amine and unsaturated hydrocarbons, is attacked only slowly at room temperature to give (CF3)2NOH, (CF3),NH, (CF3)2NON(CFs)2, [(CFa)jN-0]2CH-CO O N(CF3)2, and unidentified liquid products but no (CFa),N 0-C0 C0 0 N(CF3)2, the product expected (see p, 226) if any... 

A similar reaction pattern has been observed for the carbonylative cross-coupling reaction of o-iodoaniline and terminal acetylenes, where 2-snbstituted l,4-dihydro-4-oxoquinolines are obtained in good yields (Scheme 43). " The reaction of aromatic acetylenes generally gives a better yield than that of aliphatic acetylenes. Fnnctional groups such as acetal, THP, and ester are compatible with the reaction conditions. Other authors have reported that PdCl2(dppf) is similarly effective and the yield depends on the amine nsed. " For example, 2-phenyl-l,4-dihydro-4-oxoquinoline is obtained in 83% (diethylamine), 70% (triethylamine), 60% (piperidine), and 61% (morpholine) yields under 20 atm of CO in the presence of 10% of the catalyst at 120 °C for 1 h. 

Reppe [83] developed the Reppe reaction of carbonylation, vinylation, ethy-nylation and cyclization by reaction of acetylene with carbon monoxide, water, alcohols, amines, aldehydes and ketones, etc. In 1952, the reaction of olefins in place of acetylene, in the presence of metal carbonyl catalysts, produces alcohols. This process is called the new Reppe process, and butanol has been industrially produced by this process since around 1960. 

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