Alkylation heteroaromatic ketone

Alkyl aryl ketones are convenient intermediates for preparing other substituted aromatic and heteroaromatic compounds. Challenger and co-workers " acetylated thieno[2,3-h]thiophene (1) with acetyl chloride and stannic chloride [Eq. (59)]. The 2-acetylthieno[2,3-A]-thiophene obtained by this method was reduced to the 2-ethyl derivative (20) identical with the product of an independent synthesis. ... 

The ruthenium-catalyzed addition of C-H bonds in aromatic ketones to olefins can be applied to a variety of ketones, for example acetophenones, naphthyl ketones, and heteroaromatic ketones. Representative examples are shown in the Table 1. Terminal olefins such as vinylsilanes, allylsilanes, styrenes, tert-butylethy-lene, and 1-hexene are applicable to this C-H/olefin coupling reaction. Some internal olefins, for example cyclopentene and norbornene are effective in this alkylation. The reaction of 2-acetonaphthone 1 provides the 1-alkylation product 2 selectively. Alkylations of heteroaromatic ketones such as acyl thiophenes 3, acyl furans, and acyl pyrroles proceed with high yields. In the reaction of di- and tri-substitued aromatic ketones such as 4, which have two different ortho positions, C-C bond formation occurs at the less congested ortho position. Interestingly, in the reaction of m-methoxy- and m-fluoroacetophenones C-C bond formation occurs at the congested ortho position (2 -position). 

Iodine in combination with [bis(acyloxy)iodo]arenes is a classical reagent combination for the oxidative iodination of aromatic and heteroaromatic compounds [99], A typical iodination procedure involves the treatment of electron-rich arenes with the PhI(OAc)2-iodine system in a mixture of acetic acid and acetic anhydride in the presence of catalytic amounts of concentrated sulfuric acid at room temperature for 15 min [100,101]. A solvent-free, solid state oxidative halogenation of arenes using PhI(OAc)2 as the oxidant has been reported [102]. Alkanes can be directly iodinated by the reaction with the PhI(OAc)2-iodine system in the presence of f-butanol under photochemical or thermal conditions [103]. Several other iodine(in) oxidants, including recyclable hypervalent iodine reagents (Chapter 5), have been used as reagents for oxidative iodination of arenes [104-107]. For example, a mixture of iodine and [bis(trifluoroacetoxy)iodo]benzene in acetonitrile or methanol iodinates the aromatic ring of methoxy substituted alkyl aryl ketones to afford the products of electrophilic mono-iodination in 68-86% yield [107]. 

This process was also extended to the formation of /3-hydroxylactams from a ,/3-unsaturated amides with tethered keto-amides 249 (Scheme 111) (179-181). Various substrates underwent cyclizations resulting in the corresponding /3-hydroxylactams 250 with high diastereoselectivities (>95 5) and moderate yields (52-70%). The reaction was tolerant of a wide range of ketones including alkyl, aromatic, and heteroaromatic ketones. Substituents on the /3-position of a,p-unsaturated amides were not well tolerated. Acryloyl amides were found to be the best substrates for this type of cyclization. In addition, crotonoyl amide also underwent cyclization, but conversions and reaction rates were diminished. A... 

O3yhydroperoxides. Peroxides of the oxyhydro type are obtained by the addition of hydrogen peroxide to ketones. High yields of alkyl radicals are then often obtained by reaction with ferrous salts. 1-Meth-oxycyclohexyl hydroperoxide is easily obtained from cyclohexanone and hydrogen peroxide in methanol. It gives rise to the 5-(methoxy-carbonyl)-pentyl radical, which has been used to alkylate protonated heteroaromatic bases in high yield [Eq. (6)]. 

Some oxaziranes can be prepared very simply from ketones and N-chloroamines. Thus 2-methyl-3,3-pentamethyleneoxazirane is easily obtained from cyclohexanone and iV-methylchloramine its reduction by ferrous salts gives an alkyl radical, which has been used to alkylate, in high yield, protonated heteroaromatic bases in aqueous solution (Scheme 5). 

Electrochemical studies are usually performed with compounds which are reactive at potentials within the potential window of the chosen medium i.e. a system is selected so that the compound can be reduced at potentials where the electrolyte, solvent and electrode are inert. The reactions described here are distinctive in that they occur at very negative potentials at the limit of the cathodic potential window . We have focused here on preparative reductions at mercury cathodes in media containing tetraalkylammonium (TAA+) electrolytes. Using these conditions the cathodic reduction of functional groups which are electroinactive within the accessible potential window has been achieved and several simple, but selective organic syntheses were performed. Quite a number of functional groups are reduced at this limit of the cathodic potential window . They include a variety of benzenoid aromatic compounds, heteroaromatics, alkynes, 1,3-dienes, certain alkyl halides, and aliphatic ketones. It seems likely that the list will be increased to include examples of other aliphatic functional groups. 

A variety of different sources of radicals have been used in several heteroaromatic substitution reactions [2] these include acyl peroxides, oxaziridines, thiohydroxa-mic Barton esters, the Gif reaction, alkyl xanthates, and ketones/H202 (Scheme 8). 

Thus many compounds arc obtained (250, Table 24), which may be considered to be derived from C-alkylation of the nucleophilic reagent by the Mannich base. Alkyl ketonic and phenolic bases arc mostly involved in this reaction, which exhibits many analogies with aminomethylation, particularly concerning chemo- and regioselectivity on aromatic and heteroaromatic derivatives. Ring activation by means of hydroxy and amino substituents in the alkylation of pyridine and pyrimidine derivatives is also required. 

From a historical perspective, the a-(dialkylamino)nitrile anions were the first acyl anion equivalents to undergo systematic investigation. More recent studies indicate that anions of a-(dialkylamino)nitriles derived from aliphatic, aromatic or heteroaromatic aldehydes intercept an array of electrophiles including alkyl halides, alkyl sulfonates, epoxides, aldehydes, ketones, acyl chlorides, chloroformates, unsaturated ketones, unsaturated esters and unsaturated nitriles. Aminonitriles are readily prepared and their anions are formed with a variety of bases such as sodium methoxide, KOH in alcohol, NaH, LDA, PhLi, sodium amide, 70% NaOH and potassium amide. Regeneration of the carbonyl group can be achieved... 

A method for the synthesis of highly substituted aromatic and heteroaromatic hydroxy compounds is the photochemical Wolff rearrangement of an unsaturated a-diazo ketone in the presence of an alkyne. The product, an alkenylcyclobutenone, undergoes ringopening and recyclization to a phenol (equation 60). Three examples of the reaction are the formation of the naphthols 587 and 588 and that of the hydroxybenzofuran 589. Complexes 590 (R = alkyl or aryl r-alkyl or Me3Si), produced from THF, alkynes and... 

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