Aryl ethers iodination

Keywords Propargylic aryl ethers, iodine, sodium bicarbonate, nitromethane, room temperature, electrophilic iodocyclization, 3,4-disubstituted 2//-benzopyrans... 

Proton acids can be used as catalysts when the reagent is a carboxylic acid. The mixed carboxylic sulfonic anhydrides RCOOSO2CF3 are extremely reactive acylating agents and can smoothly acylate benzene without a catalyst.265 With active substrates (e.g., aryl ethers, fused-ring systems, thiophenes), Friedel-Crafts acylation can be carried out with very small amounts of catalyst, often just a trace, or even sometimes with no catalyst at all. Ferric chloride, iodine, zinc chloride, and iron are the most common catalysts when the reactions is carried out in this manner.266... 

Iodine-mediated removal of both prenyl protecting groups from aryl ether 506 leads to the unexpected formation of 3-(3-iodo-2,2-dimethylchroman-6-yl)propan-l-ol. The reaction proceeds via formation of the ortho-allylic phenol intermediate 507 by electrophilic removal of a prenyl species, followed by an iodine promoted electrophilic cycliza-tion (Scheme 111) <2001SL1989, 2002T5689>. 

Aryl ethers in the presence of a solvent can be preferentially halo-genated in the nucleus. Thus, anisole with phosphorus pentabromide or with iodine monochlotide yields p-bromoanisole (90%) and p-iodo-anisole (46%), respectively. Phosphorus pentachloride has also been used for the halogenation of the nucleus as in the preparation of 4-chloro-biphenyl ether (90%). The action of this reagent with aliphatic and aryl-aliphatic ethers is very complex, giving both cleavage and halogenation products. ... 

Treatment of oestrone with tetraphenylbismuth monotrifluoroacetate gave oestrone phenyl ether and exemplified, in part, a new procedure for aryl ether formation.31 A detailed study was reported of the formation of benzyl ethers by sequential reaction of alcohols with chloro(phenylmethylene)dimethylammonium chloride and sodium hydrogen telluride.32 Steroidal alcohols, inter alia, were converted into hydrolytically stable silyl ethers by reaction with B N Sil or BulPh2I which were generated in situ from the selenosilane and iodine.33 The 5a-hydroxycholestane (21) was protected in this way. 

A good and comprehensive review of catalytic electrophilic acylation was published by Pearson and Buehler.i Only the catalysts most widely used were considered, with special attention to iron trichloride, zinc chloride, iodine, and elemental iron. The substrates that can be acylated using small amounts of catalysts include alkylarenes, aryl ethers, biphenyls, naphthalenes, acenaphthenes, fluorene, furans, and thiophenes. Aromatic acyl chlorides lead to better yields than aliphatic ones, reaching a maximum of 96% and a minimum of 34%. In general, fhe reactions are performed af relatively high temperatures (from 50°C to 200°C) af which hydrogen chloride evolution is fairly rapid. 

Aromatic iodination. Alkyl aryl ethers are iodinated (27 examples, 75-100%). Lead(IV) acetate can be used in place of HgO. ... 

Yakura et al. have shown that Oxone in combination with a catalytic quantity of 4-iodophenoxy acetic acid is an effective system for the hypervalent iodine oxidation of phenols and aryl ethers (eq 112). ... 

The structure of thyroxine, a thyroid hormone that helps to regulate metabolic rate, was determined in part by comparison with a synthetic compound believed to have the same structure as natural thyroxine. The final step in the laboratory synthesis of thyroxine by Harington and Barger, shown helow, involves an electrophilic aromatic substitution. Draw a detailed mechanism for this step and explain why the iodine substitutions occur ortho to the phenolic hydroxyl and not ortho to the oxygen of the aryl ether. [One reason iodine is required in our diet (e.g., in iodized salt) is for the biosynthesis of thyroxine.]... 

The use of iodotrimethylsilane for this purpose provides an effective alternative to known methods. Thus the reaction of primary and secondary methyl ethers with iodotrimethylsilane in chloroform or acetonitrile at 25—60° for 2—64 hours affords the corresponding trimethylsilyl ethers in high yield. The alcohols may be liberated from the trimethylsilyl ethers by methanolysis. The mechanism of the ether cleavage is presumed to involve initial formation of a trimethylsilyl oxonium ion which is converted to the silyl ether by nucleophilic attack of iodide at the methyl group. tert-Butyl, trityl, and benzyl ethers of primary and secondary alcohols are rapidly converted to trimethylsilyl ethers by the action of iodotrimethylsilane, probably via heterolysis of silyl oxonium ion intermediates. The cleavage of aryl methyl ethers to aryl trimethylsilyl ethers may also be effected more slowly by reaction with iodotrimethylsilane at 25—50° in chloroform or sulfolane for 12-125 hours, with iodotrimethylsilane at 100—110° in the absence of solvent, " and with iodotrimethylsilane generated in situ from iodine and trimcthylphenylsilane at 100°. ... 

Periodic acid dihydrate, with iodine and durene to give iododurene, 51, 94 Phenols, from aryl methyl ethers, 53, 93 Phenylacetaldehyde, from 2-lithio-1,3,5-trithiane and benzyl bromide, 51, 43 Phenylacetic acid, bromination, 50, 31... 

Alkyl- or aryl-dibenzothiophenes are conveniently prepared from the 2-arylthio-cyclohexanones, which are readily cyclized and dehydrogenated to yield the respective 1-, 2-, 3- or 4-substituted dibenzothiophenes (382 equation 9 Section 3.15.2.3.2). More complex polycyclic systems are available, using suitable aryenethiols, such as naph-thalenethiols, and 2-bromo-l-tetralone to synthesize the appropriate 2-arylthio ketones. Diaryl sulfides can be converted to dibenzothiophene derivatives in satisfactory yields by photolysis in the presence of iodine (equation 10) (75S532). Several alkyldibenzothiophenes with substituents in the 2- and/or 3-positions were prepared in satisfactory yield by the condensation of dichloromethyl methyl ether with substituted allylbenzo[6]thiophenes (equation 11) (74JCS(P1)1744). 

Benzocoumarins (405) result from the dehydrogenation of the corresponding dihydrocoumarins by palladium-charcoal at 300 °C in the absence of solvent (73CB62), whilst 4-aryl-3,4-dihydrocoumarins are converted to the coumarins in diphenyl ether (72IJC32). This latter conversion also occurs under milder conditions using iodine and potassium acetate in acetic acid (73AJC899). 

The use of hypervalent iodine reagents in carbon-carbon bond forming reactions is summarized with particular emphasis on applications in organic synthesis. The most important recent methods involve the radical decarboxylative alkylation of organic substrates with [bis(acyloxy)iodo]arenes, spirocyclization of para- and ortho-substituted phenols, the intramolecular oxidative coupling of phenol ethers, and the reactions of iodonium salts and ylides. A significant recent research activity is centered in the area of the transition metal-mediated coupling reactions of the alkenyl-, aryl-, and alkynyliodonium salts. 

A novel hypervalent iodine-induced direct intramolecular cyclization of a-(aryl)alkyl-jS-dicarbonyl compounds 33 has been recently reported (Scheme 15) [30]. Both meta- and para-substituted phenol ether derivatives containing acyclic or cyclic 1,3-dicarbonyl moieties at the side chain undergo this reaction in a facile manner affording spirobenzannulated compounds 34 that are of biological importance. 

When the magnesium alkyl compound does not form readily, i. e. in using aryl halides, a crystal of iodine is often added to start the reaction. Other solvents than ether have been used, i. e. anisole, phenyl amyl ether, and dimethyl-aniline. The solvent apparently combines with the compound MgRX forming intermediate products R20.MgRX and R3N.MgRX, and acts as a catalyst, since it has been found that the reactions proceed in benzene or xylene provided a small amount of ether or dimethyl-aniline be added. 

This BI3 complex cleaves aryl methyl ethers to phenols at room temperature in good yield. Dialkyl ethers are converted into iodinated products. It also converts terminal gem-diacetates into aldehydes.3... 

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