Cross-coupling reactions epoxide

Sulfonium salts have been prepared on insoluble supports by S-alkylation of thioethers (Figure 8.2) only as synthetic intermediates. These compounds can be used to alkylate carboxylates [168] and halides [65], or as electrophiles for the Suzuki cross-coupling reaction (see Entry 7, Table 3.48 [169]). Sulfonium salts are also C,H-acidic, and can be used as intermediates for the synthesis of epoxides (Entry 7, Table 15.1 [170]). 

Alkenylboron compounds cyclopropanations, 9, 181 haloetherification, 9, 182 hydrogenation and epoxidation, 9, 182 metal-catalyzed reactions, 9, 183 metallic reagent additions, 9, 182 via radical addition reactions, 9, 183 5-Alkenylboron compounds, cross-coupling reactions, 9, 208 Alkenyl complexes with cobalt, 7, 51 with copper, 2, 160, 2, 174 with Cp Re(CO) (alkene)3 , 5, 915-916 with dicarbonyl(cyclopentadienyl)hydridoirons, 6, 175 with gold, 2, 255... 

Cross-coupling reactions of ArCOAr. Reaction of Yb(0) with diaryl ketones changes the reactivity of the carbonyl group from electrophilic to nucleophilic. Thus in the presence of this lanthanoid metal, diaryl ketones couple with other ketones, nitriles, and epoxides to give pinacols, a-hydroxy ketones, and 1,3-diols, respectively, via the intermediate a. 

Introduction of the silylmethyl group into organic halides, tosylates, and epoxides is achieved by nickel, palladium-, or copper-catalyzed cross-coupling reactions. 

The Suzuki cross-coupling reaction is recognized as a novel, abbreviated method for the synthesis of 2-hydroxychrysene, 2-hydroxy-5-methylchrysene, and 8-hydroxy-5-methyl-chrysene from easily accessible reactants (Eq. (8)) [23]. These phenolic compounds constitute precursors for the synthesis of dihydrodiol and bay-region diol epoxide derivatives of chrysene and 5-methylchrysene, which are implicated as the active forms of carcinogenic polynuclear aromatic hydrocarbons. 

Lithiation of compound 560 with s-BuLi-TMEDA in THF at —78 °C following an inverse addition protocol provided the anion 561. It reacts with primary alkyl iodides and triflates, silyl chlorides, diphenyl disulfide, epoxides, aldehydes, ketones, imines, acyl chlorides, isocyanates and sulfonyl fluorides to yield the expected compounds 562 (Scheme 152). The transmetallation of compound 561 with ZnBr2 allowed the palladium-catalyzed cross-coupling reaction with aryl and vinyl bromides837. When the reaction was quenched with 1,2-dibromotetrafluoroethane, the corresponding bromide 562 (X = Br) is obtained838. 

Transition metal mediated cross couplings of epoxides have remained relatively unexplored, with only a few examples of this potentially useful reaction reported in the literature. A recent report details the Suzuki-Miyaura cross-coupling of epoxides <07JOC3253>. The reaction of aryl epoxides with arylboronic acids under Suzuki-Miyaura coupling conditions provides the coupled product in good yields. Careful monitoring of the reaction is essential to avoid Pd-catalyzed rearrangement of the epoxides. 

Allylic barium reagents prepared in this way can realize highly a-selective reactions with different electrophiles, e.g. cross-coupling reactions with allylic halides or allylic phosphates, additions to carbonyl compounds or imines, and ring opening of epoxides. A selective Michael addition reaction with an a,/ -unsaturated cy-cloalkanone can also be performed by use of an allylic barium reagent. 

Compound 47 has been generated and used in the synthesis of a variety of 2-substituted indoles 48. Unlike lithiation of 77-(phenylsulfonyl)indole 3 [9,14], hthia-tion reactions of 4 have not been studied systematically. Nonetheless, selected examples including the corresponding reaction conditions used are given below (Table 7). Silanol 48g has been generated and exploited by Denmark in cross-coupling reactions [192, 193]. Kline used this chemistry to prepare 48b en route to a synthesis of 2-iodotryptamine [194]. Additional electrophiles used in reactions with 47 include epoxides (carbohydrates) [166], allyUc pivalates [195], and chlorodialkylphosphines [196]. 

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