A novel visible-light-induced palladium-catalyzed Heck reaction for bromine sugars and aryl olefins with high regioand stereochemistry selectivity for the preparation of C-glycosyl styrene is described. This reaction takes place in one step at room temperature by using a simple and readily available starting material. This protocol can be scaled up to a wide range of glycosyl bromide donors and aryl olefin substrates. Mechanistic studies indicate that a radical addition pathway is involved.C-Glycosides, in which the glycosidic oxygen is replaced by a carbon atom, have received a great deal of attention 1 because of the crucial roles of carbohydrates in resisting metabolic degradation and biological activities. 2 Compared with N-or Oglycosides, C-glycosides show an obvious enhancement in both in vitro and in vivo stability. Despite the significant methods available for constructing C-glycosides, a stereoselective and efficient method is still challenging and lags far behind that for O-or N-glycosides. 3 Over the past few decades, synthetic methods for C-glycosides have mainly concentrated on transition-metal-catalyzed 4 cross-coupling reactions. In particular, the construction of aryl C-glycosides 5 has undergone remarkable development. In 2008, Gagnéand co-workers reported a Ni-catalyzed Negishi cross-coupling approach for the synthesis of C-alkyl and C-aryl glycosides 6 (Scheme 1, Gagne's work). Recently, an efficient and stereoselective synthesis via palladium-catalyzed C−H glycosylation of Caryl glycosides was reported by Chen and co-workers. 7 In addition, the groups of Gagne, Cossy, and Nakamura also explored nickel-, 8 cobalt-, 9 and iron-catalyzed 10 cross-coupling reactions through generation of glycosyl radical intermediates to synthesize C-aryl glycosides.Although synthetic routes for C-aryl glycosides have been widely explored, the C-glycosyl styrenes, which are versatile starting compounds for, e.g., varitriol, 11 C-glycosyl aldehydes, 12 UDP sugar derivatives, 13 pyranopyran carbohydrate amino acids, 14 and some natural products, 15 remain challenging. At the outset, an intramolecular radical cyclization strategy was applied to prepare C-glycopyranosyl styrenes. In 1991, Stork and co-workers 16 demonstrated a temporary silicon connection for constructing C-glycopyranosyl styrenes that undergo an intramolecular radical process. Soon afterward, the Beau group 17 used a similar strategy to realize samarium iodidepromoted radical cyclization for the formation of the Cglycopyranosyl bond. Over the past few years, some other
