화학공학소재연구정보센터
Journal of the American Chemical Society, Vol.139, No.34, 11877-11886, 2017
alpha-Sulfinyl Benzoates as Precursors to Li and Mg Carbenoids for the Stereoselective Iterative Homologation of Boronic Esters
The stereoselective reagent-controlled homologation of boronic esters is one of a small number of iteratable synthetic transformations that if automated could form the basis of a veritable molecule-making machine. Recently, alpha-stannyl triisopropylbenzoates and alpha-sulfinyl chlorides have emerged as useful building blocks for the iterative homologation of boronic esters. However, alpha-stannyl benzoates need to be prepared using stoichiometric amounts of the (+)- or (-)-enantiomer of the scarcely available and expensive diamine sparteine; also, these building blocks, together with the byproducts that are generated during homologation, are perceived as being toxic. On the other hand, alpha-sulfinyl chlorides are difficult to prepare with high levels of enantiopurity and are prone to undergo deleterious acid base side-reactions under the reaction conditions for homologation, leading to low stereospecificity. Here, we show that the use of a hybrid of these two building blocks, namely, alpha-sulfinyl triisopropylbenzoates, largely overcomes the above drawbacks. Through either the sulfinylation of alpha-magnesiated benzoates with either enantiomer of Andersen's readily available menthol-derived sulfinate or the alpha-alkylation of enantiopure S-chiral alpha-sulfinyl benzoates, we have prepared a range of highly enantiopure mono- and disubstituted alpha-sulfinyl benzoates, some bearing sensitive functional groups. Barbier-type reaction conditions have been developed that allow these building blocks to be converted into lithium (t-BuLi) and magnesium (i-PrMgCl center dot LiCl) carbenoids in the presence of boronic esters, thus allowing efficient and highly stereospecific homologation. The use of magnesium carbenoids allows carbon chains to be grown with the incorporation of sensitive functional groups, such as alkyl/aryl halides, azides, and esters. The use of lithium carbenoids, which are less sensitive to steric hindrance, allows sterically encumbered carbon carbon bonds to be forged. We have also shown that these building blocks can be used consecutively in three- and four-step iterative homologation processes, without intervening column chromatography, to give contiguously substituted carbon chains with very high levels of enantio- and diastereoselectivity.