Chiral auxiliaries asymmetric Simmons-Smith reactions

The reaction was first carried out with the substrate bearing the chiral auxiliary. Scheme 5-64 shows the asymmetric cyclopropanation reaction using 2,4-pentandiol as a chiral auxiliary.115 Scheme 5-65 illustrates the use of optically pure 1,2-frafts-cyclohexanediol as a chiral auxiliary in asymmetric Simmons-Smith cyclopropanation.116 Excellent yield and diastereoselectivity are obtained in most cases. 

Normally the chiral auxiliaries are introduced and removed in the asymmetric synthesis of Simmons-Smith reactions of allylic alcohols to provide mostly /rani-disubstituted cyclopropanes. Stereoselective syntheses of c -disubstituted cyclopropanes are difficult to achieve. Starting from (Z)-3-phenylprop-2-en-l-ol (80a) and (Z)-6-phenylhex-2-en-l-ol (80b), the corresponding c -disubstituted cyclopropanes 81a and 81b were prepared by first treating them with diethylzinc followed by diethyl (- -)-(/ ,7 )-tartrate (DET). A zinc-bridged intermediate is assumed to be formed first. This is subsequently treated with diethylzine and diiodomethane to give the products 81. The reaction conducted at — 12 "C gave the cyclopropanated products 81a and 81b with 70 and 81% ee, respectively.This method has the advantages that the introduction of the chiral auxiliary to the substrate and its removal are not neccessary and that both cis- and trans-disubstituted cyclopropanes could be prepared from (Z)- and ( )-allylic alcohols, repectively. 

Asymmetric induction is possible in the Simmons-Smith reaction if a suitable auxiliary is used, or if the chirality is built in via a chiral template precursor (sec. 10.9). When 418 was prepared from diethyl tartrate. 

A number of chiral acetal derivatives have also proved effective in asymmetric cyclopropanation reactions, with auxiliaries based on tartaric acid proving to be partieularly usefiil. In the case of cyclic a,P unsaturated compounds, di-O-benylthreitol derivatives (see 51) imdergo efficient and diastereoselective Simmons-Smith reactions to give the cyclopropanated products SS. ... 

The landmark report by Winstein et al. (Scheme 3.6) on the powerful accelerating and directing effect of a proximal hydroxyl group would become one of the most critical in the development of the Simmons-Smith cyclopropanation reactions [11]. A clear syw directing effect is observed, implying coordination of the reagent to the alcohol before methylene transfer. This characteristic served as the basis of subsequent developments for stereocontrolled reactions with many classes of chiral allylic cycloalkenols and indirectly for chiral auxiliaries and catalysts. A full understanding of this phenomenon would not only be informative, but it would have practical applications in the rationalization of asymmetric catalytic reactions. 

The asymmetric synthesis of cyclopropanes has attracted continual efforts in organic synthesis, due to their relevance in natural products and biologically active compounds. The prevalent methods employed include halomethylmetal mediated processes in the presence of chiral auxiliaries/catalysts (Simmons-Smith-type reactions), transition-metal-catalyzed decomposition of diazoalkanes, Michael-induced ring closures, or asymmetric metalations [8-10,46], However, the asymmetric preparation of unfunctionahzed cyclopropanes remains relatively undisclosed. The enantioselective activation of unactivated C-H bonds via transition-metal catalysis is an area of active research in organic chemistry [47-49]. Recently, a few groups investigated the enantioselective synthesis of cyclopropanes by direct functionalization reactions. 

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