Allyl organometallic compounds chiral

We have seen in Section 1.1.3 that reactions of many allyl organometallics and chiral C=X electrophiles proceed with only modest levels of relative diastereoselection. Significant improvement in dia-stereoselectivity is possible, however, by using double asymmetric synthesis, that is, by using the highly enantioselective allyl metal reagents described in Section 1.1.4 rather than the less diastereoface-selec-tive achiral allyl metal compounds discussed in Section 1.1.3. Double asymmetric synthesis is also... 

A number of highly enantioselective chiral allyl organometallic reagents have been described in the literature. These are of considerable interest both for the asymmetric synthesis of homoallyl alcohols as well as in double asymmetric reactions with chiral C=X electrophiles. - Two distinct groups of chiral allyl metal reagents can be identified those with conventional, easily introduced chiral auxiliaries and ones in which the center of chirality is a structural component of the reagent (e.g. allyl metal compounds with substituents at C-1). These are discussed separately in the sections that follow. 

Yamamoto and coworkers [3], however, have reported that reactions of al-lyl-9-BBN with certain chiral imines give the corresponding allylation products with very high enantiomeric excess, in essentially, the quantitative yields (Eq. 12.2). Table 12.1 summarizes these very high 1,2-asymmetric inductions. The main reason for poor selectivity of imine is the complex reactivity of imines toward other organometallic compounds [4-6]. 

Indeed, several interesting procedures based on three families of active catalysts organometallic complexes, phase-transfer compounds and titanium silicalite (TS-1), and peroxides have been settled and used also in industrial processes in the last decades of the 20th century. The most impressive breakthrough in this field was achieved by Katsuki and Sharpless, who obtained the enantioselective oxidation of prochiral allylic alcohols with alkyl hydroperoxides catalyzed by titanium tetra-alkoxides in the presence of chiral nonracemic tartrates. In fact Sharpless was awarded the Nobel Prize in 2001. 

---