Chiral lithium amide bases 2,3 -Wittig rearrangement

A high level of enantioselectivity in an acyclic system has been reported in the rearrangement of tricarbonylchromium(O) complexes of allyl benzyl ethers using chiral lithium amide base 73 (equation 38) . Upon treatment with 1.1 equivalents of lithium amide 73 and 1 equivalent of LiCl at —78 to —50°C, ether 74 afforded the rearrangement product R)-75 in 80% yield with 96% ee. The effect of substituents on the chemical yields and enantioselectivity of the [2,3]-Wittig rearrangement was also studied (see Table 3). 

Scheme 6.21. Asymmetric [2,3]-Wittig rearrangements using a chiral lithium amide base [70,87-89]. The transition structure leading to the major enantiomer is illustrated.

The pioneering work on enantioselective [2,3]-Wittig rearrangement was carried out by Marshall and Lebreton in the ring-contracting rearrangement of a 13-membered cyclic ether using lithium bis(l-phenylethyl) amide (63) as a chiral base (equation 34). Upon treatment with a (S,S)-63 (3 equivalents) in THF at —70 to —15 °C, ether 64 afforded the enantioenriched [2,3]-product 65 in 82% yield with 69% ee. The reaction was applied in the synthesis of (+)-aristolactone (66). 

Other Enantioselective Reactions. Enantioselective epoxide elimination by chiral bases has been demonstrated. More recently, the enantioselective [2,3]-Wittig rearrangement of a 13-membered propargylic ally lie ether has been performed using the lithium amide of (f ,f )-(l) as the base for deprotonation (eq 15). For this particular substrate, THF is a better solvent than ether, although pentane produces better results in a related transformation (eq 16). In fact, a change in solvent in this type of reaction has been shown to lead to a reversal of the stereoselectivity of the transformation. ... 

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