Transmetallation Titanium isopropoxide

Titanium ylides are generated from imine esters with titanium isopropoxide chlorides and amines or by transmetalation of the N-lithiated ylides (90,91). The regioselectivity of their reactions with methyl acrylate is opposite to that normally observed (90). A transition state is proposed in Scheme 11.13 to explain this alternative regioselectivity. Intramolecular cycloadditions of the titanium ylides offer a synthetic application of this regioselectivity. 

A number of methods to increase the thermal stability of Kdbrich reagents have centered around replacement of the lithium counterion normally present with a variety of transition metals, chiefly titanium, hafnium and copper." For example, the reagent derived from transmetalladon of lithium dichlorometh-ane with titanium isopropoxide could be reacted with various ketones and aldehydes to afford halohydrin adducts in good yields at temperatures as high as 0 °C. Competition experiments established the chemoselectivity of this reagent (Scheme 14). The direct activation of severid allylic halides has been accomplished with tin and chromium ° reagents (equation 26). Transmetallation of an alkyllead precursor has also been noted. 

The lithiation of ethyl allyl sulfide followed by transmetallation with titanium isopropoxide engenders an allyltitanium reagent formulated as (26 Scheme 8). This and related reagents add to aldehydes or ketones to afford hydroxy sulfides, which are converted to epoxides as shown. The power of this method for the stereoselective generation of even trisubstituted epoxides is evident from Scheme 8 and equation (18). Reagent (26a), prepared as shown in Scheme 8a, undergoes addition to ketone (26b) to afford product exclusively resulting from chelation-controlled diastereofacial addition (as a mixture of epimers at the position shown). ... 

DeCamp et al.t19l synthesized the lactone intermediate of the 1-hydroxyethylene isostere with high yields and stereoselectivity. As summarized in Scheme 10 (Section 10.6.2), the titanium homoenolate is prepared from ethyl 3-iodopropionate. The iodide is metalated with zinc/copper couple to give the iodozinc homoenolate species. The alkyltitanium homoenolate is then generated by transmetalation of the iodozinc precursor with one of the several chlorotitanium isopropoxide species. The resulting titanium homoenolate reacts with a N-protected a-amino aldehyde, leading to a mixture of 45-diastereomers. In the last step, the product is lactonized. 

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