Cuprate, addition with

It has been proposed that a directed cuprate addition with a carbamate or a carbonate serving as a reagent-directing functional group may account for the stereochemical outcome of these reactions (see models 115 and 116 in Scheme 6.25) [39, 48]. 

Scheme 6.26. Construction of polyketide building blocks by sequential directed stereoselective hydroformylation and directed cuprate addition with the aid of the reagent-directing o-DPPB group. (o-DPPB = ortho-diphenylbenzoylphosphanyl, DME = dimethoxyethane)...

Cuprate additions with BF3 activation have been carried out with enantiopure 4-thiazolines (96) (Equation (19)). Although the reaction takes place with a poor yield an excellent diastereoselectivity is achieved <91JCS(P1)2291>. 

A number of alternative multi-step procedures for the synthesis of a-tert-alkyl ketones are known, none of which possess wide generality. A previous synthesis of 2-tert-penty1cyclopentanone involved reaction of N-1-cyclopentenylpyrrol 1 dine with 3-chloro-3-methy1-l-butyne and reduction of the resulting acetylene (overall yield 46 ). However, all other enamines tested afford much lower yields. Cuprate addition to unsaturated ketones may be useful in certain cases. Other indirect methods have been briefly reviewed. ... 

There are numerous examples of cuprate additions to 4-alkoxy-2-cyclopentenones, which proceed with excellent tram diastereoselection16. 

This 1,2-asymmetric induction has been attributed to stcric and stcrcoclectronic factors. Similarly, the cuprate additions to 4-alkylcyclopentenones l7 -19, and 4-alkylcyclohexcnones16 b-18 proceeded with very high trans diastereoselection. The copper iodide catalyzed addition of propylmagnesium bromide to 4-methyl-2-cyclohexenone gave a trans/cis ratio of 80 20, whereas the addition to 5-methyl-2-cyclohexenone produced a transjcis ratio of 93 72 3-Silyloxy system 3 gave the trans-adduct 4 on treatment with butylcopper-boron trifluoride reagent20. 

Scheme 36). Interestingly, the higher order cuprate 206 underwent conjugate addition with only moderate selectivity. This is likely due to the intervention of an electron transfer pathway. Competing electron transfer reactions involving a-alkoxymetal reagents of this type have also been reported by Cohen [81]. 

The cuprate derived from the cis isomer of this reagent undergoes conjugate addition with cyclohexenone with unusually high diastereoselectivity (5 1, Eq. 23)24). In this case, electrophilically initiated ring opening with mercuric acetate chemo-selectively attacks the sterically least hindered cyclopropyl bond to give a branched product 7. Reductive work-up produces 8 in which the stereochemistry of the... 

Remarkably, the regioselectivity of the cuprate addition to acceptor-substituted enynes is also insensitive to the steric properties of the substrate. Thus, enynes with tert-butyl substituents at the triple bond (e.g. 68) underwent 1,6-additions even when the cuprate was also sterically demanding (Scheme 2.24) [47]. The method is therefore highly suitable for the preparation of sterically encumbered allenes of type 69. 

Scheme 2.28 Functionalized allenes obtained by 1,6-cuprate addition to acceptor-substituted enynes and regioselective enolate trapping with methyl triflate (77), aldehydes (78, 79), ketones (80) and silyl halides (81).

So-called lower order cyanocuprates RCu(CN)Li do not generally react with acceptor-substituted enynes. An exception is the cuprate t-BuCu(CN)Li which undergoes anti-Michael additions with 2-cn-4-ynoates and nitriles (equation 61)151. The mechanistic aspects of this very unusual reaction are unknown radical intermediates and electron transfer steps have not been found. 

Z, 6Z- 10 COOMe was produced by a short and stereospecific one-pot synthesis (Scheme 17) [25], via sequential addition of dipropyllithium cuprate 115 to two equivalents of acetylene, followed by Michael addition of the resulting conjugated dienyl cuprate 116 with methyl propiolate 117. The only sig-... 

High levels of asymmetric induction can be achieved intramolecularly if the substrate functionality and the heteroatom ligand are contained in the same molecule. Chiral amido(a]kyl)cuprates derived from allylic carbamates [(RCH= CHCH20C(0)NR )CuR undergo intramolecular allylic rearrangements with excellent enantioselectivities (R = Me, n-Bu, Ph 82-95% ee) [216]. Similarly, chiral alkoxy(alkyl)cuprates (R OCuRLi) derived from enoates prepared from the unsaturated acids and trans-l,2-cyclohexanediol undergo intramolecular conjugate additions with excellent diasteroselectivities (90% ds) [217]. 

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