Ketones reaction with cuprates

There is also a correlation between the reduction potential of the carbonyl compound and the ease of reaction with cuprate reagents. The more easily reduced, the more reactive is the compound toward organocuprate reagents. Compounds such as a,/3-unsaturated esters and nitriles which are not as easily reduced as a,j3-unsaturated ketones do not react readily with simple alkyl cuprates even though they are good acceptors in conjugate addition reactions involving other types of nucleophiles (Michael reactions). 

Asymmetric induction by sulfoxide is a very attractive feature. Enantiomerically pure cyclic a-sulfonimidoyl carbanions have been prepared (98S919) through base-catalyzed cyclization of the corresponding tosyloxyalkylsulfoximine 87 to 88 followed by deprotonation with BuLi. The alkylation with Mel or BuBr affords the diastereomerically pure sulfoximine 89, showing that the attack of the electrophile at the anionic C-atom occurs, preferentially, from the side of the sulfoximine O-atom independently from the substituent at Ca-carbon. The reaction of cuprates 90 with cyclic a,p-unsaturated ketones 91 was studied but very low asymmetric induction was observed in 92. 

The titaniated (25)-2,5-dihydro-2-isopropyl-3,6-dimethoxypyrazines derived from cyclo(L-Val, Gly) or cyclo(L-Val, Ala) (1, R1 = H, CH3) react with a,/I-unsaturatcd aldehydes exclusively by 1.2-addition (cf. nearly exclusive 1,4-addition of ,//-unsaturated ketones with cuprate complexes of 2,5-dialkoxy-3,6-dihydropyrazines, see Section D. 1.5.2.3.1.4.) in a highly diastereoselective mode to give virtually only the (l S,2R)-diastereoniers 2 ". In reactions with the corresponding lithiated pyrazines both regioselectivity and diastereofacial differentiation at C-2 are also remarkably high (dc 95 %), but the diastereomeric excess at C-l is substantially smaller (30 50%) ... 

The procedure described here illustrates the preparation of mixed lithium arylhetero(alkyl)cuprate reagents and their reactions with carboxylic acid chlorides,4 These mixed cuprate reagents also react with a,a -dibromoketones,12 primary alkyl halides,4 and a,/3-unsaturated ketones,4 with selective transfer of only the alkyl group. 

We owe to Kato and his colleagues a considerable advance in furan copper reagents. They have demonstrated the formation of the lithium di(3-furyl) cuprate species 87 which is highly reactive and possesses hard properties that suit it to reaction at hard centers, mainly carbonyl carbon.223 The reagent is easily prepared in situ from 3-furyllithium and Cu2I2. Simple copper derivatives do not react with ketones, but this cuprate reacts well and quantitatively with acid chlorides. It also reacts well with some epoxides (oxirans). Moreover, there is another form prepared in the presence of... 

Scheme 54 shows the synthesis reported by Cox et al. of the pyrazoline compound 198 [98]. The Weinreb amide (e.g., 199) was reacted with a terminal alkyne followed by a reaction of the resulting alkyl ketone (200) with an aryl cuprate to produce the pyrazoline 198. Cox et al. employed the use of microwave technology in this reaction. Kidwai and Misra also employed microwave technology to produce pyrazoline compounds [99]. 

The reaction of 1,2-allenyl ketones with organocuprates afforded /3,y-unsaturated enones. The reaction with mixed cuprates RR CuLi delivered, depending on the properties of R and R, two products 430 and 431 [192]. 

Coupling with enol esters (7, 93). A new synthesis of an alkyl-substituted alkene involves coupling of a lithium dialkyl cuprate with an enol triflate,1 available from a ketone by reaction with triflic anhydride and 2,6-di-t-butylpyridine.2 A wide variety of organocuprates can be used and the geometry of the enolate is largely retained. Reported yields are in the range 60 100%. 

Ss2 reaction with a,fi-epoxy ketones.6 The enolate 1 of 2,3-epoxycyclohexanone reacts with methyllithium to give, after acidic work-up, 2-methy -2-cyclohexenone (3), the product of SN2 addition. Reaction of 1 with lithium dimethyl cuprate on the other hand results in 6-methyl-2-cyclohexcnonc (2), the product of Sv2 addition. 

Two highly unusual reactions were noted in this study which merit attention. First, the treatment of (59) with cuprate (60) gave rise to 1,2-addition of the alkyne as the only product (67% equation 57). Second, when trifluoromethyl ketone (59) was treated with either the higher or lower order methylcu-prates, the cyanohydrin (61) was isolated in addition to the normal 1,4-addition product (equation 58). 

Fig. 10.46 (cont.) Mechanistic possibilities for the 1,4-addition of a Gilman cuprate to an a,/Lunsatitrated ketone. Part 2 shows the formation of the CuR-containing enolate (I) and its further reaction with typical electrophiles. The fact that all intermediates of this 1,4-addition are chiral, but generated in racemic form should not be overlooked consequently, the same is true of the final products J, K and L. 

Cheng, K.F., Nagakura, I., and Piers, E. 1982. Reaction of P-halo aP-unsaturated ketones with cuprate reagents. Efficient syntheses of PP-dialkyl ketones and P-alkyl P-unsaturated ketones. A synthesis of (Z)-jasmone. The Canadian Journal of Chemistry, 60(10) 125 6-63. 

---