Cuprate, 3- -, reaction with

Reaction of propynyl-substituted ester 1 with lithium dimethylcuprate gives allene 2. The problem investigated in this study148 was the stereochemical course of the cuprate reaction with propynyl esters, and the relative configuration around the allene unit of 2 was determined by chemical methods (see pp 473 and 487). 

Because of the reactivity of aldehydes with cuprates (sec. 8.7.A.v), 1,2-addition to a,p-unsaturated aldehydes can compete with 1,4-addition, although the former usually predominates. a,p-Unsaturated ketones normally give 1,4-addition. In Table 8.21, 12 Marshall showed how the copper reagent and proportion of RLi to Cu influenced the ratio of 1,2- to 1,4-addition with 439 and di(4-pentenyl)cuprate. Reaction with this... 

A. Alexakis, G. Cahiez, and J. F. Normant, Tetrahedron, 1980, 36, 1961. (Z)-Alkenyl cuprate reactions with various electrophiles, e.g., CO2, epoxides, aldehydes, ot,jS-enones, and alkynes. 

The most frequently used organocuprates are those m which the alkyl group is pri mary Steric hindrance makes secondary and tertiary dialkylcuprates less reactive and they tend to decompose before they react with the alkyl halide The reaction of cuprate reagents with alkyl halides follows the usual 8 2 order CH3 > primary > secondary > tertiary and I > Br > Cl > F p Toluenesulfonates are somewhat more reactive than halides Because the alkyl halide and dialkylcuprate reagent should both be primary m order to produce satisfactory yields of coupled products the reaction is limited to the formation of RCH2—CH2R and RCH2—CH3 bonds m alkanes... 

A key step in the reaction mechanism appears to be nucleophilic attack on the alkyl halide by the negatively charged copper atom but the details of the mechanism are not well understood Indeed there is probably more than one mechanism by which cuprates react with organic halogen compounds Vinyl halides and aryl halides are known to be very unreactive toward nucleophilic attack yet react with lithium dialkylcuprates... 

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. 

Thiol protection, 59, 190 Thiono esters, reaction with ethyl isocyanoacetate, 59,187 Thionyl chloride, 55, 27 Thiophenol, 55, 122 58, 144 Thorium dodecanedioate, 56,110 Toluene, 56, 86 58,125 p-Toluenesulfonates, reaction with organo-cuprates, 55,112 p-Toluenesulfonic acid, 58, 57, 63 p-Toluenesulfonic acid, monohydrate, 56,44... 

Asymmetric conjugate addition of dialkyl or diaryl zincs for the formation of all carbon quaternary chiral centres was demonstrated by the combination of the chiral 123 and Cu(OTf)2-C H (2.5 mol% each component). Yields of 94-98% and ee of up to 93% were observed in some cases. Interestingly, the reactions with dialkyl zincs proceed in the opposite enantioselective sense to the ones with diaryl zincs, which has been rationalised by coordination of the opposite enantiofaces of the prochiral enone in the alkyl- and aryl-cuprate intermediates, which precedes the C-C bond formation, and determines the configuration of the product. The copper enolate intermediates can also be trapped by TMS triflate or triflic anhydride giving directly the versatile chiral enolsilanes or enoltriflates that can be used in further transformations (Scheme 2.30) [110],... 

Scheme 4.10 gives some examples of application of alkyne carboalumination in synthesis. The reaction in Entry 1 was carried out as part of a synthesis of the immunosuppressant drug FK-506. The vinyl alane was subsequently transmetallated to a cuprate reagent (see Chapter 8). In Entry 2, the vinyl alane was used as a nucleophile for opening an epoxide ring and extending the carbon chain by two atoms. In Entries 3 to 5, the vinyl alane adducts were converted to vinyl iodides. In Entry 6, the vinyl alane was converted to an ate reagent prior to reaction with formaldehyde. 

Formation of the very unstable dehydroalanine derivatives A p-dimethylaminophe-nyl- and Af-p-nitrophenyhnethylenedehydroalanine methyl ester could only be verified by -NMR. Because of Michael-type reactions with cuprates, the iV-arylmethylenedehy-droalanine methyl esters have been applied as building blocks in the synthesis of amino acids.[18]... 

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