Additions lithium butyl cuprate

Chiral aminals 1,4-dihydropyridine-3-carboxaldehydes.1 The chiral aminal 2 prepared from pyridine-3-carboxylaldehyde and (S,S)-12 reacts with organocopper reagents in the presence of methyl chloroformate to give almost exclusively products of 1,4-addition, as expected from reactions of the free aldehyde.3 No products of 1,2-addition are formed, but 1,6-adducts are minor products in some cases. The 1,4-adducts are formed in 82-93% de (R-configuration). Addition of butyl and ethyl groups is best effected with lithium cuprates, but addition of methyl, vinyl, or aryl groups is best effected with organomagnesium cuprates. Under these conditions,... 

CONJUGATE ADDITION Alkylmethyl-magncsiocuprates. 2-Carboethoxyl-benzyl phenyl sulfoxide. Cyanodiethyl-aluminum chloride. 1-Cyclopropyl-l-tiimethylsilyloxyethylene. Lithium 1,3-butadiene-l-olate. Lithium dimethyl-cuprate. Magnesium ethyl malonate. Potassium carbonate. Tri-n-butyl-stannyllithium. Trimethylzinclithium. 

The stannylcupration of alkynes has been widely studied. Reaction of alkynes with lithium bis(tributylstannyl) cuprate leads to r -2-(tri butyl stannyl) vinyl cuprates, which are synthetically equivalent to cis- 1,2-ethylene dianions. Addition of the tin-copper reagent across the triple bond occurs i>7/-stereospecifically, thus providing Z-vinylstannanes. Phenylacetylene reacts with the tin cuprate with a regiochemistry opposite to that of 1-decyne.294 The intermediate cuprates react well with the various electrophiles.295 For example, the reaction with ethylene oxide gives primary alcohols, and further treatment of their />-toluenesulfonates with butyllithium gives 1-substituted cyclobutenes (Equation (120)) 294... 

The construction of the naturally derived narbomycin and tylosin-aglycones by Masamune and coworkers employ identical methodology for seco-acid formation. In each case, Peterson alkenadon of a functionalized aldehyde (not shown) and the silyl ketones (96 R = SiMes Scheme 36) or (99 Scheme 37) efficiently introduced the required ( )-a,3-unsaturation. Silyl ketone formation is accomplished in each case through cuprate acylation by an activated carboxylic acid derivative. Formation of an acid chloride was not possible in the sensitive tylosin-aglycone intermediate however, selective acylation of the silylcuprate proceeded at the pyridyl thiol ester moiety of (98) and not with the r-butyl thiol ester. In a related investigation, (97), an advanced intermediate for 6-deoxyerythronolide B, was obtained from (95) via addition of lithium diethylcuprate to the acid chloride (84% yield). In all the above cases, no addition was observed at the f-butyl thiol ester. 

Just as anions of allyl derivatives can be homoenolate equivalents (chapter 13) so anions of vinyl derivatives can be acyl anion equivalents. Vinyl (or enol) ethers can be lithiated reasonably easily, especially when there is no possibility of forming an allyl derivative, as with the simplest compound 81. The most acidic proton is the one marked and the vinyl-lithium derivative 82 reacts with electrophiles to give the enol ether of the product17 84. However, tertiary butyl lithium is needed and compounds with y-CHs usually end up as the chelated allyl-lithium 85. These vinyl-lithium compounds add directly to conjugated systems but the cuprates will do conjugate addition.18... 

Lithium n butyl (phenylthio) cuprate has been used in nucleophilic substitution reactions of arenesulfonyl fluorides, al-lylic acetates, 9 BBN, propargyllc carbamates, and bromo-alkenes, as well as in nucleophilic additions to acetoxy-epoxides. It Is a good choice for 1,4-addItIon of an n-Bu group, having been used in 1,4 addition-elimination reactions of a-oxoketene dithloacetals and 3-halo-2-cycloalkenones, and in tandem vicinal dialkylation reactions of 5-methyleneoxa-zolones and alkynes. A typical example Is the use of the reagentin the stereospecific synthesis of (, -2-heptenoicacidfrom acetylene (eq 1). ... 

It has also been shown that reduction of the ethylenic bond in enones may occur via copper hydride derivatives formed by thermal decomposition of the lithium organocuprate. This can pose a problem since such decomposition occurs above 243 K in the temperature region where many cuprates are only beginning to react at appreciable rates with the substrate. However, addition of excess n-butyl-lithium appears to eliminate this complication. 

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