Lithium homoenolate

The lithiation of y-chloro acetal 175 with lithium and a catalytic amount of naphthalene (4%) allowed the preparation of the intermediate 176, which can be considered as a masked lithium homoenolate, and was used for the preparation of the hydroxy ketone 179 through the hydroxy acetal 177 and dithiane 178 using known chemistry (Scheme 62)" . 

A completely different approach to lithium homoenolate synthons uses a carbon-oxygen bond cleavage. Lithiation of acrolein diethyl acetal 180 with lithium and a catalytic amount of DTBB (2.5%) in the presence of different carbonyl compounds in THF at 0°C gave, after final hydrolysis, the corresponding y-products 181 in different diastereomeric ratios (Z/ 3/1 to 20/1) (Scheme 63) . 

Lithium homoenolates derived from carboxylic acids were generated from the corresponding /3-chloro acids by means of an arene-catalyzed lithiation. Chloro acids 186 were deprotonated with n-butyllithium and lithiated in situ with lithium and a catalytic amount of DTBB (5%) in the presence of different carbonyl compounds to yield, after hydrolysis, the expected hydroxy acids (187). Since the purification of these products is difficult, they were cyclized without isolation upon treatment with p-toluenesulfonic acid (PTSA) under benzene reflux, into substituted y-lactones 188 (Scheme 64) . 

The rearrangement of l-(trimethylsilyl)allylic alcohols to 3-(trimethylsilyloxy)allyllithiums in the presence of base is a convenient source of lithium homoenolates. These can be alkylated to yield the corresponding silyl enol ethers. 

Unusual carbanions. Lithium homoenolates are formed from P-aryl-a,P-unsaturated ketones and esters. Their reaction with carbonyl compounds leads to y-lactols and lactones. Reductive dechlorination of a-chloroimines provides a-amino carbanions. Access to 1,2-amino alcohols is assured. 

Reductive lithiation of allylic acetals. This method provides masked lithium homoenolates, which are used in reactions with carbonyl substrates. 

Masked lithium homoenolates of type XII are of interest in synthetic organic chemistry and can be considered as three-carbon homologating reagents with umpolung reactivity [122]. The lithiation of the jS-chloro orthoester 147 with lithium in the presence of a catalytic amount of DTBB, under Barbier-reaction conditions, and using carbonyl compounds as electrophiles, followed by acidic hydrolysis, led to lactones 149 as reaction products, the masked lithium homoenolate 148 bang proposed as a reaction intermediate (Scheme 2.20) [123]. 

Eunctionalized organolithium compounds, having a protected carboxylic acid functionality, can also be considered as masked lithium tris-homoenolates and were prepared by DTBB-catalyzed (5%) Uthiation of the corresponding )-chlorinated materials. Eor instance, compound 227 in THE at —78°C leads to the expected organoUthium intermediate 228, which reacts with a series of electrophiles present in the reaction medium... 

Lithinm homoenolates 560 were generated by lithiation of enones 559 with lithium and a catalytic amonnt of naphthalene (4%) in the presence of different carbonyl com-ponnds as electrophiles and a Lewis acid (LiCl, TiCLj, SnBu4, SnCLj, BF3) in THF at... 

If the mesomeric stabilization is provided by a double bond, the lithiated species is a homoenolate synthon, as shown in Scheme 44a. Reaction with an electrophile typically occurs at the y-position, yielding an enamine, which can then be hydrolyzed to a carbonyl compound. An important application of this approach is to incorporate a chiral auxiliary into the nitrogen substituents so as to effect an asymmetric synthesis. 2-AzaaUyl anions (Scheme 44b), which are generated by tin-lithium exchange, can be useful reagents for inter- and intramolecular cycloaddition reactions. ... 

Homologation reaction of lithium enolates with bis(iodomethyl)zinc (58) yields a homoenolate, namely the organozinc derivatives bearing a carbonyl group at the /3 position (Scheme 6)55. Treatment of the lithium enolate of cyclohexanone, generated from the silyl... 

Treatment of 3-stannylpropionamide with two equivalents of butyllithium at low temperature (—78 °Q generates a similar dianionic homoenolate, which reacts with standard electrophiles Eq. (46) [43], It is interesting to note that the propionate moiety rather than the butyl groups is selectively cleaved off the tin in the tin-lithium exchange. 

Kleinman and co-workers 20 synthesized a lactone precursor to the (2/ ,46, 56 )- -hydroxy-ethylene dipeptide stereoselectively in four steps using the lithium salt of ethyl propiolate as a homoenolate equivalent. As summarized in Scheme 11, addition of ethyl lithiopropiolate to a protected a-amino aldehyde affords hydroxy acetylenic esters as a mixture of dia-stereomers. Reduction of the acetylene group and subsequent lactonization gives a readily separable (4S)-lactone-enriched mixture. Direct alkylation with alkyl halide and lithium hexamethyldisilanazide yields the tram-lactone as the major stereoisomer. 

Barluenga and Yus showed that reductive lithation with naphthalene was nonetheless an effective way of making functionalised organolithiums. The (3-oxygenated species such as 11 are stable below -78 °C provided the lithium is at a primary centre (above this temperature they decompose with elimination of Li20) and can be formed by reductive lithiation of the lithium alkoxide 10.22 25 The amide 12 behaves similarly,26 and protected aldehyde 14 yields homoenolate equivalent 15.27... 

This volume, which complements the earlier one, contains 9 chapters written by experts from 7 countries. These include a chapter on the dynamic behavior of organolithium compounds, written by one of the pioneers in the field, and a specific chapter on the structure and dynamics of chiral lithium amides in particular. The use of such amides in asymmetric synthesis is covered in another chapter, and other synthetic aspects are covered in chapters on acyllithium derivatives, on the carbolithiation reaction and on organolithi-ums as synthetic intermediates for tandem reactions. Other topics include the chemistry of ketone dilithio compounds, the chemistry of lithium enolates and homoenolates, and polycyclic and fullerene lithium carbanions. 

Aldol-iype Condensation. Dimetalation of (R)-(+)-3-(p-tolylsulfinyl)propionic acid with Lithium Diisopropylamide produces a chiral homoenolate dianion equivalent which reacts with carbonyl compounds to afford p-sulfinyl-y-hydroxy acids these spontaneously cyclize to give the corresponding p-sulfinyl 7-lactones (eq 2) ... 

Trimethylsiloxy cyanohydrins (9) derived from an a,3-unsaturatied aldehyde form ambident anions (9a) on deprotonation. The latter can react with electrophiles at the a-position as an acyl anion equivalent (at -78 C) or at the -y-position as a homoenolate equivalent (at 0 C). The lithium salt of (9) reacts exclusively at the a-position with aldehydes and ketones. The initial kinetic product (10) formed at -78 C undergoes an intramolecular 1,4-silyl rearrangement at higher temperature to give (11). Thus the initial kinetic product is trapped and only products resulting from a-attack are observed (see Scheme 11). The a-hydroxyenones (12), -y-lactones (13) and a-trimethylsiloxyenones (11) formed are useful precursors to cyclopentenones and the overall reaction sequence constitutes a three-carbon annelation procedure. 

The lithium salt of the unsaturated a-amtnonitrile (39) reacts as a homoenolate ( y-attack) with aldehydes or ketones to give 1,2-addition products (40). Deprotonadon of the masked carbonyl affords substituted lactones (equation 23). ... 

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