Homoenolates reaction with carbonyl compounds

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. 

Allyltitanium complexes derived from a chiral acetal have been reacted with carbonyl compounds and imines [63], While the chiral induction proved to be low with carbonyl compounds, high induction was observed with imines. This complex represents the first chiral homoenolate equivalent that reacts efficiently with imines. Finally, the reactions with electrophiles other than carbonyl compounds and imines, namely a proton source, NCS, and I2, furnished the corresponding alkene, chloro, and iodo derivatives in good yields [64]. 

The reaction of the siloxycyclopropane with titanium(IV) chloride produces the titanium homoenolate (3-titaniopropionate) in good yield this, however, is relatively unreactive (eq 2). Addition of one equivalent of Ti(OR )4 generates a more reactive RTiChOR species, which smoothly reacts with carbonyl compounds below room temperature. The y-hydroxy ester adducts are useful synthetic intermediates and serve as precursors to y-lactones and cyclopropanecarboxylates. A useful variation involves the use of the cyclopropanecarboxylate ester as a functionalized homoenolate precursor to obtain levulinic acid derivatives (eq 3). ... 

An alternative formation of titanated alkoxyallenes could be achieved by reaction of 3-alkoxy-2-propyn-l-yl carbonates 78 with (r/2-propene)titanium diisopropoxylate (79). Successive addition of 80 to benzaldehyde afforded the corresponding addition products 81 in high yield (Scheme 8.22) [70]. The results demonstrate that titanium species 75 and 80 can serve as easily available ester homoenolate equivalents. Notably, conversion of lithiated alkoxyallenes to the magnesium species by treatment with MgBr2 followed by addition to chiral carbonyl compounds resulted in a mixture of a- and y-products [71]. 

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. ... 

In 1977, an article from the authors laboratories [9] reported an TiCV mediated coupling reaction of 1-alkoxy-l-siloxy-cyclopropane with aldehydes (Scheme 1), in which the intermediate formation of a titanium homoenolate (path b) was postulated instead of a then-more-likely Friedel-Crafts-like mechanism (path a). This finding some years later led to the isolation of the first stable metal homoenolate [10] that exhibits considerable nucleophilic reactivity toward (external) electrophiles. Although the metal-carbon bond in this titanium complex is essentially covalent, such titanium species underwent ready nucleophilic addition onto carbonyl compounds to give 4-hydroxy esters in good yield. Since then a number of characterizable metal homoenolates have been prepared from siloxycyclopropanes [11], The repertoire of metal homoenolate reactions now covers most of the standard reaction types ranging from simple... 

Next to the cyclopropane formation, elimination represents the simplest type of a carbon-carbon bond formation in the homoenolates. Transition metal homoenolates readily eliminate a metal hydride unit to give a,p-unsaturated carbonyl compounds. Treatment of a mercurio ketone with palladium (II) chloride results in the formation of the enone presumably via a 3-palladio ketone (Eq. (24), Table 3) [8], The reaction can be carried out with catalytic amounts of palladium (II) by using CuCl2 as an oxidant. Isomerization of the initial exomethylene derivative to the more stable endo-olefin can efficiently be retarded by addition of triethylamine to the reaction mixture. 

In line the with the chemistry of dialkylzinc [36], the zinc homoenolate is inert to carbonyl compounds in a variety of solvents, Eq. (33). Slow addition accurs only in an HMPA/THF mixture. When the reaction is conducted in halomethane in the presence of Me3SiCl, however, a very rapid addition reaction occurs [33], Control experiments indicate that the acceleration is due to the activation of the carbonyl group by Me3SiCl. The activating effect of the chlorosilane disappears in ethereal solvents. 

Yet another development which is worth mentioning in this context is the 5n substitution of acetals of unsaturated carbonyl compounds. The phenomenon that the reaction of an allylic acetal with a Grignard reagent in the presence of CuBr may occur as a vinylogous substitution with double bond shift has been long known.The reaction can be utilized in an efficient synthesis of 3-substituted propionaldehydes using the acrolein acetal as a homoenolate cation equivalent (Scheme 38). ... 

Perhaps the only true homoenolates used in synthesis are derived by metallation of derivatives of 3-haloacids. The acids themselves 12 give lithium 3-halocarboxylates 13 and hence by metallation the homoenolate which probably exists as 15, an analogue of the dilithium enolates of carboxylic acids (chapter 2). Reaction 16 with aldehydes or ketones gives y-lactones 19, by a homoaldol reaction via y-hydroxyacids 18, common products from addition of acid homoenolates to carbonyl compounds.3... 

In line with the chemistry of dialkylzincs, pure zinc homoenolates (9), which can be generated by the reaction of a silyloxycyclopropane (8) with ZnCh, are inert to carbonyl compounds in ethereal solvents. By contrast, when the reaction is conducted in halomethanes in the presence of MesSiCl, rapid addition occurs. The accelerating effect of the chlorosilane disappears in ethereal solvents (Scheme 15). ... 

In the presence of a Lewis acid, alkyl 2-silyloxycyclopropanecarboxylates (14) react with a wide range of carbonyl compounds to give a diester (15), which has b n converted to a variety of furan derivatives (Scheme 18). An interesting use of the oxyanionic tautomer of a homoenolate involves the reaction of a magnesium cyclopropanolate (12) with the lithium enolate of cyclohexanone, from which a tricyclic ring containing a functionalized cycloheptanone (13) is formed in a single step (Scheme 18). ... 

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