VINYLATION OF ENOLATES

VINYLATION OF ENOLATES WITH A VINYL CATION EQUIVALENT trans-3-METHYL-2-VINYLCYCLOHEXANONE... 

It has been shown that selective a-vinylation of enolate anions derived from 1,3-dicarbonyl compounds can be achieved by reaction with 4-/-butyl-1 -cyclohexenyl-(aryl)iodonium and 1-cyclopentenyl(aryl)iodonium tehafluoroborates without competing a-arylation, provided that the alkenyliodonium salt used bears a / -mcthoxyphcnyl, rather than phenyl, group.24... 

Enolate anions derived from various 1,3-dicarbonyl compounds can be viny-lated with cyclohexenyl- and cyclopentenyl- iodonium salts (Scheme 27) [50]. The vinylation of enolate anions 58 in these reactions is frequently accompanied by the formation of the phenylated dicarbonyl compounds however, the selectivity of these vinylations can be improved by using alkenyl(p-methoxyphenyl)-iodonium salts instead of 57. 

Buchwald and co-workers studied the a-arylation and a-vinylation of enolates derived from ketones with a binaphthyl monophosphine bearing a P-stereogenic atom (80, Scheme 8.31). 

Carbon-carbon bond formation by using metal enolates as synthons in organic chemistry and the protonation, alkylation, arylation, and vinylation of enolates have been reviewed. " The stereoselective carbon-carbon formation of bond through Mannich reaction has been detailed according to the type of Mannich base produced. Phosphine-catalysed asymmetric additions of malonate esters to y-substituted allenoates and aUenamides have been reported. ... 

Selectivity between a- and p-vinylation of enol ethers has been investigated again diphosphines and nitrogen-based ligands promote a-products. Cyclic enol ethers also remain popular substrates for asymmetric Heck reactions (40-96% ee). Use of hindered bases and BINAP facilitates these reactions. Similar strategies may be employed using 2-pyrrolines (up to 83% ee) or intramolecular arylations.446 Two examples of stereodirected Heck reactions and a kinetic resolution have also appeared... 

Vinylation of enolates have been performed using Fp (alkyl vinyl ether) complexes [Fp = CsH5Fe(CO)2] as vinyl cation equivalents (Scheme 51). ... 

The acid-catalyzed reaction of enol ethers 2 (X = OR) and enamines 2 (X = NR2) to form y-lactol derivatives proceeds with great ease even on silica gel chromatography. Vinyl sulfides 2 (X = SR) or vinyl chlorides 2 (X = Cl) are difficult to hydrolyze. 

Phenyl 2-(trimethylsilyl)ethynyl sulfone (118) can act as a vinyl cation synthon (equations 93 and 94)78 79. Thus, the reaction of enolates with 118 and subsequent desulfonylation of the adduct gives a-vinyl ketone, such as 119 and 120. 

An intramolecular version of enolate Michael addition to enantiomerically pure vinylic sulfoxides is represented by reaction of a cyclopentenone sulfoxide with dichloroketene (Scheme 5)90 this type of additive Pummerer rearrangement has been developed by Marino and coworkers91 into a highly effective way of constructing variously substituted lactones in very high enantiomeric purity (equation 43). 

Frequently, when the enol content is high, both forms can be isolated. The pure keto form of acetoacetic ester melts at — 39°C, while the enol is a liquid even at — 78°C. Each can be kept at room temperature for days if catalysts such as acids or bases are rigorously excluded.Even the simplest enol, vinyl alcohol (CH2= CHOH), has been prepared in the gas phase at room temperature, where it has a half-life of 30min. " The enol Me2C=CCHOH is indefinitely stable in the solid state at —78°C and has a half-life of 24h in the liquid state at 25°C. When both forms cannot be isolated, the extent of enolization is often measured by NMR. 

Ally lie ethers of enols (ally lie vinylic ethers) also undergo the Claisen rearrange-ment in fact, it was discovered with these compounds first ... 

However, the observations of Ward and Sherman need not rule out triple-bond participation and vinyl cations in the systems studied by Hanack and co-workers (75-79). Presumably, the enol formate 61 itself arises via a transition state involving a rate-determining protonation and vinyl cation 62 (see previous section). A vinyl cation such as 62 with an adjacent phenyl group is considerably more stable and hence more accessible than a vinyl cation such as 63, stabilized only by a neighboring alkyl group. Hence, formation of enol formate 61 and its... 

Unfortunately, it quickly became apparent that a shortfall in this proposal was an inability to prepare the desired vinyl halide 25 in a straightforward and selective manner [19]. In contrast, we reasoned that the selective formation of an enol sulfonate, such as the enol triflate 26a, could be controlled by judicious tuning of enolization conditions starting from the corresponding ketone, and that such an enol sulfonate would possibly be a substrate for a palladium-mediated coupling (Scheme 9.17). In this way a common intermediate from the previously defined synthesis, that is, the racemic ketone rac-13 or its cyano equivalent rac-5 could be used to generate the required enamide. 

The a-arylation of carbonyl compounds (sometimes in enantioselective version) such as ketones,107-115 amides,114 115 lactones,116 azlactones,117 malonates,118 piperidinones,119,120 cyanoesters,121,122 nitriles,125,124 sul-fones, trimethylsilyl enolates, nitroalkanes, esters, amino acids, or acids has been reported using palladium catalysis. The asymmetric vinylation of ketone enolates has been developed with palladium complexes bearing electron-rich chiral monodentate ligands.155... 

Boronic acids 96 and 97 couple very well with vinyl triflates 98 and 99 under typical Suzuki conditions (Pd(PPh3)4/Na2C03/LiCl/DME) to give indoles 100 and 101, respectively, in 76-92% yield [115, 116]. Enol triflates 98 and 99 were prepared in good yield (73-86%) from N-substituted 3-piperidones, wherein the direction of enolization (LDA/THF/-78 °C PhNTf2) is dictated by the tf-substituent. 

Acylation of enol ethers. Reaction of 1 with ethyl vinyl ether in ether provides an intermediate that undergoes dehydrochlorination when heated to provide the trichloromethyl ketone 2, which is converted by base (haloform reaction) to the ester 3 in high yield. 

Reipig (39,40), Pfaltz (41), and Andersson and their co-workers (42) independently showed that these catalysts are capable of effecting the selective cyclopropanation of enol ethers and enolsilanes. Methyl vinyl ketone and acetophenone enolsilanes provide high selectivities in the cyclopropane products, but both isomers are formed equally. The trisubstituted dihydropyran 65 leads to cyclopropane adducts in high diastereoselectivities and enantioselectivities using 55c CuOTf as catalyst. 

With ethoxypropadiene, the vinylic copper intermediate formed via the allylzinc-cation reacts with another molecule of ethoxyallene leading to the formation of enol ether 112 as an E-Z mixture [55],... 

The opportunity for tandem cyclization was explored. Here, the results can be accommodated by postulating the intermediacy of a vinyl radical [66]. For example, the controlled potential reduction of enol phosphate 246 affords 247 as a mixture of stereoisomers, in addition to a 15% yield of the linearly fused tricyclopentanoid 248. Assuming that the initial reduction cleaves the phosphate unit, then there exists the opportunity for the resulting radical 249 to be further reduced to afford a carbanion, or undergo a 5-exo-trig radical cyclization onto the pendant alkene. Given the nature of the products and the fact that they are inconsistent with the expectations of carbanion chemistry, it seems clear that the latter pathway dominates. 

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