Ketones metal enolates

Enantioselective protonation of ketone metal enolates constitutes an important method for the preparation of optically active ketones. Fuji and coworkers have shown interest in the magnesium countercation in the enantioselective protonation of such enolates. Pertinent results are obtained with protonation of Mg(II) enolates of 2-alkyltetralones and carbamates derived from l,l -binaphtalene-2,2 -diol as chiral proton sources, as indicated in equation 82 and Table 11. 

As first demonstrated by Stork,the metal enolate formed by metal-ammoni reduction of a conjugated enone or a ketol acetate can be alkylated in liquic ammonia. The reductive alkylation reaction is synthetically useful since ii permits alkylation of a ketone at the a-position other than the one at whicf thermodynamically controlled enolate salt formation occurs. Direct methyl-ation of 5a-androstan-17-ol-3-one occurs at C-2 whereas reductive methyl-... 

Addition Reactions of Metal Enolates of Non-stabilized Esters, Amides, and Ketones to Epoxides... 

In spite of their intrinsic synthetic potential, addition reactions of metal enolates of non-stabilized esters, amides, and ketones to epoxides are not widely used in the synthesis of complex molecules. Following the seminal work of Danishefsky [64], who introduced the use of Et2AlCl as an efficient catalyst for the reaction, Taylor obtained valuable spiro lactones through the addition reaction of the lithium eno-late of tert-butyl acetate to spiro-epoxides, upon treatment of the corresponding y-... 

In the general context of donor/acceptor formulation, the carbonyl derivatives (especially ketones) are utilized as electron acceptors in a wide variety of reactions such as additions with Grignard reagents, alkyl metals, enolates (aldol condensation), hydroxide (Cannizzaro reaction), alkoxides (Meerwein-Pondorff-Verley reduction), thiolates, phenolates, etc. reduction to alcohols with lithium aluminum hydride, sodium borohydride, trialkyltin hydrides, etc. and cyloadditions with electron-rich olefins (Paterno-Buchi reaction), acetylenes, and dienes.46... 

With conjugated enone substrates, the alkoxymetallation leads to the formation of a metal enolate that can undergo a facile protonation to accomplish the hydroalkoxylation. Following this mechanism, various /3-alkoxyketones were obtained in good yields by the addition of primary and secondary alcohols to methyl vinyl ketone under cationic Pd(n) catalysis.443 Similarly, [Rh(COD)(OMe)]2 was found to catalyze the hydroalkoxylation of both methyl vinyl ketone and phenyl vinyl ketone (Equation (121)).444... 

One of the first careful studies of the influence of chirality proximal to ketone enolates is illustrated in eq. [95] (113). Condensation of the enolate 126 (M = Li) with propanal (THF, -100 C) afforded a modest bias for the (5,i )-diastereomeric aldol adduct 127 (127 128 = 57 43). The influence of the metal center in this condensation has recently been examined. The boryl enolate 126 [M = B(n-C4H9)2l afforded a ratio 127 128 = 64 36 in pentane (-78°C) (6a, 113). Similar studies designed to probe the dependence of diastereoface selection on metal enolate structure have been carried out with metal enolates 129 (eq. [96], Table 32). 

A new chiral proton source (111), based on an asymmetric 2-oxazoline ring, has been found to be capable of effecting asymmetric protonation of simple prochiral metal enolates (112) to give corresponding ketones (113) which need not bear polar groups. 

It is important that the indicator color, showing a small excess of strong base, not be discharged completely since the presence of any excess enol acetate or ketone will permit equilibration of the isomeric metal enolates. Consequently, the addition of this reactant is complete if further additions will discharge completely the color of the indicator. 

Felhnann and Dubois have described the structure of the enolate 29 derived from the reaction of f-butyl acetate with (MeO)2Mg. The NMR spectrum reveals two O-metallated species, which should be symmetric enolates as proposed by Pinkus and Wu for the bromomagnesium enolate of methyhnesityl ketone (metal is tricoordinated). ... 

Schmidtke H-H (1994) Vibrational Progressions in Electronic Spectra of Complex Compounds Indicating Stron Vibronic Coupling. 171 69-112 Schmittel M (1994) Umpolung of Ketones via Enol Radical Cations. 169 183-230 Schonherr T (1997) Angular Overtap Model Applied to Transition Metal Complexes and dN-Ions in Oxide Host Lattices. 191 87-152... 

Reviews on stoichiometric asymmetric syntheses M. M. Midland, Reductions with Chiral Boron Reagents, in J. D. Morrison, ed., Asymmetric Synthesis, Vol. 2, Chap. 2, Academic Press, New York, 1983 E. R. Grandbois, S. I. Howard, and J. D. Morrison, Reductions with Chiral Modifications of Lithium Aluminum Hydride, in J. D. Morrison, ed.. Asymmetric Synthesis, Vol. 2, Chap. 3, Academic Press, New York, 1983 Y. Inouye, J. Oda, and N. Baba, Reductions with Chiral Dihydropyridine Reagents, in J. D. Morrison, ed., Asymmetric Synthesis, Vol. 2, Chap. 4, Academic Press, New York, 1983 T. Oishi and T. Nakata, Acc. Chem. Res., 17, 338 (1984) G. Solladie, Addition of Chiral Nucleophiles to Aldehydes and Ketones, in J. D. Morrison, ed., Asymmetric Synthesis, Vol. 2, Chap. 6, Academic Press, New York, 1983 D. A. Evans, Stereoselective Alkylation Reactions of Chiral Metal Enolates, in J. D. Morrison, ed., Asymmetric Synthesis, Vol. 3, Chap. 1, Academic Press, New York, 1984. C. H. Heathcock, The Aldol Addition Reaction, in J. D. Morrison, ed., Asymmetric Synthesis, Vol. 3, Chap. 2, Academic Press, New York, 1984 K. A. Lutomski and A. I. Meyers, Asymmetric Synthesis via Chiral Oxazolines, in J. D. Morrison, ed., Asymmetric Synthesis, Vol. 3, Chap. 

Tetr 32 2979 (1976) (regiospecific preparation of ketone enolates and synthetic uses) 33 2737 (1977) (structure and reactivity of alkali metal enolates)... 

This work raises the possibility that some eryfAro-selective aldol condensations with metal enolates may actually involve the a-metallo ketone. 

Alkali metal enolates of ordinary ketones and aldehydes tend to fail to undergo the Tsuji-Trost allylation.37 However, it has been found that their enoxyborates and zinc enolates52 readily undergo the Pd catalysed allylation which proceeds with net retention just like the other examples of the... 

The design for a direct catalytic asymmetric aldol reaction of aldehydes and unmodified ketones with bifunctional catalysts is shown in Figure 36. A Brpnsted basic functionality (OM) in the heterobimetallic asymmetric catalyst (I) could deprotonate the a-proton of a ketone to generate the metal enolate (II), while at the same time a Lewis acidic functionality (LA) could activate an aldehyde to give (III), which would then react with the metal enolate (in a chelation-controlled fashion) in an asymmetric environment to afford a P-keto metal alkoxide (IV). 

The addition of an alkaline earth metal enolate A to a carbonyl compound is always an exer-gonic process irrespective of whether the enolate is derived from a ketone, an ester, or an amide and whether the carbonyl compound is an aldehyde or a ketone (Figure 13.44, top). One of the reasons for this exergonicity hes in the fact that the alkaline earth metal ion is part of a chelate in the alkoxide B of the aldol addition product. The driving forces for the additions of alkaline earth metal enolates of esters and amides to carbonyl compounds are further increased because the aldol adducts B are resonance-stabilized, whereas the enolates are not. 

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