Ketones, reaction with acid dianions

On quenching the reaction with acid, this dianion is protonated twice to give the enol of an a-hydroxy-ketone, and it is this a-hydroxy-ketone that is the final product of the acyloin reaction. The yield in this example is a quite respectable 70%. However, in many other cases, this usefulness of the acyloin reaction is hampered by the formation of by-products that arise because of the reactivity of the enediolate dianion. It is, of course, quite nucleophilic, and is likely to be formed in the presence... 

Nitroalkenes react with lithium dianions of carboxylic acids or with hthium enolates at -100 °C, and subsequent treatment of the Michael adducts with aqueous acid gives y-keto acids or esters in a one-pot operation, respectively (Eq. 4.52).66 The sequence of Michael addition to nitroalkenes and Nef reaction (Section 6.1) provides a useful tool for organic synthesis. For example, the addition of carbanions derived from sulfones to nitroalkenes followed by the Nef reaction and elimination of the sulfonyl group gives a,P-unsaturated ketones (Eq. 4.53).67... 

Organoytterbium chemistry has been developed in the last 20 years, although the development rate is much slower than the other lanthanides like samarium or cerium. Dianionic complexes that are produced from the reaction of ytterbium with diaryl ketones react with various kinds of electrophiles including carbon-heteroatom unsaturated bonds.35 Phenylytterbium iodide, a Grignard-type reagent, is known to have reactivity toward carbon dioxide,36 aldehydes, ketones,37,37 and carboxylic acid derivatives38,3811 to form the corresponding adducts respectively. 

A few years ago, Blagonev and Ivanov described the bis-deprotonation of aryl acetic acids by Grignard reagents. These magnesinm dianions, known as Ivanov reagents, react with aldehydes and ketones. Reaction between dianions of phenylacetic acid and benzaldehyde yields the anti S-hydroxy acid as the major diastereomer anti/syn 69/22) (equation 113). This result is in agreement with the formation of a cyclic chair-like transition state according to the model of Zimmerman-Traxler . 

Enolate hydroxylation is a problem of long standing. Direct oxygenation succeeds with the fully substituted enolates of certain a,a-disubstituted ketones and a variety of carboxylic acid derivatives (ester anions, acid dianions, amide anions), but the reaction of enolates, RCH = C(0 )R or CH2 = C(0 )R, with oxygen results in complex products of overoxidation. The stable... 

The first step in the overall synthetic scheme (Scheme 6) is the condensation of an appropriate carboxylic acid with trifluoroacetaldehyde. The carboxylic acid is chosen to impart specificity for the target enzyme. In one example,[28 the dianion of cyclohexanepropanoic acid (29) was formed by the addition of LDA and then quickly condensed with trifluoroacetaldehyde to form the p-hydroxy acid 30 as a racemic mixture of erythro- and threo-isomers. The p-hydroxy acid 30 is then protected with TBDMSOTf forming 31. Diphenyl phosphorazidate, TEA, and benzyl alcohol were then utilized in a Curtius rearrangement of the protected alcohol 31, which proceeds through an isocyanate intermediate that yields the protected amino alcohol 32 upon reaction with benzyl alcohol. In order for this step to occur at an appreciable rate, a second equivalent of triethylamine had to be added. The amino alcohol 32 was then deprotected and coupled with Boc-Phe-Leu-OH to give the trifluoromethyl alcohol 33, which was oxidized to the corresponding trifluoromethyl ketone 34 as a 1 1.2 mixture of diastereomers using the Dess-Martin periodinane procedure. Thus far, the compound shown in Scheme 6 is the only compound that has been synthesized by this method, but it is reasonable to assume that many other similar fluoro ketones can be produced by this scheme. 

Generally, ester enolates of structure (202 R = M, R = Oalkyl) rearrange via a 3,3-shift, whereas the corresponding amide enolates (202 R = M, R = N(alkyl)2) and acid dianions (202 R = M, R = OM) prefer the 2,3-pathway (equation 20). Both pathways have been observed with ketone enolates (202 R = M, R = alkyl). With substrate (179), Koreeda and Luengo observed only traces of Wittig rearrangement product (205), except for the lithium enolate, where (205) accounted for up to 20% of the reaction mixture (equation 21). ° Thomas and Dubini, however, reported predominant formation of 2,3 Wittig products (207) and (209) under base treatment of ketones (206) and (208) (equation 22). ... 

Carboxylic acid derivatives such as esters and amides undergo nucleophilic acyl substitution reactions with the ketone dianion derived fiom benzophenone, providing modest yields of the corresponding carbonyl products (equations 102 and 103). Benzhydrol is a significant by-product in these reactions. 

Ketones do not undergo fluoride-mediated reactions with silyl nitronates. However, enhancement of the C-nucleophilicity of nitronates has been achieved by double deprotonation at -90 °C with -butylli-thium in THF in the presence of at least 2 equiv. of HMPA (equation 21). Under these conditions, the residual proton of the monolithium salt, the acidity of which has been indicated to be in the same range as that of diisopropylamine, is metallated to give the dianion. 

The first step in this transform comprises formation of a radical dianion (1-2) from reaction of at the sites of lowest electron density (Scheme 4.1). In the case of steroids, this requirement rules out all but positions 1,4 of the aromatic ring A. The charges on the intermediate then strip protons from the alcohol in the reaction medium to yield the dihydrobenzene 1-3. The alcohol, frequently tert-butanol, thus acts as a quench. The enol ether function in the product is sufficiently robust to serve as a protecting group in many subsequent reactions. Mild acid hydrolysis of that enol ether affords the surprisingly stable unconjugated ketone 1-4. Treatment of this last intermediate with mineral acid causes the unsaturation to move over into conjugation at C4 (1-5). 

B.vii. Acid Dianions. All of the named reactions discussed in Section 9.4 constitute relatively minor variations of the fundamental condensation reaction of aldehydes, ketones, or acid derivatives with another aldehyde, ketone, or acid derivative. The ability to produce kinetic enolates from acid derivatives has made possible another useful modification of the enolate reaction. Carboxylic acids have an acidic proton that is removed by 1 equivalent of base to first give a carboxylate (see 226). Addition of a second equivalent of a powerful base such as a dialkylamide leads to the dianion (227). Subsequent reaction with an electrophilic species, in this case 1-bromobutane, occurred first at the more nucleophilic a-carbon to give hexanoic acid. 2 The carboxylate is usually generated with n-butyllithium and the enolate with LDA, although 2 equivalents of LDA can be used. As discussed in Chapter 8, treatment of a carboxylic acid with an excess of an organo-... 

Dianions of this type react with ketones, epoxides,and esters " as well as a wide variety of other electrophiles. As an example, the dilithio anion of 2-methylpropionic acid was condensed with the epoxide moiety in 229 to form an hydroxy acid, which cyclized to form the lactone ring in 230. Since most of the enolates of acid derivatives contain a leaving group, the alkoxide resulting from reaction with an epoxide often displaces that leaving group to give the lactone. 

Dihydroisocoumarins are conveniently obtained from the reaction of aldehydes and ketones with the dianions derived from o-toluic acids, though the products are not always stereochemically pure (94SC779). However, enantiomerically pure dihydroisocoumarins result from the stereoselective reduction of (arene)-tricarbonylchromium cmnplexes of homobenzylic ketones by DIB ALH, followed by oxidation of the resulting lactols (94CCS01). 

The deprotonation of tetrahydrofuran-2-carboxylic acid with two equivalents of lithium diisopropylamide allows additional functionality to be introduced at the 2-position <92TL6783>. In the case of the reactions of the dianion with ketones, the 2-jS-hydroxytetrahydrofuran-2-carboxylic acids that are formed can be converted into the exocyclic methylene derivatives by a process that... 

The dianions of a-halocarboxylic acids give epoxy acids (called glycidic acids) on reaction with aldehydes and ketones. 

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