Enolate ions silyl enol ethers

Selective fluonnation in polar solvents has proved commercially successful in the synthesis of 5 fluorouracil and its pyrimidine relatives, an extensive subject that will be discussed in another section Selective fluonnation of enolates [47], enols [48], and silyl enol ethers [49] resulted in preparation of a/phn-fluoro ketones, fieto-diketones, heta-ketoesters, and aldehydes The reactions of fluorine with these functionalities is most probably an addition to the ene followed by elimination of fluonde ion or hydrogen fluoride rather than a simple substitution In a similar vein, selective fluonnation of pyridmes to give 2-fluoropyridines was shown to proceed through pyridine difluondes [50]... 

The combination of silyl enol ethers and fluoride ion provides more reactive anions to give alkylated nitre compounds in good yields after oxidation v/ith DDQ, as shovm in Eq. 9.22. This process provides a new method for synthesis of indoles and oxyindoles fsee Chapter 10, Symhesis of Hatarocydic Compoioids). 

Amidoalkylation of silyl enol ethers with /V-acyliiiiiiiium ions containing camphanoyl-derived acyl functions (see Appendix) as the chiral auxiliary leads to optically active 2-substituted piperidine derivatives with moderate to high diastereoselectivity, depending on the chiral auxiliary and the cnol ether82 99. The auxiliary is removed by hydrolysis with base or acid. 

The chiral (V-camphanoyl iminium ion 7, prepared by hydride abstraction from 2-camphanoyl-l,2,3,4-tetrahydro-6,7-dimethoxyisoquinoline 6 (see Appendix) with triphenylcarbenium te-trafluoroborate, reacts with silyl enol ethers to give 1-substituted tetrahydroisoquinoline derivatives with reasonable diastereoselectivity, 0°. On addition of titanium(IV) chloride, prior to the addition of the silyl enol ether, the diastereoselectivity gradually rises to an optimum at 2.5 equivalents of the Lewis acid, but the yield drops by 20%. 

Formal Enolate Generation by Fluoride Ion, Increasing the Nucleophilicity of the Silyl Enol Ether... 

Kuwajima (75) has provided full details of the regiospecific monoalkylation of carbonyl compounds via their silyl enol ethers, using stoichiometric amounts of fluoride ion. Noyori (76) has given more information on the use of the complex fluoride source (2) (Chapter 18)... 

This area of reactivity has been the subject of excellent reviews (J5). Silyl enol ethers are not sufficiently nucleophilic to react spontaneously with carbonyl compounds they do so under the influence of either Lewis acids or fluoride ion, as detailed above. Few clear trends have emerged from the somewhat limited number of definitive studies reported so far, with ambiguities in diastereoisomeric assignments occasionally complicating the issue even further. 

The enol acetates, in turn, can be prepared by treatment of the parent ketone with an appropriate reagent. Such treatment generally gives a mixture of the two enol acetates in which one or the other predominates, depending on the reagent. The mixtures are easily separable. An alternate procedure involves conversion of a silyl enol ether (see 12-22) or a dialkylboron enol ether (an enol borinate, see p. 560) to the corresponding enolate ion. If the less hindered enolate ion is desired (e.g., 126), it can be prepared directly from the ketone by treatment with lithium diisopropylamide in THE or 1,2-dimethoxyethane at —78°C. ... 

Certain other metal ions also exhibit catalysis in aqueous solution. Two important criteria are rate of ligand exchange and the acidity of the metal hydrate. Metal hydrates that are too acidic lead to hydrolysis of the silyl enol ether, whereas slow exchange limits the ability of catalysis to compete with other processes. Indium(III) chloride is a borderline catalysts by these criteria, but nevertheless is effective. The optimum solvent is 95 5 isopropanol-water. Under these conditions, the reaction is syn selective, suggesting a cyclic TS.63... 

The use of /i-ketocstcrs and malonic ester enolates has largely been supplanted by the development of the newer procedures based on selective enolate formation that permit direct alkylation of ketone and ester enolates and avoid the hydrolysis and decarboxylation of ketoesters intermediates. Most enolate alkylations are carried out by deprotonating the ketone under conditions that are appropriate for kinetic or thermodynamic control. Enolates can also be prepared from silyl enol ethers and by reduction of enones (see Section 1.3). Alkylation also can be carried out using silyl enol ethers by reaction with fluoride ion.31 Tetraalkylammonium fluoride salts in anhydrous solvents are normally the... 

Fluoride ion can also induce reaction of silyl enol ethers with electrophilic alkenes. 

The reaction of Cjq with silylated nucleophiles [47] requires compounds such as silyl ketene acetals, silylketene thioacetals or silyl enol ethers. It proceeds smoothly and in good yields in the presence of fluoride ions (KF/18-crown-6) (Scheme 3.10). The advantage of the latter synthesis is the realization of the cyclopropanation under nearly neutral conditions, which complements the basic conditions that are mandatory for Bingel reactions. Reaction with similar silyl ketene acetals under photochemical conditions and without the use of F does not lead to methanofullerenes but to dihydrofullerene acetate [48]. 

Methyl y-oxocarboxytates.2 Silyl enol ethers react with methyl diazoacelate in the presence of a copper salt to form siloxy-substituted cyclopropancs (1) in useful yields. Cleavage of the siloxy group with fluoride ion (4, 477 478) affords y-oxo esters (2) in good yields. 

Corriu and coworkers have reported an alternative procedure for the conjugate addition of ketones to a.P-unsaturated acceptors which employs CsF-(RO)4Si (Scheme 56) 126 this procedure affords adducts with a,3-enones, oc.fj-unsaturated esters and a,3-unsaturated amides. Mechanistically, silyl enol ether formation occurs initially, followed by fluoride ion catalyzed enolate formation. 

Photolysis of /V-(diphcnylainmo)-2.4.6-tnmcthylpyridinium tetrafluoroborate (37) generates diarylnitrenium ion (38) as revealed by its reaction with electron-rich alkenes (silyl enol ethers and allylsilanes) to give products of substitution at para- and ortho-positions (39) and (40) (Scheme ll).47... 

On the other hand, indirect anodic oxidation of cyclic silyl enol ethers in the presence of iodide ions gives a-iodocyclic ketones (equation 39)43. 

Fluoride ion-catalysed addition of trifluoromethyltrimethylsilane to acyl silanes occurs to give l,l-difluoro-2-trimethylsilyloxyalkenes (silyl enol ethers of difluoromethyl ketones), through nucleophilic addition of trifluoromethyl anion, Brook rearrangement and loss of fluoride. These compounds could be isolated when tetrabutylammonium difluorotriphenylstannate was used as a catalyst use of tetrabutylammonium fluoride gave the product corresponding to subsequent aldol reaction with the difluoromethyl ketone (Scheme 78)m. 

Reaction of triisopropylsilyl enol ether with a combination of iodosylbenzene 18 and trimethylsilyl azide at -15 °C gives directly the /J-azido triisopropylsilyl enol ether 38 in a high yield. A mechanism involving the reductive -elimination of a-iodanyl onium ion 37, probably produced by ligand exchange of in situ generated PhI(N3)OTMS with silyl enol ether, was proposed. Addition of azide to the resulting a,/l-unsaturated onium ion explains the formation of 38 [58,59]. 

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