Ethers, enol, addition from enols

Others [180,260]). In general, enol radical cations may be obtained from either direct oxidation of stable ends or by selective oxidation of the enol tautomer of the keto/enol equilibrium. In addition it has been outlined that enol radical cations offer an access to a-carbonyl radical chemistry. Other enol systems like silyl enol ethers, enol esters and enolates similarly may open up after oxidation the chemistry of a-carbonyl radical or a-carbonyl cation intermediates, whereas enol ether oxidative a-functionalization reactions work by another route. 

Although ethereal solutions of methyl lithium may be prepared by the reaction of lithium wire with either methyl iodide or methyl bromide in ether solution, the molar equivalent of lithium iodide or lithium bromide formed in these reactions remains in solution and forms, in part, a complex with the methyllithium. Certain of the ethereal solutions of methyl 1ithium currently marketed by several suppliers including Alfa Products, Morton/Thiokol, Inc., Aldrich Chemical Company, and Lithium Corporation of America, Inc., have been prepared from methyl bromide and contain a full molar equivalent of lithium bromide. In several applications such as the use of methyllithium to prepare lithium dimethyl cuprate or the use of methyllithium in 1,2-dimethyoxyethane to prepare lithium enolates from enol acetates or triraethyl silyl enol ethers, the presence of this lithium salt interferes with the titration and use of methyllithium. There is also evidence which indicates that the stereochemistry observed during addition of methyllithium to carbonyl compounds may be influenced significantly by the presence of a lithium salt in the reaction solution. For these reasons it is often desirable to have ethereal solutions... 

Because of thetr electron deficient nature, fluoroolefms are often nucleophihcally attacked by alcohols and alkoxides Ethers are commonly produced by these addition and addition-elimination reactions The wide availability of alcohols and fliioroolefins has established the generality of the nucleophilic addition reactions The mechanism of the addition reaction is generally believed to proceed by attack at a vinylic carbon to produce an intermediate fluorocarbanion as the rate-determining slow step The intermediate carbanion may react with a proton source to yield the saturated addition product Alternatively, the intermediate carbanion may, by elimination of P-halogen, lead to an unsaturated ether, often an enol or vinylic ether These addition and addition-elimination reactions have been previously reviewed [1, 2] The intermediate carbanions resulting from nucleophilic attack on fluoroolefins have also been trapped in situ with carbon dioxide, carbonates, and esters of fluorinated acids [3, 4, 5] (equations 1 and 2)... 

The synthetic problem is now reduced to cyclopentanone 16. This substance possesses two stereocenters, one of which is quaternary, and its constitution permits a productive retrosynthetic maneuver. Retrosynthetic disassembly of 16 by cleavage of the indicated bond furnishes compounds 17 and 18 as potential precursors. In the synthetic direction, a diastereoselective alkylation of the thermodynamic (more substituted) enolate derived from 18 with alkyl iodide 17 could afford intermediate 16. While trimethylsilyl enol ether 18 could arise through silylation of the enolate oxygen produced by a Michael addition of a divinyl cuprate reagent to 2-methylcyclopentenone (19), iodide 17 can be traced to the simple and readily available building blocks 7 and 20. The application of this basic plan to a synthesis of racemic estrone [( >1] is described below. 

A high degree of syn selectivity can be obtained from the addition of enamines to nitroalkenes. In this case, the syn selectivity is largely independent of the geometry of the acceptor, as well as the donor, double bond. Next in terms of selectivity, are the addition of enolates. However, whether one obtains syn or anti selectivity is dependent on both the geometry of the acceptor and the enolate double bond, whereas anti selectivity of a modest and unreliable level is obtained by reaction of enol silyl ethers with nitroalkenes under Lewis acid catalysis. 

Simple 1,2,4-triazole derivatives played a key role in both the synthesis of functionalized triazoles and in asymmetric synthesis. l-(a-Aminomethyl)-1,2,4-triazoles 4 could be converted into 5 by treatment with enol ethers <96SC357>. The novel C2-symmetric triazole-containing chiral auxiliary (S,S)-4-amino-3,5-bis(l-hydroxyethyl)-l,2,4-triazole, SAT, (6) was prepared firmn (S)-lactic acid and hydrazine hydrate <96TA1621>. This chiral auxiliary was employed to mediate the diastereoselective 1,2-addition of Grignard reagents to the C=N bond of hydrazones. The diastereoselective-alkylation of enolates derived from ethyl ester 7 was mediated by a related auxiliary <96TA1631>. 

The reaction of acyclic ADC compounds with monoenes has already been discussed in Sections III,B and IV,B. In certain cases the major reaction pathway involves addition of the ADC compound as a 47r component, to the monoene to give 1,3,4-oxadiazines (Scheme 1). 1,3,4-Oxadiazines are the major or sole products from the reactions of ADC compounds with indene,80 and 4-nitrophenyl vinyl ether,90 and from the reaction of azodibenzoyl with enamines and enol ethers.91 93 Norbornadiene also gives a 1,3,4-oxadiazine (42) with ADC compounds.82 However, benzonorbornadiene behaves differently, and the major product from the reaction with PTAD has the structure 119.205 Other bicyclic monoenes react similarly.206 1,3,4-... 

Intramolecular Addition Formation of Cyclic Enol Ethers and Lactones from Pent-4-yn-1-ols and But-3-yn-1-ols... 

Thermal decomposition of y-lactone tosylhydrazone sodium salts are reported to yield cyclobu-tanones, which can be accounted for by rearrangement of an intermediate oxycarbene. In this manner, the sodium salts of dihydrofuran-2(37/)-one tosylhydrazones 1 were decomposed as a loose powder, at 310 C in a bulb-to-bulb distillation apparatus at an initial pressure of 0.1 Torr, to give the corresponding cyclobutanones 2 in addition to enol ethers, cyclopropanes and open-chain alkenes. Condensable products (74-76%) were collected at — 78 °C, weighed and the ratio of components was determined from their relative GC peak areas.63... 

Considerable use has also been made of allyl carbonates as substrates for the allylation of Pd enolates.9 The reaction of Pd° complexes with allyl enol carbonates119,120 proceeds by initial oxidative addition into the allylic C—O bond of the carbonate followed by decarboxylation, yielding an allylpalladium enolate, which subsequently produces Pd° and the allylated ketone (equation 22). In like fashion, except now in an intermolecular sense, allyl carbonates have been found to allylate enol silyl ethers (equation 23),121 enol acetates (with MeOSnBu3 as cocatalyst) (equation 24),122 ketene silyl acetals (equation 25)123 and anions a to nitro, cyano, sulfonyl and keto groups.115,124 In these cases, the alkoxy moiety liberated from the carbonate on decarboxylation serves as the key reagent in generating the Pd enolate. 

Vinyl ethers have also been prepared by addition of alkoxides to acetylene,6 7 6 elimination from halo ethers and related precursors,6 8 and vinyl exchange reactions.6 Reaction of an electrophilic tungsten carbenoid with methylene phosphorane or diazomethane also produces vinyl ethers.9 Enol ethers have resulted from the reaction of some tantalum and niobium carbenoids with esters,10 and the reaction of phosphoranes with electrophilic esters.4... 

Re-examination of the photolyses of the family of aryldisilanes PhRR Si—SiMe3 (R,R = Me, Ph) in solution containing acetone was found to give not only the previously observed products believed to be derived from an ene reaction between the silatriene and acetone, 12651, but in addition, and not previously observed, the [2 + 2] siloxetanes, 127, were detected and isolated, as were the silyl enol ethers 128 derived from the simple silene... 

A disadvantage of the described method is the necessity of using preformed benzyl enol ethers, which are usually not available from stock and whose synthesis is not always a simple task. In addition, benzyl enol ethers of ketones are not available. 

CO2-PEG system is also effective for the scandium-catalyzed aldol reactions, and poly(ethylene glycol) dimethyl ether (PEG(OMe)2, MW = 500) is more effective than PEG (Scheme 3.12) [57]. Emulsions in C02-PEG(0Me)2 medium are observed when the concentration of the additive is 1 g/L. Not only benzal-dehyde but also substituted aromatics, aliphatic, and a, /]-unsaturated aldehydes react smoothly, and various silicon enolates derived from a ketones, esters, and thioesters also react well to afford the corresponding aldol adducts in high yields. 

Modem variants of the Mukaiyama aldol addition start from silyl enol ethers, not from enol ethers, and use an aldehyde instead of the acetal as the electrophile. Mukaiyama aldol additions of this kind have been included in the C,C coupling reactions that build the basic repertoire of modem synthetic chemistry and can even be performed in a catalytic enantioselective fashion. 

The absolute configuration and enantiomeric excess of amino ketones 20 were evaluated by gas chromatography (GC) and, 3C NMR studies after conversion into the diastereomeric acetals 21. The reaction proceeds via addition of the nitrene 18 to the double-bond of 19. The yield and diastereoselectivity of this reaction were significantly enhanced when using chiral enol ethers 23, generated from C2 symmetric 22. The best result (36 % yield and 50 % ee) was obtained using a fivefold excess of reagent 6e and equimolar amount of triethylamine [12d] (Scheme 9). 

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