Enol esters, and

Photochemical oxacarbene formation, 307 Photochemical rearrangements of cross-conjugated cyclohexadienones, 330 Photochemical rearrangements of enol esters and enol lactones, 339... 

Due to the nonaromatic character of the oxepin system the oxepinones do not usually form stable enol structures. By O-acylation or O-alkylation, however, the enol forms can be stabilized as enol esters and ethers, respectively. A large number of substituted 1-benzoxepins have been synthesized by this route. Acetylation of l-benzoxepin-3(2//)-ones 1 and l-benzoxepin-5(2/T)-ones 3 was readily achieved with acetic anhydride in the presence of an appropriate base such as pyridine, triethylamine or sodium acetate.t5,t6 t72 176... 

See Section 362 (Ester-Alkene) for the formation of enol esters and Section 367 (Ether-Alkenes) for the formation of enol ethers. Many of the methods in Section 60A (Protection of Aldehydes) are also applicable to ketones. 

This section contains syntheses of enol esters and esters of unsaturated acids as well as ester molecules bearing a remote alkenyl unit. 

The DKR processes for secondary alcohols and primary amines can be slightly modified for applications in the asymmetric transformations of ketones, enol esters, and ketoximes. The key point here is that racemization catalysts used in the DKR can also catalyze the hydrogenation of ketones, enol esters, and ketoximes. Thus, the DKR procedures need a reducing agent as additional additive to enable asymmetric transformations. 

Hydrogenation of N-Acyl Enamides, Enol Esters and Enol Carbamates... 

Solutions of acetyl nitrate have also been used for the synthesis of a-nitroketones from enol esters and ethers. ° ... 

Silyl enol ethers, enol esters and alkyl enol ethers of ketones and aldehydes can be C-alkylated with reactive alkylating agents in the presence of Lewis acids86-90. However, information regarding the use of these reactions for diastereoselcctive or asymmetric synthesis is still limited. 

Perhaps the most useful type of alkene substrates for these reactions are enol ethers, enol esters and vinyl sulfides. Silyl enol ethers have excellent electron-donor properties, with an ionization potential of about 8 eV and an oxidation potential in various solvents of approximately 1.0-1.5 V vs SCE161. These compounds are easily synthesized by reaction of an enolate with a chlorosilane. (A very recent report synthesized a variety of silyl enol ethers with extremely high stereochemical yield, using the electrogenerated amidate of 2-pyrolidinone as the base.)162 An interesting point is that the use of oxidative or reductive cyclization reactions allows carbonyl functionalities to be ambivalent, either oxidizable or reducible (Scheme 65)163. 

Scheme 4. Preparation of enol esters and dienyl esters from terminal alkynes and carboxylic acids.

This section contains syntheses of enol esters and esters of unsaturated acids. 

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. 

Since the report by Carboni and Lindsey in 1959 on the cycloaddition reaction of tetrazines to multiple bonded molecules as a route to pyridazines, such reactions have been extensively studied. In addition to acetylenes and ethylenes, enol ethers, ketene acetals, enol esters and enamines, and even aldehydes and ketones have been used as starting materials for pyridazines. A detailed investigation of various 1,2,4, 5-tetrazines in these syntheses revealed the following facts. In [4 + 2] cycloaddition reactions of 3,6-bis(methylthio)-l,2,4,5-tetrazine with dienophiles, which lead to pyridazines, the following order of reactivity was observed (in parenthesis the reaction temperature is given) ynamines (25°C) > enamines (25-60°C) > ketene acetals (45-100°C) > enamides (80-100°C) > trimethylsilyl or alkyl enol ethers (100-140°C) > enol... 

Three independent syntheses of fukinone (335) have been published. In the first of these, Piers and Smillie ° converted the octalone (336), which they had previously used in connection with their synthesis of aristolone, into (337) by treatment with ethyl formate followed by catalytic reduction. Dehydrogenation of (337) with 2,3-dichloro-5,6-dicyanobenzoquinone and subsequent oxidation and esterification yielded (338). This keto-ester was converted into fukinone (335) by hydrogenation followed by methylation of the enolate ester and dehydration of the resultant keto-alcohol (339). Torrence and Finder have also completed the synthesis of fukinone using the octalone (336) as the key intermediate. 

Conversion Of Enolates to SUyl Enol Ethers, Silyl Enol Esters, and Silyl Enol Sulfonate Esters... 

The reaction of acid chlorides with zinc metal in an ethereal solvent usually resulted in esters arising from the acyl group and a portion of the solvent molecules [59, 60]. Later, Normant reported the formation of an enol ester and proposed the formation of an acylzinc followed by a 1,2-hydrogen rearrangement in zinc-oxy carbenoids (Eq. (5.54)) [61],... 

Dihydrocodeinone [65, 69-70], 1-bromodihydrocodeinone [69], 14-hydroxydihydrocodeinone [38], and the alkyldihydrocodeinones [65] can be converted into esters of the enol form by heating the ketones with acid anhydrides and sodium salts. The enol esters and their salts are stable even in hot solution, but they are hydrolysed to the original ketones by boding with acids [69]. Dihydrocodeinone enol acetate [liv] is marketed as the drug acedicon. 

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