Enolates Fries rearrangement

A second process that occurs concurrently with the dissociation— redistribution process is an intermolecular rearrangement by which cyclohexadienone groups move along a polymer chain. The reaction maybe represented as two electrocycHc reactions analogous to a double Fries rearrangement. When the cyclohexadienone reaches a terminal position, the intermediate is the same as in equation 8, and enolization converts it to the phenol (eq. 9). 

The photo-Fries rearrangement of aryl hydrogen (or methyl) succinates 267 leads to 4-(2-hydroxyaryl)-4-oxobutanoic acids (or methyl esters 268), which are readily cyclized to 5-(2-acetoxyaryl)-2(3//)-furanones (269) (Scheme 68). [189-191] Photolysis of 269 [191] or the analogous open-chain enol acetates [192,193] leads to chromones. 

P-Keto acids 34 can be converted into 5,6-dialkyl-4-hydroxypyran-2-ones by thermolysis of the Meldrumls acid derivatives 35. A Fries rearrangement of the derived enol acylates and reduction of the resulting 3-acylpyranone with EtjSiH provides a route to the 3,6-dialky Ipyranones 36 (Scheme 17) <99T4783>. 

The Fries rearrangement of phenol esters gives a mixture of 2- and 4-acylphenols. Similarly, enol esters undergo rearrangement to give the corresponding 1,2-di ketones. 

The enol ester (307) undergoes a photo-Fries rearrangement, giving a (3-diketone, isolated in its enolic form (308).245... 

In the presence of a stoichiometric amount of SbCls, Friedel-Crafts acylation proceeds with acyl hahdes and acid anhydrides [47], SbCls also promotes the Fries rearrangement of phenyl acetates [48], The electrophilic acylation of fluoro-olefins with acetyl fluoride or benzoyl fluoride is promoted by SbFs in liquid SOy [49], The Friedel-Crafts acylation of benzene and electron-rich arenes is successfully catalyzed by SbCl5-AgClO4 [50], SbCl, Ar.BCl [51], SbCl5-LiClO4 [52], or CaCI, AgSbFg [53] (Scheme 14,19), Acyl chlorides, acid anhydrides, and acyl enolates are used as sources of acyl groups. 

Titanium tetrachloride is a moisture-sensitive, highly flammable liquid reacting violently with water (34). It is a strong Lewis acid capable of promoting Diels-Alder reactions (35) and induces the addition of silyl enol ethers and allyl silanes to carbonyl compounds and derivatives (34r-36). It is a less commonly used catalyst in Friedel-Crafts reactions but very useful for the acylation of activated alkenes and in the Fries rearrangement. 

The photochemical reactivity of P-ketoesters is different form that of P-diketones. Irradiation of a P-ketoester in the presence of an alkene produces oxetane via the ketone carbonyl instead of the desired cyclobutane ring system. Therefore, it is necessary to covalently lock the ketoesters as the enol tautomers. To this end, silyl enol ethers, 129 and 132a, and enol acetates, 130 and 132b, were prepared, but these substrates still fail to undergo the desired intramolecular [2 + 2] photocycloaddition with olefins. The only new products observed in these reactions result from the photo-Fries rearrangement of the cyclic enol acetate (130 to 131) and cis-trans isomerization of both acyclic substrates 132a/b. However, tetronates are appropriate substrates for both intermolecular and intramolecular photocycloadditions with olefins. In addition, enol acetates and silyl enol ethers of p-keto esters are known to undergo [2 + 2] photoaddition with cyclic enones (vide infra). 

The Lewis acid-catalyzed Fries rearrangement is performed under strong acidic conditions and therefore reqnires protection of sensitive functional groups. Conversely, the PFR can be achieved nnder milder conditions (organic solvents, nentral media, room temperature, etc.) and is therefore free from this type of problems. Moreover, polyacylation of aromatics is usually difficult to achieve. In the PFR, this problem can be solved by using acetals [144—146] or enol esters [147] as carbonyl protecting groups. Addition of anhydrous K CO is convenient to avoid deprotection [148]. 

Rearrangement of the -acetylated dienolate 4 presents a wide scope and, like the Fries rearrangement, is polar. The plausible intermediates are titanium enolate and acetyl chloride. 

The aryl succinates (94) undergo smooth photo-Fries rearrangements leading to the enol lactones (95). 

Norrish type II cleavage Photoenolization (s. a. 3-Elimination, photo-enolization-induced) review 31,128 Photoflnorination 32, 484 Photo-Friedel-Crafts synthesis, intramolecnlar 32, 975 mem-Photo-Fries rearrangement, skeletal 31,685 Photoisomerization... 

Garcia, H., Miranda, M. A., Roquet-Jalmar, M. F and Martinez-Utrilla, R., Influence of enol acetylation on the photo-Fries rearrangement of an ort/jo-acylaryl benzoate, Liebigs Ann. Chem., 2238, 1982. 

Martmez-UtriUa, R. and Miranda, M. A., Indirect hydroquinone succinoylation via a photo-Fries rearrangement appUcation to the synthesis of enol lactones. Tetrahedron Lett., 21, 2281,1980. 

A novel base-catalyzed Fries-like rearrangement of a 3-acetoxythiophene has been reported (Scheme 149) (79JOC3292). This has been explained as the result of iodide-induced deacylation and subsequent C-acylation of the intermediate enolate anion. Some transformations of 4-hydroxy-2-methylthiophene-3-carboxylic ester are shown in Scheme 150 (69KGS567,75KGS914,71KGS759). 

Hydroxythiocoumarins are, of course, enolic and react as acetoacetate analogues. Electrophiles such as Mannich reagents, aromatic aldehydes and enones react readily (Scheme 22), while acylation can be direct, or via a Fries-type rearrangement of 4-acyloxy precursors. 

Tabuchi, H., Hamamoto, T., Ichihara, A. Modification of the Fries type rearrangement of the O-enol acyl group using W,W-dicyclohexylcarbodiimide and 4-dimethylaminopyridine. Synlett 1993, 651-652. 

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