Aromatization enol formation

The mechanism of the Fiesselmann reaction between methylthioglycolate and a,P-acetylenic esters proceeds via consecutive base-catalyzed 1,4-conjugate addition reactions to form thioacetal Enolate formation, as a result of treatment with a stronger base, causes a Dieckmann condensation to occur providing ketone 8. Elimination of methylthioglycolate and tautomerization driven by aromaticity provides the 3-hydroxy thiophene dicarboxylate 9. 

Diels-Alder reaction, 493 El reaction, 391-392 ElcB reaction, 393 E2 reaction, 386 Edman degradation, 1032 electrophilic addition reaction, 147-148. 188-189 electrophilic aromatic substitution, 548-549 enamine formation, 713 enol formation, 843-844 ester hydrolysis, 809-811 ester reduction, 812 FAD reactions. 1134-1135 fat catabolism, 1133-1136 fat hydrolysis, 1130-1132 Fischer esterification reaction, 796 Friedel-Crafts acylation reaction, 557-558... 

Base-catalysed cyclization of proximate diacetyl aromatics [e.g. o-diaccty I benzene (36)] gives the corresponding enone (37). Relative rates, activation parameters, and isotope effects are reported for (36), and also for 1,8-diacetylnaphthalene, 4,5-diacetylphenanthrene, and 2,2/-diacetylbiphenyl, in aqueous DMSO.61 Reaction proceeds via enolate formation (rate determining for the latter three substrates), followed by intramolecular nucleophilic attack [rate determining for (36)], and finally dehydration. 

Even simple enols have substantial lifetimes, provided that bases or acids are completely excluded173. Thus, an aromatic enol 4 is prepared in situ by Norrish-type fragmentation of 2. If (-)-ephedrine is present in the reaction mixture, the enol reverts enantioselectively to (/ )-2-rnethy 1 -1 -indanone (3). With as little as 0.01 mol % catalyst, 45% ee is obtained176. The crucial enol 4 has also been generated from either the benzyl enol ester 5 by palladium on charcoal and hydrogen or from the allyl ester 6 by palladium acetate, triphenylphosphine and ammonium formate. In the presence of a chiral 1.2-hydroxyamine, e.g., ephedrine, substantial stereogenic induction in 2-methylindanone 3 was observed175. 

Redrawing this intermediate shows how easily it can cyclize to a six-membered ring. Enol formation allows a very favourable aldol cyclization to give a six-membered ring then dehydration and enolization to make the aromatic ring with hydrolysis of the CoA ester and decarboxylation gives resveratrole. 

Upon treatment of y-butenolides with an appropriate base, aromatization-driven enol formation takes place as observed with azlactones. Although the steric environment of the a- and y-positions bears a close resemblance, only y-selective reactions have been reported in the literature. Because the y-butyrolactone structural motif is frequently found in biologically relevant molecules, development of catalysts for asymmetric introduction of y-butenolides into organic frameworks in a stereoselective fashion is highly desirable. For conjugate addition of y-butenolides, bifunctional catalysts seem to be a uniquely effective class of promoters. 

The ultimate stabilized enol is phenol. It is estimated that the equilibrium constant for formation of the aromatic enol form from the nonaromatic ketone is greater than IQi (Fig. 19.23). 

Kobayashi et al. also applied the catalyst to asymmetric 1,4-addition reactions of azlactones with acrylates [66]. The active a-proton of the azlactone (5(4H)-oxazolone) skeleton showed a low pKa value compared to that of the alanine Schiff bases, because the anion formed is stabilized via enol formation and aromatization. After 1,4-addition reactions with acrylates, the 2-substituted glutamic acid derivatives formed could be obtained via hydrolysis using a weak acid. It was found that Pybox 3 prepared from alaninol derivatives was effective for this reaction. The desired products were obtained in good yields with good enantios-electivities. Several amino acid derivatives containing aUcyl chains in the a-position were screened, and the leucine derivative (R = Bu) showed the best enantio-selectivity in this reaction (Table 16, entry 8). 

The Reformatsky reagent was generated by treatment of the ester 378 with diethyl zinc, while RhCl(PPh3)3 is assumed to accelerate enolate formation. The addition to imines 377 was followed by an in situ cyclization to give p-lactams under release of menthol. Imines derived from aromatic aldehydes yield the products 379 with remarkable enantioselectivity, which was, however, lower or vanished completely with aldimines of cyclohexyl or isobutyric aldehyde (Scheme 4.82). P-Lactam 379 (R = Ph) obtained from benzalimine served as an intermediate in a synthesis of the difluoro analog of the Taxol side chain [188]. 

Hydroperoxides have been obtained from the autoxidation of alkanes, aralkanes, alkenes, ketones, enols, hydrazones, aromatic amines, amides, ethers, acetals, alcohols, and organomineral compounds, eg, Grignard reagents (10,45). In autoxidations involving hydrazones, double-bond migration occurs with the formation of hydroperoxy—azo compounds via free-radical chain processes (10,59) (eq. 20). 

Generally, isolated olefinic bonds will not escape attack by these reagents. However, in certain cases where the rate of hydroxyl oxidation is relatively fast, as with allylic alcohols, an isolated double bond will survive. Thepresence of other nucleophilic centers in the molecule, such as primary and secondary amines, sulfides, enol ethers and activated aromatic systems, will generate undesirable side reactions, but aldehydes, esters, ethers, ketals and acetals are generally stable under neutral or basic conditions. Halogenation of the product ketone can become but is not always a problem when base is not included in the reaction mixture. The generated acid can promote formation of an enol which in turn may compete favorably with the alcohol for the oxidant. 

The mechanism is presumed to involve a pathway related to those proposed for other base-catalyzed reactions of isocyanoacetates with Michael acceptors. Thus base-induced formation of enolate 9 is followed by Michael addition to the nitroalkene and cyclization of nitronate 10 to furnish 11 after protonation. Loss of nitrous acid and aromatization affords pyrrole ester 12. 

Flavone formation is believed to proceed through a similar mechanism as the synthesis of chromones, albeit aromatic acid anhydrides and their corresponding salts are used. The first step is benzoylation of 12 to give the ester 14. Enolization and o-alkylation then affords the enolbenzoate 15. Enolbenzoate 15 then undergoes an acyl transfer to yield... 

The formation of a stable imino-enole tautomer 358 is due to the conjugation of the C=C and C=N double bonds with the aromatic ring and hydroxyl group. The enaminoketone tautomer 357 is present in a negligible amount. 

In the first step, catalyst 64c attacks ketene 66 to form a zwitterionic enolate 71, followed by Mannich-type reaction with imine 76 (Fig. 40). A subsequent intramolecular acylation expels the catalyst under formation of the four-membered ring. Utilizing 10 mol% of 64c, N-Ts substituted (3-lactams 77 were prepared from symmetrically as well as unsymmetrically substituted ketenes 66, mainly, but not exclusively, with nonenolizable imines 76 as reaction partners [96]. Diastereos-electivities ranged from 8 1 to 15 1, yields from 76 to 97%, and enantioselectivities from 81 to 94% ee in the case of aliphatic ketenes 66 or 89 to 98% ee for ketenes bearing an aromatic substituent. Applying complexes 65 or the more bulky and less electron-rich 64b, ee values below 5% were obtained. 

Scheme 2.11 shows some examples of Robinson annulation reactions. Entries 1 and 2 show annulation reactions of relatively acidic dicarbonyl compounds. Entry 3 is an example of use of 4-(trimethylammonio)-2-butanone as a precursor of methyl vinyl ketone. This compound generates methyl vinyl ketone in situ by (3-eliminalion. The original conditions developed for the Robinson annulation reaction are such that the ketone enolate composition is under thermodynamic control. This usually results in the formation of product from the more stable enolate, as in Entry 3. The C(l) enolate is preferred because of the conjugation with the aromatic ring. For monosubstituted cyclohexanones, the cyclization usually occurs at the more-substituted position in hydroxylic solvents. The alternative regiochemistry can be achieved by using an enamine. Entry 4 is an example. As discussed in Section 1.9, the less-substituted enamine is favored, so addition occurs at the less-substituted position. 

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