Decarboxylation with aromatization

Esters of 9-oxo-6,9-dihydro-triazolo[4,5-/]quinoline-8-carboxylic acids 176 can be hydrolyzed and decarboxylated to afford the 9-oxo-6,9-dihydrotriazolo[4, 5-/]quinolines 177 (Scheme 55) (87CCC2918, 88CCC1068,90JMC2640). These in turn were aromatized with POCI3 to the appropriate 9-chloroderivatives 178,... 

The thermal decomposition of MCPBA is slow and unselective. When cobalt catalyzed, the initial reaction is very fast and selective but the reaction is Wdered by the re-arrangement of Co(in)a to Co(III)s and by the slow reaction with m-chlorotoluene. These reactions are also characterized by a high steady state concentration of Co(III). High concentrations of Co(III) are not desirable because Co(III) is known to react with the acetic acid solvent and also decarboxylate aromatic acids (2). 

An equimolar mixture of 3,4,5-trimethoxy phenyl iodide 157, lithium propargyl alkoxide 158, and diethyl ethoxymethylene malonate 159 was stirred at room temperature in the presence of a palladium catalyst. Then, to the resulting intermediate 161 potassium t-butoxide was added, and the ensuing base-promoted decarboxylative aromatization afforded tetrahydrofuran MCR adduct 162 in good yield. The ester was first reduced and the furan ring was hydrogenated with Raney nickel to furnish a diastereomeric mixture of products 163 in high yield. Further synthetic manipulations then provided a known precursor to the natural product. 

One great advantage of the decarboxylative halogenation with O-acyl esters of A-hydroxy-2-thiopyridone is that the reaction does not require any heavy metal such as Ag or Hg, unlike the Hunsdiecker reaction [24, 25]. Moreover, decarboxylative bromination of p-methoxybenzoic acid can be also carried out in good yield, while it does not proceed with the Hunsdiecker reaction instead, electrophilic bromination on the aromatic ring occurs. 

Attempts to apply the thermal decarboxylation reaction in the liquid phase to aromatic halofor-mic acid esters have shown that their reaction is different from that ol the aliphatic haloformates. It was found that evolution of carbon dioxide occurs, but only high boiling products could be isolated.136 On heating in the presence of aromatics and Lewis acids, aryl chloroformates do not react to give chlorinated aromatics with concomitant decarboxylation, but undergo a Friedel-Crafts reaction to give phenyl benzoates.137 Under similar conditions phenyl fluoroformate undergoes only polymerization and carbonate formation.137... 

The cyclic glycol 273 gave 7,10,14-/-butyI-3-methoxy-l,8-bisdehydro[14]annulene (275) by decarboxylative aromatization on treatment with hydrogen chloride . ... 

The selective ability of higher-valent metal ions to oxidize organic free radicals has been examined and two mechanisms have been proposed for the decomposition of cerium(iv) carboxylates in the presence of olefins and aromatic hydrocarbons (i) involving a non-decarboxylative route with the generation of carboxyalkyl radicals via thermal decomposition, and ( ) the formation of alkyl radicals and COg in the decarboxylation reaction. E.s.r. studies using cerium(iv) have been used to provide evidence for the formation of the sulphite radical anion SO3 in the oxidation of sulphite. ... 

The phenylacetic acid derivative 469 is produced by the carbonylation of the aromatic aldehyde 468 having electron-donating groups[jl26]. The reaction proceeds at 110 C under 50-100 atm of CO with the catalytic system Pd-Ph3P-HCl. The reaction is explained by the successive dicarbonylation of the benzylic chlorides 470 and 471 formed in situ by the addition of HCl to aldehyde to form the malonate 472, followed by decarboxylation. As supporting evidence, mandelic acid is converted into phenylacetic acid under the same reaction conditions[327]. 

The physical properties of cyanoacetic acid [372-09-8] and two of its ester derivatives are Hsted ia Table 11 (82). The parent acid is a strong organic acid with a dissociation constant at 25°C of 3.36 x 10. It is prepared by the reaction of chloroacetic acid with sodium cyanide. It is hygroscopic and highly soluble ia alcohols and diethyl ether but iasoluble ia both aromatic and aUphatic hydrocarbons. It undergoes typical nitrile and acid reactions but the presence of the nitrile and the carboxyUc acid on the same carbon cause the hydrogens on C-2 to be readily replaced. The resulting malonic acid derivative decarboxylates to a substituted acrylonitrile ... 

Trichloroacetic acid K = 0.2159) is as strong an acid as hydrochloric acid. Esters and amides are readily formed. Trichloroacetic acid undergoes decarboxylation when heated with caustic or amines to yield chloroform. The decomposition of trichloroacetic acid in acetone with a variety of aUphatic and aromatic amines has been studied (37). As with dichloroacetic acid, trichloroacetic acid can be converted to chloroacetic acid by the action of hydrogen and palladium on carbon (17). 

Isoquinoline reacts with aliphatic carboxylic acids photolyticaHy or with a silver catalyst to give excellent yields of alkylation products by decarboxylation (155). This method is useful in the synthesis of 2-benzoyhsoquinolines bearing a variety of aromatic substituents in the 1-position (156). 

Carboxylic acids react with xenon difluoride to produce unstable xenon esters The esters decarboxylate to produce free radical intermediates, which undergo fluonnation or reaction with the solvent system Thus aliphatic acids decarboxylate to produce mainly fluoroalkanes or products from abstraction of hydrogen from the solvent Perfluoro acids decarboxylate in the presence of aromatic substrates to give perfluoroalkyl aromatics Aromatic and vinylic acids do not decarboxylate [91] (equation 51)... 

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