Esters decarboxylation

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)... 

Standard retrosynthetic manipulation of PGA2 (1) converts it to 5 (see Scheme 2). A conspicuous feature of the five-membered ring of intermediate 5 is the /(-keto ester moiety. Retrosynthetic cleavage of the indicated bond in 5 furnishes triester 6 as a potential precursor. Under basic conditions and in the synthetic direction, a Dieck-mann condensation4 could accomplish the formation of a bond between carbon atoms 9 and 10 in 6 to give intermediate 5. The action of sodium hydroxide on intermediate 5 could then accomplish saponification of both methyl esters, decarboxylation, and epi-merization adjacent to the ketone carbonyl to establish the necessary, and thermodynamically most stable, trans relationship between the two unsaturated side-chain appendages. 

Electrophilic substitution of the ring hydrogen atom in 1,3,4-oxadiazoles is uncommon. In contrast, several reactions of electrophiles with C-linked substituents of 1,3,4-oxadiazole have been reported. 2,5-Diaryl-l,3,4-oxadiazoles are bromi-nated and nitrated on aryl substituents. Oxidation of 2,5-ditolyl-l,3,4-oxadiazole afforded the corresponding dialdehydes or dicarboxylic acids. 2-Methyl-5-phenyl-l,3,4-oxadiazole treated with butyllithium and then with isoamyl nitrite yielded the oxime of 5-phenyl-l,3,4-oxadiazol-2-carbaldehyde. 2-Chloromethyl-5-phenyl-l,3,4-oxadiazole under the action of sulfur and methyl iodide followed by amines affords the respective thioamides. 2-Chloromethyl-5-methyl-l,3,4-oxadia-zole and triethyl phosphite gave a product, which underwent a Wittig reation with aromatic aldehydes to form alkenes. Alkyl l,3,4-oxadiazole-2-carboxylates undergo typical reactions with ammonia, amines, and hydrazines to afford amides or hydrazides. It has been shown that 5-amino-l,3,4-oxadiazole-2-carboxylic acids and their esters decarboxylate. 

The anion formed from the acetyl methyl group under reaction conditions then attacks one of the carbethoxy groups to form a cylohexanone to give (74-4) as the isolated product. The free acid obtained on hydrolysis of the ester decarboxylates to give the (3-diketone (74-5). In a classic apphcation of the Knorr pyrrole synthesis, the diketone is then allowed to react with 2-aminopentan-3-one. Since the latter is unstable, it is generated in situ by reduction of the nitrosation product from diethyl ketone. There is thus obtained piquindone (74-6) [76], a compound that displays antipsychotic activity. 

Methyl esters 333 that are activated toward decarboxylation by a C-2-ethoxycarbonyl group and tethered by an alkyl chain to an acrylate Michael-acceptor undergo chemoselective S] [2-dealkylation of the methyl ester, decarboxylation and cyclization upon exposure to lithium chloride in DMEU, affording tetrahydropyrans in excellent yield and diastereoselectivity (Equation 142) <1998JOC144>. 

The following are examples of other generation methods of the same kind of reactive sp2 carbon-centered radicals. Treatment of aromatic diazocarboxylate ester (11) at pH 7.2 forms the phenyl radical, through hydrolysis of the ester, decarboxylation to the phenyldiimide, and finally, reaction with molecular oxygen (eq. 11.9a). Electron transfer reduction of 1,4-diazonium (12) with Cu+ generates the corresponding /7-phenylene biradical (probably step-by-step formation) (eq. 11.9b). These simple sp2 carbon-centered radicals also destroy DNA plasmid at pH 7.6, under living-body conditions, like esperamicin [37-39]. 

Fig. 13.27. Acetoacetic ester synthesis of methyl ketones II hydrolysis of the alkylated acetoacetic ester/decarboxylation of the alkylated acetoacetic acid.

If care is taken to avoid ring cleavage, 5-aryl-l,3,4-oxadiazole-2-carboxylic acids will undergo typical reactions such as the formation of acid chlorides, amides and esters. Decarboxylation may occur on heating, for example with 5-amino-l,3,4-oxadiazole-2-carboxylic acids (77JHC1385), and an amide has been dehydrated to a nitrile (78GEP2808842). 

This synthesis uses a Claisen condensation, followed by a p-keto ester decarboxylation. 

A mixture of lupinine and epilupinine is obtainable by the following series of reactions. The betaine XXVI on cyclic hydrogenation and subsequent decarboxylation with 20 % hydrochloric acid gives a mixture of epimeric lupininic acids (XXIX). The dicarboxylic ester XXVIII is also obtained by the mercuric acetate dehydrogenation of the piperidine derivative XXX and by the alkylation of monomeric piperideine with a y-bromopropylmalonic ester. The last route is presumably a first Mannich condensation followed by an alkylation. Hydrolysis of the malonic esters, decarboxylation (XXIV), esterification, and reduction with lithium aluminum hydride complete the synthesis of a mixture which consists of 80% dZ-epilupinine and 20% dMupinine. Thermal... 

The radical EtOCOCMe2COO, generated by photolysis of the corresponding Barton (N-hydroxy-2-thiopyridone) ester, decarboxylates inefficiently unless generated in benzene under reflux. Under these conditions 2-pyridyl-SCMe2-C02Et is obtained in 80% yield. Investigation of the reaction of the decarboxy-... 

Seitz T, Baudoux J, Bekolo H, Cahard D, Plaquevent JC, Lasne MC, Rouden J. Organocatalyzed route to enantioen-richied pipecolic esters decarboxylation of an aminomalo-nate hemiester. Tetrahedron 1(XI6 61-.6155-6165. 

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