Pyridinium salts pyridone formation

When 4-alkylated pyridinium salts are exposed to ferricyanide, oxidation at the 4-a-carbon atom competes with pyridone formation and all possible oxidation products 104-109 are produced as complex reaction mixtures. In the case of complete substitution of the 4-a-H atoms (110), pyridones 111 result as unique products in almost quantitative yields. 

The formation of a 4-pyridone with simultaneous oxidative elimination has never been observed for 4-substituted pyridinium salts, which is in contrast to the 2-substituted analogues. 

Pyridone Formation by Alkaline Ferricyanide Oxidation or 3-Substituted Pyridinium Salts... 

Both N-N and N-C bond fission occurs on irradiation of the hydrazone derivatives (191). The photodegradation of the phenylhydrazone and the hydrazone of benzil have also been described. a-Ketoiminyl radicals are formed on irradiation of oximino ketones at low temperature. A study of the photochemical decomposition of sulfamic esters and their use as initiators of cross-linking of a melamine resin have been described. The bispyridinyl radical (192) is formed by one electron reduction of the corresponding pyridinium salts. The irradiation of this biradical at 77 K results in C-N bond fission with the formation of benzene-1,3-diyl. The predominant products from the irradiation (X,> 340 nm) of (193) in methanol were identified as A -hydroxy-2-pyridone and (194) from the fission of the C-O bond. Other products were 2-pyridone, (195) and (196) that arise from O-N bond fission. The reaction is to some extent substituent dependent and a detailed analysis of the reaction systems has identified an intramolecular exciplex as the key intermediate in the C-O bond heterolysis. 

G—GE[3 >0=G—OH], and resembles the splitting of 1-phenacyl-pyridinium salts (p. 390). Other examples are known743, 877 Although methide formation must occur in these reactions the methide is not considered to play a part in pyridone formation743. 

The nitro group in quaternary salts of 4-nitropyridine is easily replaced. Recrystallization of the methiodide from undried acetone gives l-methyl-4-pyridone . Reaction of 4-nitropyridine with benzyl chloride yields 1-benzyl-4-pyridone, and with benzyl bromide, l-benzyl-3,5-dibromo-4-pyridone (nuclear bromination is thought to result from the oxidation of hydrobromic acid by nitrous acid) the experimental description suggests that in these reactions nucleophilic replacement of nitro by halide may occur initially . The consequences of the autoquaternization of 4-nitropyridine have already been mentioned. The formation of 4-hydroxypyridine from 4-nitropyridine and acetic anhydride a presumably involves the acetyl-pyridinium salt. 4-Nitropyridine 1-oxides give with acetic anhydride mainly 4-hydroxy-or 4-acetoxy-3-nitropyridine l-oxides sic but the presence... 

Chloro-l-methylpyridinium iodide (1) reacts with a mixture of a carboxylic acid and an alcohol, in the presence of two equivalents of base, to form an ester (eq 1). The pyridinium salt (2) is formed rapidly by displacement of chloride from (1) by the carboxylate subsequent reaction with the alcohol results in formation of the ester, along with 1 -methyl-2-pyridone (3). A variety of solvents may be employed, but yields are highest in dichloromethane or pyridine. Tri-n-butylamine or Triethylanune are often used as base. The co-product (3) is insoluble in dichloromethane and so precipitates from this solvent. Good results are obtained even for hindered carboxylic acids and alcohols. 

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