Pyrazine ketones oxidation

Pyrazine A -oxides have been conveniently synthesized by oxidation of pyrazines (Section 8.03.5.2), and by condensation of a-amino nitriles with a-oximino ketones (Section 8.03.9.3). 

Several major routes to pyrazine ketones have been covered already by primary synthesis in Chapters 1 and 2, by oxidation of aralkylpyrazines in Section 3.2.4.1, by oxidation of secondary hydroxyalkylpyrazines in Section 5.2.2, from pyrazinecarboxylic esters by the Claisen reaction in Section 8.2.2, from pyrazinecarbonyl halides (using several methods) in Section 8.3.2, and frompyrazinecarbonitriles with a Grignard (or similar reagent) in Section 8.6.2. 

Proton magnetic resonance techniques have been used for the measurement of rates of hydrogen-deuterium exchange of pyrazine (in CHsOD-CHsONa at 164.6") (591) for a study of protonation of pyrazine (1472) for analysis of the reaction mixture from quatemization of 2-substituted pyrazines with methyl iodide (666) for elucidation or confirmation of the structures of alkylpyrazines obtained by alkylation of pyrazines with aldehydes and ketones in the presence of a solution of an alkali or alkaline earth metal in liquid ammonia, or a suspension of these metals in other solvents (614) for a study of changes in chemical shifts produced on ionization of 2-methyl and 2-amino derivatives of pyrazine in liquid ammonia (665) for characterization of methoxymethylpyrazines (686) for the determination of the position of the A -oxide function in monosubstituted pyrazine V-oxides and the analysis of V-oxidation reactions (838) for a study of the structure of the cations of fV-oxides of monosubstituted pyrazines (1136) and for the determination of the structure of the products of peroxyacetic and peroxysulfuric acid iV-oxidation of phenyl- and chlorophenylpyrazines (733b). 

Reactions of Pyrazine Ketones Pyrazine Cyanates, Isocyanates, Thiocyanates, Isothiocyanates, and Carbonitrile Oxides... 

A new primary synthesis of 2-amino-3-arylpyrazines is accomplished by reaction of aroyl cyanides with 1,2-diaminoethane (Scheme 33). An important synthesis is that of 2-amino-3-cyano-5-sub-stituted pyrazines, which are conveniently synthesized by condensation of aminomalononitrile with a-oximino ketones and then deoxygenation of the resulting pyrazine jV-oxides (Scheme 37). 

Buron et al, published the synthesis of botryllazine derivatives containing a pyrazine core [84]. Scheme 42 describes the synthesis of these compounds. Chloropyrazine 160 was employed as the starting material for the synthesis of the pyrazine chalcone analog 161. 2-Chloro-3-tributylstannylpyrazine 162 was the key intermediate and was coupled with acid chloride 163 to produce the ketone 164. Following protection and subsequent reaction with 165, pyrazine 166 was generated. Oxidation, deprotection, and demetallation produced the pyrazine of interest 161. 

An important preparation of pyrazines (303) is from a-amino ketones RCOCH2NH2 or their monooximes which spontaneously condense to give 2,5-dihydropyrazines (302). The a-amino ketones are often prepared in situ by reduction of isonitroso ketones, and the dihydropyrazines are usually oxidized to pyrazines before isolation icf Section 3.2.2.3.3). Catalytic reduction of a-azido ketones also leads to 2,5-dihydropyrazines (80OPP265). Similarly, a-nitro ketones may be reduced to the a-amino ketones which dimerize spontaneously (69USP3453278). 

Several mechanisms have been reported for pyrazine formation by Maillard reactions (21,52,53). The carbon skeletons of pyrazines come from a-dicarbonyl (Strecker) compounds which can react with ammonia to produce ot-amino ketones as described by Flament, et al. (54) which condense by dehydration and oxidize to pyrazines (Figure 6), or the dicarbonyl compounds can initiate Strecker degradation of amino acids to form ot-amino ketones which are hydrolyzed to carbonyl amines, condensed and are oxidized to substituted... 

Lipid-Protein-Carbohydrate Interactions. Evidence for such complex interaction was recently reported by Huang et al (36) who observed that the addition of corn lipids to zein and corn carbohydrates enhanced the formation of alkylpyrazines, indicating that lipid-derived free radicals may accelerate the rate of Maillard reactions. Two of the alkylpyrazines, identified in such mixtures after heating for 30 minutes at 180°C, have 5-carbon alkyl substitution at the pyrazine ring and could only be explained by interaction of lipid or lipid decomposition products. These authors suggested that condensation of amino ketones, formed by protein-carbohydrate interaction, may yield 3,6-dihydropyrazine which would in turn react with pentanal, a lipid oxidation product, to form 2,5-dimethyl-3-pentylpyrazine. 

The identification of 49 pyrazines in heated beef and other meats has been extensively revieved (32, 43). Several mechanisms have been proposed for pyrazine formation by the Maillard reaction. Dlcarbonyl compounds can initiate Strecker degradation of amino acids to yield ot-amino ketones, vhich in turn can undergo condensations and oxidizations to form substituted pyrazines (13). 

The sodio derivative of methylpyrazine (20) reacts with aldehydes and ketones to give secondary and tertiary pyrazine carbinols, respectively.175, 178 Yields in the range 21-99% are obtained when the molar ratio of methylpyrazine sodamide carbonyl compound used is 2 2 1. Oppenauer oxidation of 1-phenyl-2-pyrazylethand (21), the aldol addition product of methylpyrazine and benzaldehyde, gives phenacylpyrazine (22) in 18% yield.176... 

The reaction of pyrazylmethylsodium with styrene oxide gives the secondary carbinol (26) in 73% yield and oxidation of compound 26 with acidic potassium dichromate yields the corresponding ketone.179 The sodio derivative reacts with butyl nitrite to give pyrazin-aldoxime (27) in 39% yield.180... 

The tetrazole analogue (341) of 7-oxocholest-5-en-3/3-yl acetate has been prepared 82 by reaction of the afi-unsaturated ketone with hydrazoic acid and boron trifluoride etherate hydrolysis of the 3)3-acetate and oxidation of the resultant alcohol furnished 7a-aza-B-homocholest-4-eno[7a,7-d]tetrazol-3-one. Cycloaddition of ethylenediamine to 2a-bromo-5a-cholestan-3-one has furnished a simple one-step route to 5 -cholestane[2,3-e]dihydro-2,3-pyrazine (342).183 Analogous cycloaddition has been achieved using 16a-bromoandrostan-17-ones. 

Alkylpyrazines may be oxidized to pyrazine aldehydes, ketones, or carboxylic acids. They may also undergo nuclear oxidation (covered piecemeal in most other chapters), oxidative hydroxylation, epoxidation, and so on. Such reactions are illustrated in the following examples ... 

This chapter includes not only nuclear and extranuclear pyrazinecarboxylic acids and anhydrides, but also the related esters, acyl halides, amides, hydrazides, nitriles, aldehydes, ketones, and any of their thio analogues a few rare isothiocyanatopy-razines and pyrazinecarbonitrile oxides are also included. To avoid repetition, interconversions of these pyrazine derivatives are discussed only at the first opportunity for example, the esterification of carboxylic acids is discussed as a reaction of carboxylic acids rather than as a preparative route to carboxylic esters, simply because the section on carboxylic acids precedes that on carboxylic esters. To minimize any confusion, many cross-references have been inserted. 

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