Pyrido pyrazine reactions

IR spectroscopy has also been used in structural problems in 2- and 3-hydroxypyrido[3,4-f ]pyrazines (63JCS5156), in 8-oxopyrido[2,3-f ]pyrazine-7-acids (73MI21501) and in the pyrido[3,4-f ]quinoxaline field (74JCS(P1)1965). IR spectra were recommended for the distinction of isomeric products in the Isay reaction (Section 2.15.15.6.1) (71TH21500) UV spectra were not satisfactory. The Raman spectra of a number of 1- and 3-deazaflavin analogues have been recorded and discussed (80BBA(623)77). 

No systematic study of the mass spectra of pyridopyrazines has been noted, but those of 2,3-dialkyl and 2,3-diaryl derivatives have been recorded 750MS97), and mass spectrometry has been used in the elucidation of problems in the reactions of pyrido[2,3-f ]pyrazines with amide ion (including use of and derivatives) (79JHC305), and of pyrido[2,3-f ]pyrazinium salts with indoles (78ZOR431). The mass spectra of some 1-deazaflavins have been recorded (74JCS(P1)1965). 

H-Pyrido[2,l-i]purine-9-carboxylic acid, 7-oxo-methyl ester, 5, 566 Pyrido[2,3-6]pyrazine, amino-nucleophilic attack, 3, 253 Pyrido[2,3-h]pyrazine, 6-chloro-reactions... 

CN/CC replacement has also been observed on treatment of pteridine with malonitrile or cyanoacetamide 6-amino-7-R-pyrido[2,3,-h]pyrazine (R = CN, CONH2) beingformed (73JCSP(1)1615) (Scheme 15). The reaction involves initial addition of the reagent to the N-3-C-4 bond, scission of the dihydro bond between N-3 and C-4 in the covalent adduct, and recycli-zation. This mechanism is fundamentally different from the mechanism mentioned in Scheme 14, where two molecules of the reagent were used for addition and where the bond breaking takes place between N-1 and C-2. 

Acylation of 3-arylamino-4-arylimino-4//-pyrido[l,2-u]pyrazines (373) with acyl chlorides afforded mixtures of mono- and bisacylated derivatives 374 and 375 (99JPR332). Acetyl chloride gave only monoacylated product 374 (R = 4-MePh, R =Me). Bis-acylated derivative 375 (R = 4-MePh, r = Me) was obtained in 68% yield in boiling toluene. Reaction of 373 with dienophiles 376 and 377 gave 4-thiono and 4-seleno derivatives of 4//-pyrido[l,2-u]pyrazines 378 (Y==S, Se) and 4-imino-4//-pyrido[l,2-u]pyrazines 379, respectively (99JPR332). 

Different azanthraquinones 390-392 were prepared from 3-amino-4-imino-4//-pyrido[l,2-a]pyrazines 373 with 1,4-quinones in one pot reactions via [4-1-2] cycloaddition and the subsequent ring transformation (Scheme 9) (97T5455). 

Treatment of bis-lactim ether 420 with BuLi, then with cw-l,4-dichloro-2-butene in the presence of Nal afforded 3,4,9,9n-tetrahydro-6//-pyrido[l,2-fl]pyrazin-4-one (421) with 96% diastereomeric excess (97TA1855). Reaction of l,2-diphenyl-6-methyl-quinoxaline with 1,4-dichlorobutane in THF in the presence of Na at —78°C afforded a 3 1 mixture of 4a,5-diphenyl-9-methyl-l,2,3,4-tetrahydro-4a//-pyrido[l,2-n]quinoxaline and 4-(4-chlorobutyl)-2,3-diphenyl-6-methyl-1,4-dihydroquinoxaline (98JHC1349). 

Reaction of 3-amino-4-imino-47/-pyrido[l,2- ]pyrazines 319 with DMAD and maleimides 321 yielded 2,2 -bipyr-idine-3,4-dicarboxylates 320, and mixtures of bi- and tricyclic derivatives 322 and 323, respectively (Scheme 27) <1996JPR430>. In the cases of maleimide reactions, higher temperature (at 160°C in xylene) in an autoclave gave only 323. When pyrido[l,2- ]pyrazine 319 (Ar = 4-MeC6H4) was reacted with W-(4-methylphenyl)-maleimide 321 (R = 4-MeC6H4), 324 could be isolated. 

Reaction of 3-amino-4-imino-4//-pyrido[l,2- ]pyrazine 306 (R = 4-MeC6H4) with ketenes 328, prepared in situ from the appropriate acetyl chloride with NEt3, yielded tricyclic derivatives 329 (Scheme 29) <1999JPR332>. Pyridine-3,4-dicarboxylates 330 were obtained from 4//-pyrido[l,2- pyrazines 307 with DMAD in refluxing toluene. 

Reaction of pyrido[ 1,2- pyrazin-4-one 304 with methyl cyanoacetate, cyanamide, and JI-oxo nitriles in AcOH at 70 °C gave imidazo[ l,2- ] pyridine 331, imidazo[l,2- ]-pyrimidine 332, and tetracyclic heterocycles 333, respectively <1996JHC639>. 

Perhydropyrido[l,2- ]pyrazin-l-one was prepared in the reaction of methyl pipecolinate and ethylene imine in boiling EtOH <19951JSP5461047>. Cyclocondensation of ethyl 2-amino-2-(2-pyridyl)acetate with DMAD, followed by treatment of reaction mixture with NaOMe, gave the 2-(l-methoxycarbonyl)-4-oxo-47/-pyrido[l,2- ]pyrazin-3-yl)acetate <1996JHC639>. 

A diastereoselective intramolecular hetero-Diels-Alder reaction of optically active 428 gave unstable 1,3,4,8,9,9a-hexahydropyrido[2,l-f][l,3]oxazin-l-one 429 (X = 0), and l,3,4,8,9,9a-hexahydropyrido[l,2-(z]pyrazin-l-one 429 (X = NTs) (Equation 80) <2003JA4970, 2004T10277>. In the case of pyrido[l,2- ]pyrazine, the reaction was carried out in the presence of 2,6-di- /-butyl-4-methylphenol. 

Selective reduction of the 7-oxo group in pyrido[23-synthetic approach to 5,10-dideazatetrahydrofolic acid <00H(53)1207>. Cycloaddition of pyrimido[4,5-c][l,2,5]oxadiazine 96 with 2,3-dihydrofuran affords a new synthesis of dimethyllumazine derivative 97 which undergoes a ring-opening reaction to give pyrazine derivative 98 <00JHC419>. 

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