Pyridopyrimidines substitution

As in the pyridopyrimidines, selective nucleophilic substitution reactions at reactive ring positions have been a fruitful source of pyridopyridazines. 

Pyrido[3,4-d]pyrimidine-2,4-dione synthesis, 3, 215 Pyridopyrimidines, 3, 201 iV-alkylations, 3, 206 biological activity, 3, 260-261 1-electron reductions, 3, 207 IR spectra, 3, 204 mass spectra, 3, 204 MO calculations, 3, 204 NMR, 3, 202, 203 nucleophilic substitution, 3, 213 8-nucleosides synthesis, 3, 206 physical properties, 3, 201-205 protonation, 3, 206 radical reactions, 3, 215 reactions with water, 3, 207 reduced... 

The preparation and use of derivatized Meldrum s acid has led to an alternative preparation of 2-substituted quinolines (49 and 50) and the preparation of pyridopyrimidines (52). When Meldrum s acid derivatives are used (as shown in this example) decarboxylation occurred under the cyclization conditions. Three component coupling has been used to readily assemble the desired 3-anilino-acrylate from reaction of Meldrum s acid, (EtO)3CH and an aniline (e.g. 54 or 55).< ... 

As previously described, the Gould-Jacobs reaction has been applied to heterocycles fused to anilines, and to some amino-substituted heterocycles. Selectivity of N- and C-cyclization of 2-aminopyridino-methylene malonates has been mentioned (51 and 56). The normal mode of cyclization of 2-aminopyridino-methylene malonates is on the nitrogen to form a pyridopyrimidine. If an electron-donating group (EDG) is in the 6-... 

Substituted pyridopyrimidines show the same tluee principal (77 77 ) absorption bands as the parent compounds but with batho-chromic shifts which may obliterate hands du e to the n n transitions. 

Mason has determined the infrared spectrum of pyrido[3,2-d]-pyrimidin-4(3ff)-one (149, N in position 5) in chloroform solution and as a KBr disc and has suggested that the low frequency of th e NH band (3389 cm ) and high frequency of the C=0 band (1745 cm i) in the solution spectra are indicative of a quasi o-quinonoid form. The infrared spectra of the four pyridopyrimidin-4(377)-ones (149), the four 2,4(ljff,3//)-diones (150), and a number of substituted derivatives, have been determined, as Nujol mulls, in these laboratories. ... 

A large number of nucleophilic substitution reactions involving interconversions of pyridopyrimidines have been reported, the majority of which involve substituents in the pyrimidine ring. This subject has been reviewed previously in an earlier volume in this series which dealt with the theoretical aspects of nucleophilic re-activiti in azines, and so only a summary of the nucelophilic displacements of the substituent groups will be given here. In general, nucleophilic substitutions occur most readily at the 4-position of pyrido-... 

E. C. Taylor and his co-workers have demonstrated an important principle in the ring-opening of pyridopyrimidines and other fused pyrimidine systems to o-aminonitriles. They have demonstrated that based-catalyzed cleavage of a 4-substituted pyrimidine will occur provided that (a) the anion formed by the attack by the base at the 2-position can be stabilized by appropriate structural features in the remainder of the molecule and (b) that the substituent attached to the 4-position is capable of departure with its bonding pair of electrons in... 

Triazanaphthalene (449) is the most unstable of the pyrido-pyrimidines to ring-degradation at pH 2 or pH 7.7 The 4-oxo derivative was converted into the 4-thioxo compound via nucleophilic displacement of the acyloxy intermediate formed with phosphorus pentasulfide. The 4-carboxymethylthio-pyridopyrimidine underwent some substitution by hydroxide ion but primarily gave the ring-opening reaction, which is facilitated by resonance activation of the 2-position by the 6-aza moiety. 

The enamine 141 can be cyclized to the [l,2,4]triazolopyridopyrimidine 142 upon treatment with sodium ethoxide (Scheme 40) <2002M1297>. This fused tricyclic system may also be obtained, like the pteridine analogue (cf. Scheme 38), from the reaction of hydrazonoyl halides and pyridopyrimidines such as 143, and also by treatment of the triazolopyrimidine 144 with dimethylformamide dimethylacetal (DMF-DMA) dimethylacetal and subsequent ring closure <2003MOL333, 2003HAC491> (Scheme 41). Another series of triazolopyridopyrimidines, for example, 146, can be prepared from a hydrazine-substituted pyridopyrimidine 145, in two ways either directly by reaction with an acid chloride, or via a derived hydrazone (Scheme 42) <1996MI585>. 

Triazole-fused pyridopyrimidines can be prepared by reaction of aldehydes with the substituted pyridopyrimidine 309 (Equation 106). The pyrazole-fused derivative 311 can be prepared by the reaction of the sulfonimine 310 with dimethyl acetylenedicarboxylate (DMAD) (Equation 107) <1998H(47)871>. 

Reaction of 2-amino-3,5-dicyano-6-substituted pyridine derivatives with formamide led to pyridopyrimidines 365 <1993JHC253>. 

The carboxylic group of 6-aryl-2-methylthiopyrido[2,3- s1pyrimidine-7-carboxylic acid 563 was amidated with (i )-2-(aminomethyl)-l-( /t-butoxycarbonyl)pyrrolidine 564, followed by sulfide oxidation of the resulting amide 565 and reaction with 4-morpholinoaniline to give the substituted pyridopyrimidine 566 as a kinase inhibitor (Scheme 26) <2005W02005090344>. 

The condensation of 2-aminopyridine with EMME followed by cyclization in Dowtherm affords the pyridopyrimidine (72).102 103 When the 2-aminopyridine is substituted in the 6-position with an electron-releasing group (R4 = CH3. OEt, NH2), the naphthyridine (71) is formed.72 In all cases of the EMME reaction and condensations involving similar carbonyl compounds, that have been studied, the naphthyridine is formed only when this latter requirement is fulfilled. 

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