Pyridazine 1-oxides, nucleophilic attack

Pyridopyridazines, hydroxyalkyl-nucleophilic attack, 3, 241 Pyridopyridazines, methyl-electrophilic reactions, 3, 240 Pyrido[2,3-6]pyridazines nucleophilic substitution, 3, 253-254 Pyrido[2,3-c]pyridazines, 3, 232-233 benzo fused, 3, 233 N-oxide... 

TL5981>. The proposed mechanism involves the oxidation of the amine to an imine, tautomerization to an enamine, and a sequence of nucleophilic attacks on the pyridazine rings followed by oxidation steps. The oxidant of choice is (bispyridine)silver permanganate <1982TL1847>, which is easily prepared, mild in action, and is soluble in organic media. If R1 = H in the product 77, electrophilic substitution (e.g., bromination, nitration, Mannich, and Vilsmeier-Haack-Arnold reactions) occurs at this position. 

Lithium ester enolate-imine condensation has been used for the preparation of / -lactam rings via addition at the imine moiety <1996H(43)1057>. But treatment of imino derivatives of the pyridazine 293 with the lithium enolate of ethyl a,a-dimethylacetate 294 in THE led to the formation of the pyrido[3,4-r/ pyridazine 295 and its oxidized form 296. Compound 295 was obtained by nucleophilic attack of the carbanion species at C-5 of the pyridazine ring followed by cyclization (Equation 24) <1996JHC1731>. 

By the action of phenyllithium, pyridazine is converted to adduct 100 (Table XVI), resulting from nucleophilic attack at position 3.34 The structural assignment is based upon H- and 13C-NMR, starting with pyridazine and its 4,5-dideutero derivative. The site of attachment of the phenyl group is other than that observed with the amide ion in ammonia (C-4). Analysis of the products obtained after hydrolysis and oxidation indicates the presence of nearly 5-6% of 4-phenyIpyridazine. Although this finding implies the formation of a small amount of the isomeric adduct 101, there is no NMR evidence for it. However, both isomeric adducts can be detected when the reaction is carried out in the presence of TMEDA or tetrahydrofuran at a lower temperature. The chemical shift values of adduct 101 are closely similar to those of the amino analog 29. 

Most likely, the cyclization of 227 to 236 is preceded by oxidation of dialkylamine 235 into imine 238a, which then reacts in its enamine form 238b as a bifunctional C,Y-nucleophile. At first this enamine, as a C-nucleophile, attacks the C(4) atom of the pyridazine ring to produce aH-adduct 239. Further possible development of this reaction is shown in Scheme 69 (cf. Scheme 67). 

Acyclic dialkylamines are not very reactive as nucleophiles in the oxidative alkylamination, however they are very prone to oxidation and, therefore, they are capable for unexpected behavior. Presumably, transformation 33 41 starts from oxidation of dialkylamme into imine 42, that is in equilibrium with enamine 43 (Scheme 28). The latter, as bifunctional C,W-nucleophile, attacks C-4 atom of the pyridazine ring to form cr -adduct 44, which then undergoes oxidative aromatiza-tion. Subsequent intramolecular oxidative amination of the intermediate 45 yields pyrrole derivative 41. The participation of imines in this process has been confirmed experimentally. In the presence of AgPy2Mn04, pyrimidopyridazine 33 reacts with authentic aldimines and ketimines 42 to give pyrroles 41. Transformation 33 41 represents not only a rare example of the tandem processes but... 

It was projxjsed that the quinoxahne residue of the product 100a was formed by the initial nucleophilic attack on position 4 and 5 of tetrachloropyridazine 98 by 1,2-DAB, then the aerial oxidation, giving an intermediate 1,4-dichloropyridazino [4,5-Z ]quinoxaline 101 which might react with two more molecules of 1,2-DAB to give the pyridazine-ring-opened system 100a (Scheme 6.32). 

Pyridine and quinoline /V-oxides react with phosphorus oxychloride or sulfuryl chloride to form mixtures of the corresponding a- and y-chloropyridines. The reaction sequence involves first formation of a nucleophilic complex (e.g. 270), then attack of chloride ions on this, followed by rearomatization (see also Section 3.2.3.12.5) involving the loss of the /V-oxide oxygen. Treatment of pyridazine 1-oxides with phosphorus oxychloride also results in an a-chlorination with respect to the /V-oxide groups with simultaneous deoxygenation. If the a-position is blocked substitution occurs at the y-position. Thionyl chloride chlorinates the nucleus of certain pyridine carboxylic acids, e.g. picolinic acid — (271), probably by a similar mechanism. 

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