Alkyl pyridazines, reactions

In contrast to the thermolysis reactions described above, photolysis of perfluoro (alkyl-pyridazines) leads to high yields of pyrazines.40-42 Thus, irradiation of pyridazines 33 with unfiltered light in the vapor phase gives pyrazines 34.40... 

Reaction of various pyridazine derivatives with nitromethane or nitroethane in DMSO affords the corresponding 5-methyl and 5-ethyl derivatives. The reaction proceeds as a nucleophilic attack of the nitroalkane at the position 5. In this way, 3,6-dichloro-4-cyano-pyridazine, 4-carboxy- and 4-ethoxycarbonyl-pyridazin-3(2//)-ones and 4-carboxy- and 4-ethoxycarbonyl-pyridazin-6(lH)-ones can be alkylated at position 5 (77CPB1856). 

Alkyl- and aryl-pyridazines can be prepared by cross-coupling reactions between chloropyridazines and Grignard reagents in the presence of nickel-phosphine complexes as catalysts. Dichloro[l,2-bis(diphenylphosphino)propane]nickel is used for alkylation and dichloro[l,2-bis(diphenylphosphino)ethane]nickel for arylation (78CPB2550). 3-Alkynyl-pyridazines and their A-oxides are prepared from 3-chloropyridazines and their A-oxides and alkynes using a Pd(PPh3)Cl2-Cu complex and triethylamine (78H(9)1397). 

Reaction of pyridazine 1-oxide with phenylmagnesium bromide gives 1,4-diphenyl-butadiene as the main product and l-phenylbut-l-en-3-yne and 3,6-diphenylpyridazine as by-products, while alkyl Grignard reagents lead to the corresponding 1,3-dienes exclusively (79JCS(P1)2136>. 

Since the pyridazine ring is generally more stable to oxidation than a benzene ring, oxidation of alkyl and aryl substituted cinnolines and phthalazines can be used for the preparation of pyridazinedicarboxylic acids. For example, oxidation of 4-phenylcinnoline with potassium permanganate yields 5-phenylpyridazine-3,4-dicarboxylic acid, while alkyl substituted phthalazines give pyridazine-4,5-dicarboxylic acids under essentially the same reaction conditions. 

There are some recent examples of this type of synthesis of pyridazines, but this approach is more valuable for cinnolines. Alkyl and aryl ketazines can be transformed with lithium diisopropylamide into their dianions, which rearrange to tetrahydropyridazines, pyrroles or pyrazoles, depending on the nature of the ketazlne. It is postulated that the reaction course is mainly dependent on the electron density on the carbon termini bearing anionic charges (Scheme 65) (78JOC3370). 

The most useful syntheses of pyridazines and their alkyl and other derivatives begins with the reaction between maleic anhydride and hydrazine to give maleic hydrazide. This is further transformed into 3,6-dichloropyridazine which is amenable to nucleophilic substitution of one or both halogen atoms alternatively, the halogen(s) can be replaced by hydrogen as shown in Scheme 110. In this manner a great number of pyridazine derivatives are prepared. 

Pyrazino[2,3-d]pyridazin-8-one, 5-chloro-synthesis, 3, 347 Pyrazino[l, 2-a]pyrimidine reactions, 3, 350 structure, 3, 339-340 synthesis, 3, 256, 365 Pyrazino[ 1,2-a]pyrimidine, 2-hydroxy-alkylation, 3, 351... 

Only a few reports have dealt with the behavior of tetra-azaindenes toward electrophiles, and the reactions reported involved the pyrazole ring. Thus, alkylation of 336 with alkyl halides affords a mixture of the A-alkylated derivatives 337 and 338. Compound 336 is produced by alkylation of 339. Bromination of 339 (R = H) affords the 7-bromo derivative 340 (82JHC817) (Scheme 34). Nitration of 2-methylpyrazolo[3,4-c] pyridazine occured at pyrazole C-3 (73JAP76893). Bromination of 341 with bromine in acetic acid gives 342 (83AP697). 

As a rule, the annular nitrogen atoms in 1,3,4-thiadiazoles are very reactive towards electrophiles as shown by facile alkylation reactions and quaternary salt formation. A thorough study on the quaternization of 2,5-disubstituted thiadiazoles, and its comparison with pyridazines has been published <84CHEC-i(4)545>. Electrophilic attack by benzyl chloride on 2-aminothiadiazole to give (44) in a regiospecific manner was utilized in the synthesis of an antiviral candidate <92MI 4io-oi>. 

Besides removal of alkyl-based groups located at the N-2 of a pyridazin-3(27/)-one also real reactions in the side chain appeared. Pyridazinium ylides, obtained via deprotonation of iV-alkylpyridazinium salts, have been reacted with phenyl isocyanates and benzenediazonium salts <2002MI287, 1997T4411>. As discussed in Section 8.01.5.7.2 1,3-dipolar cycloaddition with ethyl acrylate and ethyl propiolate were also studied. 

Ultraviolet (UV) spectroscopy does not tend to be the method of choice for structure determination, but a list of UV absorptions was given in the review by Knowles <1996CHEC-II(7)489>. Fluorescence properties and triplet yields of [l,2,3]triazolo[4,5-r/ pyridazines in various solvents have been reported <2002JPH83>. These heterocyclic systems were found to be photochemically very stable. In a recent paper, Wierzchowski et al. studied the fluorescence emission properties of 8-azaxanthine ([l,2,3]triazolo[4,5-r/ pyrimidine-5,7-dione) and its A -alkyl derivatives at various pH s <2006JPH276>. For the 8-azaxanthines, an important characteristic of emission spectra in aqueous solutions was the unusually large Stokes shift. Since 8-azaxanthine is a substrate for purine nucleoside phosphorylase II from Escherichia coli, the reaction is now monitored fluorimetrically. The fluorescence properties of [l,2,3]triazolo[4,5-r/ -pyrimidine ribonucleosides were earlier described by Seela et al. <2005HCA751>. 

Methylations of [l,2,3]triazolo[4,5-t ]pyridazines are shown in Schemes 1-3 <2002JST73>. The reaction in Scheme 3 is nonselective, highlighting the steric influence of the pyridylimino moiety on alkylations, although electrophilic attack seems to be most favored at the N-2 of the fused triazole. 

Alkylations of the 4-thione substituent of l-(2,3,5-tri-0-acetyl-/3-D-ribofuranosyl)triazolo[4,5- pyridazine-4-thione 29 were carried out using sodium hydride and various alkyl halides, and the reaction with methyl iodide to give methylthio derivative 48 is shown in Scheme 32 <1996BMC1725>. 

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