Phthalazine oxidation

JV-Oxidation of phthalazine with monoperoxyphthalic acid produces the corresponding... 

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. 

In a similar manner, phthalazine or its alkyl- or aryl-substituted derivatives are obtainable from 1,2-diacylarenes (Scheme 76). Phthalaldehydic acid and its analogs are transformed by hydrazines into the corresponding phthalazin-l(2//)-ones. Phthalazin-l(2iT)-one itself is prepared from naphthalene by oxidation, subsequent treatment with hydrazine and decarboxylation as shown in Scheme 77 (55YZ1423,64FRP1335759). 4-Substituted phthalazin-l(2iT)-ones are prepared in a similar way from 2-acylbenzoic acids. 3-Hydroxyphthalides,... 

Hydroxyphthalazin-l(2//)-one is obtained in a smooth reaction between phthalic anhydride and hydrazine hydrate and this is again the starting compound for many 1-substituted and/or 1,4-disubstituted phthalazines. The transformations of 1,4-dichloro-phthalazine, which is prepared in the usual manner, follow a similar pattern as shown for pyridazines in Scheme 110. On the other hand, phthalonitrile is the preferential starting compound for amino- and hydrazino-phthalazines. The most satisfactory synthesis of phthalazine is the reaction between a,a,a, a -tetrachloro-o-xylene and hydrazine sulfate in sulfuric acid (67FRP1438827), alt iough catalytic dehalogenation of 1-chloro- or 1,4-dichloro-phthalazine or oxidation of 1-hydrazinophthalazine also provides the parent compound in moderate yield. 

Phthalazine-1,4-diones reactions, 3, 39 Phthalazines applications, 3, 56 isoindoles from, 4, 152 mass spectra, 2, 21 metabolism, 1, 233 N-oxidation, 3, 20 nitration, 3, 22 nucleophilic attack, 3, 25 oxidation, 3, 31... 

The actual catalyst is a complex formed from osmium tetroxide and a chiral ligand, e.g. dihydroquinine (DHQ) 9, dihydroquinidine (DHQD), Zj -dihydroqui-nine-phthalazine 10 or the respective dihydroquinidine derivative. The expensive and toxic osmium tetroxide is employed in small amounts only, together with a less expensive co-oxidant, e.g. potassium hexacyanoferrate(lll), which is used in stoichiometric quantities. The chiral ligand is also required in small amounts only. For the bench chemist, the procedure for the asymmetric fihydroxylation has been simplified with commercially available mixtures of reagents, e.g. AD-mix-a or AD-mix-/3, ° containing the appropriate cinchona alkaloid derivative ... 

Six-membered ring ADC compounds can be generated by oxidation of the corresponding cyclic hydrazides. Pyridazine-3,6-dione (12) and phthalazine-1,4-dione (13, R = H), often called diazaquinones,4 are stable in solution only at low temperature, but can be generated, and intercepted at higher temperatures.39-43 Fusion of an extra benzene ring increases stability44 and the tetracyclic compound 14 is relatively stable.45 Substituted phthala-zine-l,4-diones have been widely studied because of their involvement in... 

AO is also effective in metabolizing a wide range of nitrogen-containing heterocycles such as purines, pyrimidines, pteridines, quinolines, and diazanaphthalenes (95). For example, phthalazine is rapidly converted to 1-phthalazinone by AO and the prodrug, 5-ethynyl-2-(l//)-pyrimidone, is oxidized to the dihydropyrimidine dehydrogenase mechanism-based inhibitor, 5-ethynyluracil, by AO (Fig. 4.40) (96). 

FIGURE 4.40 Structures of the AO substrates, phthalazine and 5-ethynyl-2-(lf/)-pyrimidone, and their oxidized metabolites, phthalazmone and 5-ethynyluracil, respectively. 

Dienophilic cyclic a-carbonylazo compounds (triazoline diones, indazolone, phthalazine dione) prepared in a flow cell, by anodic oxidation of the corresponding hydrazino compounds in acidic methanol or acetonitrile, react with dienes (Scheme 50) [72, 73]. 

Other functionalized supports that are able to serve in the asymmetric dihydroxylation of alkenes were reported by the groups of Sharpless (catalyst 25) [88], Sal-vadori (catalyst 26) [89-91] and Cmdden (catalyst 27) (Scheme 4.13) [92]. Commonly, the oxidations were carried out using K3Fe(CN)g as secondary oxidant in acetone/water or tert-butyl alcohol/water as solvents. For reasons of comparison, the dihydroxylation of trons-stilbene is depicted in Scheme 4.13. The polymeric catalysts could be reused but had to be regenerated after each experiment by treatment with small amounts of osmium tetroxide. A systematic study on the role of the polymeric support and the influence of the alkoxy or aryloxy group in the C-9 position of the immobilized cinchona alkaloids was conducted by Salvadori and coworkers [89-91]. Co-polymerization of a dihydroquinidine phthalazine derivative with hydroxyethylmethacrylate and ethylene glycol dimethacrylate afforded a functionalized polymer (26) with better swelling properties in polar solvents and hence improved performance in the dihydroxylation process [90]. 

With phthalazine as the heteroarene component and isocyanate in acetonitrile as solvent, uracil 346 affords pyrimido[4, 5 4,5]pyrimido[6,l-fl] phthalazine (358) in a similar way. The combination with isoquinoline affords 359 after KMn04 oxidation. However, with isoquinoline as solvent, 359 is directly available. (See Scheme 129). 

Electrophilic attack of a metal complex on one of the nitrogen atoms of 1,2-diazines has been reported to occur in the mechanism of new metal mediated methods to prepare C-N bonds. Pyrrolo-fused pyridazines and phthalazines for instance were synthesized via attack of the 1,2-diazine on a palladacyclobutane intermediate 34 formed via oxidative addition of an alkylidenecyclopropane to Pd(PPh3)2 (Equation 7) <2004JOC3202>. 

Hydrazone formation of pyridazine-3-hydrazines with aldoses, dialdofuranoses, and dialdopyranoses was studied by Stanovnik and co-workers. The respective hydrazones could be cyclized with Bt2 in MeOH or Pb(OAc)4 to j-triazolo[4,3-3]pyridazin-3-yl substituted polyols <1997JHC1115, 1998JHC513>. Similarly, 4-[(dimethylamino)-methylene]-l,8,8-trimethyl-2-oxabicyclo[3.2.1]octan-3-one was reacted with pyridazine-3-hydrazines and the resulting mixtures were subsequently treated with Pb(OAc)4. Besides j-triazolo[4,3-3]pyridazine formation also diazenes were obtained. This can be rationalized by the enehydrazine-hydrazone mixtures observed in the first reaction. For phthalazin-l-hydrazines only diazenes were obtained after oxidation <2005TA2927>. Also cyclizations of... 

---