Pyridones cycloaddition

In an Initio study of the tautomerism of 2- and -hydroxy-pyridines, 4 -hydroxypyridine was calculated to be 2.4 kcal/mol more stable than 4-pyridone. 2-Pyridone was calculated to be 0.3 kcal /mol more stable than 2-hydroxypyridine and this is in good agreement with experimental values obtained from tautomeric studies in the gas phase.A study of the bromination of the 2-pyridone/2-hydroxypyridine system has revealed that reaction occurs via the principal "one" tautomer at pH<6 and via the conjugate anion at pH>6. Attack on the "one" occurs preferentially at the 3-position, whereas on the anion it probably occurs mainly at the 5-position. The facile formation of 3f5-dibromo-2-pyridone results from the comparable reactivity of the monobromopyridones at pH<1 and pH>4- Practical procedures have been reported for the preparation of 3-bromo-2-pyridone and 3,5-dibromo-2-pyridone Cycloaddition of 2-substituted pyridinium betaines with unsymmetrical alkenes gives products of mixed orientation for example, treatment of (40) with methyl... 

Electron-deficient alkenes add stereospecifically to 4-hydroxy-THISs with formation of endo-cycloadducts. Only with methylvinyl-ketone considerable amounts of the exo isomer are produced (Scheme 8) (16). The adducts (6) may extrude hydrogen sulfide on heating with methoxide producing 2-pyridones. The base is unnecessary with fumaronitrile adducts. The alternative elimination of isocyanate Or sulfur may be controlled using 7 as the dipolarenOphile. The cycloaddition produces two products, 8a (R = H, R = COOMe) and 8b (R = COOMe, R =H) (Scheme 9) (17). Pyrolysis of 8b leads to extrusion of furan and isocyanate to give a thiophene. The alternative S-elimi-nation can be effected by oxidation of the adduct and subsequent pyrolysis. 

Double Diels-Alder cycloadditions of 2-(1H)-pyridones acting as dienophiles [92]... 

Posner G. H. Stereocontrolled Synthesis of Functionalized Cyclohexenes Via Diels-Alder Cycloadditions of 2-Pyrones and 2-Pyridones-Applications to Synthesis of Physiologically Active Compounds in Stereocontrolled Org. Synth. 1994 177, Ed. Trost B. M., Pb. Blackwell Oxford... 

Scheme 3 Examples of Dieckmann-type condensation (a) and [2 + 2 + 2] cycloaddition (b) leading to functionalized and ring-fused 2-pyridones...

Two new pyridone derivatives (14) and (15) have been prepared by cycloaddition of saccharin pseudochloride (16 R = Cl) with Danishefsky s diene and by treatment of (16 R = Me) with ciimamoyl chloride. The synthesis of two more ting expanded derivatives (17) and (18) via cycloaddition to benzisothiazoles was also described <96T3339>. 

Hoomaert has studied Diels-Alder reactions of pyridine oquinodimethane analogs generated from functionalized o-bis(chloromethyl)pyridines <96T(52)11889>. The photochemical cycloaddition of 2-alkoxy-3-cyano-4,6-dimethylpyridine with methacrylonitrile gives a bicyclic azetine, 6-alkoxy-3,5-dicyano-2,5,8-trimethyl-7-azabicyclo[4.2.0]octa-2,7-diene, in moderate yield <96CC1349>. Regiospecific hydroxylation of 3-(methylaminomethyl)pyridine to 5-(methylaminomethyl)-2-(17/)-pyridone by Arthrobacter ureafaciens has been reported <96MI173>. 

The NHC-nickel catalytic system is also useful in the synthesis of pyridones 48. The [2h-2h-2] cycloaddition of diynes 44 and isocyanates 47 affords a wide range of pyridones 48 in excellent yields in presence of [Ni(COD)2]/SIPr catalytic system (Scheme 5.14) [18]. 

Scheme 5.15 Pyridone and/or pyrimidinediones formation from a [2+2+2] cycloaddition NHC-Ni catalysed...

In contrast to some analogous structures, pyrido[2,l-f][l,2,4]triazine 108 is quite stable toward atmospheric oxygen. It reacts, however, with singlet oxygen in a cycloaddition reaction, and the intermediate 109 thus formed loses nitrogen resulting in the pyridone 110 (Scheme 8) <2001JHC205>. 

Padwa and co-workers employed a rhodium-catalyzed [3+2] cycloaddition reaction to generate a number of 3-hydroxy-2-pyridones, including the tricyclic 146, obtained using fV-phenylmaleimide 145 as the dipolarophile. The rhodium-catalyzed cyclization of 143 generates an isomiinchnone intermediate 144, which undergoes the cycloaddition (Scheme 11) <1997JOC438>. 

Other 1,3-dipolar reagents show the same mode of reactivity towards cyclopropenones. Thus, the Munchnones 412 serving as potential azomethine ylides259-261 or the nitrile ylids 41 3262 effect expansion of the three-membered ring to the 4-pyridone systems 411/414 as a result of (2 + 3) cycloaddition to the C /C2 bond. 

Analogously, the mesoionic jV-methyl thiazol-5-ones and l,3-dithiol-4-ones afforded A-methyl-4-pyridones and thiapyran-4-ones when reacting with diphenyl cyclopropenone and its thione261. Benzonitrile oxide apparently gives a 1,3-dipolar cycloaddition to the C=0 group of diphenyl cyclopropenone rationalizing the formation of triphenyl-l,3-oxazin-6-one 41626i ... 

The one step domino cycloaddition-rearrangement process of A-aryl nitrones 78 to BCP (79) afforded spirocyclopropane-annelated pyridones 81 and benzazocinones 82 in good overall isolated yields <00SL1034>. 

Itoh and co-workers reported the ruthenium(n)-catalyzed [2 + 2 + 2]-cycloaddition of 1,6-diynes with isocyanates to afford the corresponding bicyclic pyridones 163 (Scheme 72).356 357 For previously reported ruthenium-catalyzed [2 + 2 + 2]-cycloaddition of 1,6-diynes see Refs 358 and 358a, and for theoretical calculations of the cyclocotrimer-ization of alkynes with isocyanates, isothiocyanates, and carbon disulfide see Refs 359 and 359a. 

In more recent work, Chiu and co-workers [167, 168] have reported an intramolecular 1,3-dipolar cycloaddition approach toward the pseudolaric acids 85, in which the di-polarophile is an unactivated 1,1-disubstituted alkene. Hence, treatment of the diazo ketone 86 with catalytic Rh2(OAc)4 furnished a mixture of tricyclic products 87 and 88 in nearly equal proportions (Scheme 19.13). The synthesis of 2-pyridones [169] and their application to the ipalbidine core [170] has been described. The pentacyclic skeleton of the aspidosperma alkaloids was prepared via the cycloaddition of a push-pull carbonyl ylide [171]. The dehydrovindorosine alkaloids 89 have also been investigated, in which the a-diazo-/ -ketoester 90 undergoes a facile cycloaddition to furnish 91 in... 

Cyclic amino acids 139, when heated in acetic anhydride, probably form initially mesoionic oxazolium 5-oxides (munchnones) subsequent 1,3-dip olar cycloaddition of 1,2-dicyanocyclobutene, loss of carbon dioxide, and opening of the cyclobutane ring lead to dinitriles 140 (80JHC1593). Pyridone 141 is the by-product (together with an indolizine) of the mono-cyclic pyridone dicarboxylate and acrylic ester (73JHC77). 

H-stacking interactions have also been exploited to orientate olefinic moieties in a geometry suitable for photochemical cycloaddition reactions, and have been invoked by Coates et al. to explain the photodimerization and photopolymerization of mono- and diolefins carrying phenyl and perfiuorophenyl groups [43]. Matsumoto et al. reported the photodimerization of 2-pyridone in co-crystals with naphthalene-substituted monocarboxyhc acids, where the stacking of the naphthalene rings provides carbon-carbon distances appropriate for [4+4] cycloaddition [44]. 

Pyridones, as exemplified by ABT-719 (154, Figure 3.8), represent a new class of DNA gyrase inhibitors possessing a broad spectmm of antibacterial activity and, in studies toward such compounds, it was revealed that the C(8) functionality was an important part of the DNA binding action. Azomethine ylide cycloadditions were employed to give a range of proline-type derivatives in order to study stmcture-activity relationships (39). 

Thioisomiinchnones prepared by classical methods (Section 5.1.3) have also been extensively used in [3-1-2] cycloadditions with olefinic dipolarophiles (145-148). In general, the initially formed cycloadducts are isolable. In some instances (Scheme 5.32), they extrude H2S to afford 2-pyridone derivatives of type 88 (148,149). In another example, the double extrusion of H2S and CO occurred to give a pyrrole derivative (150). 

The dipolar cycloaddition chemistry of isomiinchnones is a powerful and concise route to polycyclic azaheterocycles, and Padwa has been the pioneer in this effort. Sheehan and Padwa (159) employed the rhodium-catalyzed isomiinchnone generation and subsequent trapping to a synthesis of 2-pyridones and the alkaloid... 

Pummerer reaction conditions was followed by cycUzation to isomilnchnone 292 and hence to cycloadduct 293, which loses water to form a-pyridone 294. Subsequent manipulation involving deoxygenation and debenzylation completed the synthesis. In similar fashion, the azaanthraquinone alkaloid dielsiquinone was synthesized for the first time. Also, the quinolizidine alkaloids ( )-lupinine and ( )-anagyrine, and the ergot alkaloid ( )-costaclavine were synthesized using this Pummerer cyclization-cycloaddition cascade of imidosulfoxides and isomiinch-nones. 

Cavalleri et al. (219) studied the cycloaddition of thioisomiinchnones with 5-amino-4-methylene-l,2,3-triazolines. The resulting cycloadducts afford 2-pyridones with Raney Ni or 8-thia-6-azabicyclo[3.2.1]octanes with acid. Kato has continued his extensive exploration of cycloaddition studies of mesoionic heterocycles with atypical dipolarophiles. Thus, whereas thioisomiinchnone (320) gave a complex mixture with 6,6-dimethylfulvene (119), it reacted with 2-tert-butyl-6,6-dimethylfulvene to afford 321 in 17% yield (151,152). The cycloaddition of 320 with benzocyclobutadiene was much cleaner to give 322 in 70% yield (114). 

Finally, reaction of 2,4-diphenyl-5(4//)-oxazolone 322 with 4-phenyl-A -tosyl-1-azabuta-1,3-diene was found to be highly dependent on the experimental conditions. At room temperature the sole product was 323 that arises from alkylation of 322 by addition at the imine carbon. However, heating 322 and 4-phenyl-A-tosyl-1-azabuta-1,3-diene gave rise to several products including a 2-pyridone 324, 2,3,6-triphenylpyridine 325, and the pentasubstituted pyrroles 326 and 327. The authors postulated two different reaction mechanisms. Here, both a 1,3-dipolar cycloaddition of the oxazolone and a nucleophilic addition of the oxazolone are possible and that may account for the formation of 324—327. The marked differences in reactivity of 4-phenyl-A-tosyl-l-azabuta-l,3-diene relative to A-alkyl- or A-aryl-1-aza-1,3-dienes was attributed to the powerful electron-withdrawing nature of the tosyl group (Scheme 7.107). ... 

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