Pyridones reactivity

Heteroaromatics such as furan, thiophene, and even the 2-pyridone 280 react with acrylate to form 281(244-246]. Benzene and heteroaromatic rings are introduced into naphthoquinone (282) as an alkene component[247]. The pyrrole ring is more reactive than the benzene ring in indole. 

Fluoropyridine is readily hydroly2ed to 2-pyridone in 60% yield by reflux in 6 Ai hydrochloric acid (383). It is quite reactive with nucleophiles. For example, the halogen mobiUty ratio from the comparative methoxydehalogenation of 2-fluoropyridine and 2-chloropyridine was 85.5/1 at 99.5°C (384). This labihty of fluorine has been utili2ed to prepare fluorine-free 0-2-pyridyl oximes of 3-oxo steroids from 2-fluoropyridine for possible use as antifertihty agents (385). 

As discussed in Section 4.01.5.2, hydroxyl derivatives of azoles (e.g. 463, 465, 467) are tautomeric with either or both of (i) aromatic carbonyl forms (e.g. 464,468) (as in pyridones), and (ii) alternative non-aromatic carbonyl forms (e.g. 466, 469). In the hydroxy enolic form (e.g. 463, 465, 467) the reactivity of these compounds toward electrophilic reagents is greater than that of the parent heterocycles these are analogs of phenol. 

In this solvent the reaction is catalyzed by small amounts of trimethyl-amine and especially pyridine (cf. 9). The same effect occurs in the reaction of iV -methylaniline with 2-iV -methylanilino-4,6-dichloro-s-triazine. In benzene solution, the amine hydrochloride is so insoluble that the reaction could be followed by recovery. of the salt. However, this precluded study mider Bitter and Zollinger s conditions of catalysis by strong mineral acids in the sense of Banks (acid-base pre-equilibrium in solution). Instead, a new catalytic effect was revealed when the influence of organic acids was tested. This was assumed to depend on the bifunctional character of these catalysts, which act as both a proton donor and an acceptor in the transition state. In striking agreement with this conclusion, a-pyridone is very reactive and o-nitrophenol is not. Furthermore, since neither y-pyridone nor -nitrophenol are active, the structure of the catalyst must meet the conformational requirements for a cyclic transition state. Probably a concerted process involving structure 10 in the rate-determining step... 

Taking into account the close relationship to pyridines one would expect 2-pyridones to express similar type of reactivities, but in fact they are quite different. 2-Pyridones are much less basic than pyridines (pKa 0.8 and 5.2, respectively) and have more in common with electron-rich aromatics. They undergo halogenations (a. Scheme 10) [67] and other electrophilic reactions like Vilsmeier formylation (b. Scheme 10) [68,69] and Mannich reactions quite easily [70,71], with the 3 and 5 positions being favored. N-unsubstituted 2-pyridones are acidic and can be deprotonated (pJCa 11) and alkylated at nitrogen as well as oxygen, depending on the electrophile and the reaction conditions [24-26], and they have also been shown to react in Mitsonobu reactions (c. Scheme 10) [27]. 

Pyridones can also be converted to 2-chloropyridines by exchanging the carbonyl functionality using phosphoroxychloride (POCI3) [72]. A combination of N-halosuccinimides and triphenylphosphine has also been applied to introduce halogens in this position [73]. The carbonyl functionality in 2-pyridones makes these systems reactive towards nucleophiles as well, which add in 1,4-reactions with displacement of halides [74]. The use of transition metal mediated couplings like Heck, and Suzuki have also been successfully applied on halogenated 2-pyridones (d. Scheme 10) [36,75]. 

More general processes rely on variations of the Guareschi-Thorpe reaction [14] where condensations between 1,3-dicarbonyls and cyanoacetamide yield functionalized monocyclic 2(lff)-pyridones (a and b. Scheme 2) [15, 16]. Unless the carbonyls are sufficiently different in reactivity, the reaction suffers from poor regioselectivity. The use of 3-alkoxy or 3-amino enones instead of 1,3-dicarbonyls has proven to be a versatile and reliable synthetic methodology where the 1,4-addition controls the regioselective outcome (c and d. Scheme 2) [17-19]. 

The initial step in Scheme 91 presumably involves deprotonation of the phenacyl substituent to give a pyridinium ylide. Such ylides may be generated as reactive (unstable) intermediates in the synthesis of cycl[3.2.2]azines from iV-(trimethylsilylmethyl)-2-pyridones (Scheme 92) in the presence of an excess of DMAD, the cyclazine is the major product <2003S1398>. 

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. 

The pyridone coupling components (4-8), which came into use in the 1960s chiefly for the preparation of greenish yellow disperse and reactive dyes, are made by the condensation of an alkylamine with ethyl acetoacetate and ethyl cyanoacetate. Coupling occurs at the position indicated by the arrow in Scheme 4-13. 

These dyes are invariably monoazo compounds with the reactive system attached to the diazo component, owing to the ready availability of monosulphonated phenylenediamine intermediates. Pyrazolone couplers are most commonly used, as in structure 7.82 (where Z is the reactive grouping), and this is particularly the case for greenish yellow vinylsulphone dyes. Catalytic wet fading by phthalocyanine or triphenodioxazine blues is a characteristic weakness of azopyrazolone yellows (section 3.3.4). Pyridones (7.83), barbituric acid (7.84) and acetoacetarylide (7.85 Ar = aryl) coupling components are also represented in this sector, with the same type of diazo component to carry the reactive function. 

Three salicylate (2-hydroxybenzoate) anions, which have unusual reactivity towards bromine that has been attributed to intramolecular proton transfer assisting electrophilic attack (Tee and Iyengar, 1985, 1990), exhibit modest catalysis (k /k2u = 3 to 10) and have KTS values similar to phenols. Pyridones and their /V-methyl derivatives, three heteroaromatic acid anions, and four phenoxy derivatives show comparable catalysis (k //c2u = 1.7 to 9.5) and Krs values (Table A4.4). 

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). ... 

Pyridine, pyrone and pyridone carboxylic acids undergo decarboxylation when heated, and the general order of reactivity is a > y > p. In pyridine, the carboxylic acids, as expected, exist mainly in the zwitterionic forms and decarboxylation of the a and y isomers under fairly mild conditions is a consequence of the relative stability of the ions of the type (48). 

The intermediacy of an anhydro base (57) was referred to in Scheme 46. Analogous anhydro bases (pyridone methides) can be formed by deprotonation of quaternary salts of 2- and 4-benzylpyridines and the like. The pyridone methides are usually highly reactive and not readily isolable some stable examples are shown in Scheme 49. Pyridine methides are intermediates in the base-catalyzed alkylation and acylation reactions of pyridinium salts at the exocyclic carbon. Compounds of type (60) have been estimated to have 25-30% dipolar character. Protonation of (60) occurs at the 2 - and 3 -positions in the ratio 4 1 respectively (70JCS(C)800). 

The anhydro bases, e.g. (61), formed by deprotonation of 2- and 4-alkylquinolinium salts, are more stable than the pyridone methides and are usually isolable. They are reactive enamines and some typical chemistry is shown in Scheme 50. 

In pyrrolopyridine synthesis reactions, nitropyridines are less reactive than the corresponding nitropyridone derivatives due to the decreased aromaticity of the pyridone ring. The pyridone is more attractive for nucleophilic attack in the reaction <2002H(58)301> (see Section 10.06.5.3). 

For ring systems that incorporate a pyridine ring, chemistry and reactivity of pyridone derivatives have been incorporated into Sections 10.06.5-10.06.9, wherever appropriate. For crystalline products, which represent most of the derivatives contained within this chapter, the compounds exist as the pyridone tautomer. 

As part of a synthesis program for the preparation of new antiinflammatory drugs, Pasutto et al. (85SC607) investigated the reactivity of benzo-pyrano[2,3-c]pyridinium salts 173. Upon treatment with sodium hydroxide or other nucleophiles, ring opening occurred and generated the 3-benzoylated 2-pyridones 174. In some-cases. Decker oxidation of the salts also produced the tricyclic derivatives 175 (Scheme 29). 

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