Pyridines 3- pyridones synthesis

Vinamidinium salts are important intermediates in the synthesis of heterocycles. The 2-chloro-l,3-bis(dimethylamino)trimethinium hexafluorophosphate salt has been used in the preparation of the highly selective Cox-2 inhibitor etoricoxib (Scheme 1). This method describes a straight-forward preparation of the hexafluorophosphate salt which is a crystalline, thermally and shock-stable, non-hygroscopic solid. The submitters have extensively studied the preparation of vinamidinium salts and demonstrated that the method is applicable to substituted acetic acids that contain an electron-withdrawing group (Table 1)." The annulation reaction is also general and useful for the preparation of pyridines, pyridones and pyridine N-oxides. ... 

Grosche, P., Holtzel, A., Walk, T. B., Trautwein, A. W., Jung, G. Pyrazole, pyridine, and pyridone synthesis on solid support. Synthesis 1999, 1961-1970. 

Rhodium-catalyzed [2+2+2] cycloadditions for the synthesis of substituted pyridines, pyridones, and thiopyranimines 13H(87)1017. Synthesis of six-membered azaheterocycles by means of the P-lactam synthon method 13MR01. 

Substituted pyridines and pyridazines represent privileged scaffolds and are present in various therapeutic agents and in multiple classes of natural products (08CHEC(7)1, 08CHEC(8)1). Diverse approaches for the synthesis of pyridines, pyridones, and pyridazines using RCM as the key step are described below. 

Both dialkylamine and pyridine can function as leaving groups in this type of pyridone synthesis. For example, 6-phenyl-2-pyridone can be formed from wdimethylaminopropiophenone and TV- carbamylmethyOpyridinlum chloride (XII-138) (Section 1.1., p. 599). 

A third synthesis which has resulted in the preparation of rieinine and a number of its derivatives is due to Schroeter, Seidler, Sulzbacher and Kanitz,i2 who foimd that cyanoacetyl chloride polymerises spontaneously to 6-chloro-2 4-dihydroxy-3-cyano-pyridine. The di-sodium derivative of this with methyl sulphate produces A -methyl-6-chloro-4-hydroxy-3-cyano-2-pyridone (6-chlororicininic acid), the mono-sodium derivative of which, with methyl bromide or sulphate, is converted into 6-chlororicinine and the latter is reduced by zinc and sulphuric acid to rieinine. A fourth synthesis, starting from 3-nitro-4-pyridone, is due to Reitmann. ... 

The Boekelheide reaction has been applied to the synthesis of non-natural products with the preparation of quaterpyridines serving as an example. The sequence began with the 2,4-linked bipyridyl-N-oxide 25. Execution under the typical reaction conditions produced the expected bis-pyridone 26. Treatment with POCI3 afforded the corresponding dichloride that was submitted to a palladium-catalyzed coupling with 2-stannyl pyridine to produce the desired quaterpyridine 27. 

Scheme 1 A few routes for the synthesis of 2-pyridones from functionalized pyridines...

The cycloadducts formed from the Diels-Alder reaction of 3-amino-5-chloro-2(17/)-pyrazinones with methyl acrylate in toluene are subject to two alternative modes of ring transformation yielding either methyl 6-cyano-l,2-dihydro-2-oxo-4-pyridinecarboxylates or the corresponding 3-amino-6-cyano-l,2,5,6-tetrahydro-2-oxo-4-pyridinecarboxylates. From the latter compounds, 3-amino-2-pyridones can be generated through subsequent loss of HCN <96 JOC(61)304>. Synthesis of 3-spirocyclopropane-4-pyridone and furo[2,3-c]pyridine derivatives can be achieved by the thermal rearrangement of nitrone and nitrile oxide cycloadducts of bicyclopropylidene <96JCX (61)1665>. 

Nitroenamines and related compounds have been used for synthesis of a variety of heterocyclic compounds. Rajappahas summarized the chemistry of nitroenamines (see Section 4.2).140 Ariga and coworkers have developed the synthesis of heterocycles based on the reaction of nitropyridones or nitropyrimidinone with nucleophiles. For example, 2-substituted 3-nitro-pyridines are obtained by the reaction of l-methyl-3,5-dinitro-2-pyridones with ketones in the presence of ammonia (Eq. 10.82).141... 

Another synthesis of halopyridines, unique to pyridine and other JV-containing heteroarenes, involves transformation of pyridine N-oxide into the corresponding pyridone followed by halogenation. In one case, treatment of 3-chloro-2,4 -bipyridine-l -oxide (8) with acetic anhydride produced the pyridone, which was then converted to dichloride 9 with POCls/DMF [7]. 

As mentioned in Section 10.1.2, Padwa and co-workers (40,41) employed the Pummerer reaction to generate and trap isomtinchnones. This group (190,191) has now adapted the intramolecular version of this tactic to the synthesis of several alkaloids of the pyridine, quinolizidine, and clavine classes. In each case, a 2-pyridone serves as the keystone intermediate. For example, Kuethe and Padwa (190) employed this Pummerer reaction of imidosulfoxides that contain tethered iz-bonds in a formal synthesis of the frog alkaloid ( )-pumiliotoxin C. They also used this methodology to synthesize the azafluorenone alkaloid onychine (295) (Scheme 10.42) (191). Generation of the thionium ion 291 under standard... 

Reactions involving the [4 + 1 + 1] principle, an example of which is shown in equation (136), are rather uncommon and of strictly limited utility [3 + 2 + 1] and [2 + 2 + 2] processes, on th,e other hand, are well known. Representative [3 + 2+1] three-bond formation processes are given in equations (137)—(141), from which it can be seen that the common situation is where ammonia, a substituted amine or formamide constitutes the one-atom fragment. Many [2 + 2 + 2] atom fragment syntheses are known and some are familiar reactions. Thus, the cobalt(I)-catalyzed condensation of nitriles and isocyanates with alkynes gives pyridines and 2-pyridones, often in excellent yield (e.g. equation 142), while the cyclotrimerizations of nitriles, imidates, isocyanates, etc., are well established procedures for the synthesis of 1,3,5-triazine derivatives (e.g. equation 143). Further representative examples are given in equations (144)-(147), and the reader is referred to the monograph chapters for full discussion of these and other [2 + 2 + 2] processes. Examination of the... 

Disilylation of furo[3,4-r-]pyridine followed by dialkylation leads to the formation of a-disubstituted derivatives in good yields (61-70%). This methodology provides a key step in the synthesis of the pyridone alkaloid cerpegin, 54 <2004OL2925>. 

Furo[2,3- ]pyridines can be synthesized from alkynylpyridones and iodonium sources (Scheme 31) <20060L1113>. Iodine proved to be much more effective at promoting the iodocyclization reaction than other iodonium sources (ICl, A -iodosuccinimide (NIS)). The pyridinium triiodide salt, 104, can be converted into the corresponding pyridinone by treatment with an external source of iodide. In a variation of the reaction, a one-pot synthesis of the furopyridine derivatives 105 can be achieved, with overall yields of 79-92%, by treatment with iodine followed by sodium iodide without isolation of the triiodide salt. Another similar one-pot synthesis involves 3-iodo-2-pyridones, terminal alkynes, and organic halides in a series of two palladium cross-coupling reactions (Equation 45) <20030L2441>. This reaction could also be carried out in a two-step sequence, but the overall reaction yields were typically improved for the one-pot method. 

The powerful 7V,7V-diethylcarbamate DMG serves admirably for the synthesis of substituted oxygenated pyridines. Thus, metalation of all isomeric pyridyl O-carbamates 317 with sec-BuLi/TMEDA followed by quench with numerous electrophiles affords diversely substituted products 318 in good to excellent yields (Scheme 96) (85JOC5436). Base-induced hydrolysis provides access to pyridones and hydroxypyridines. 

Cycloadditions where the 2ir component is an inline or iminium species have been much used for the synthesis of reduced pyridines and pyridones (B-87MI505-01), see also a general review of imine cycloadditions (87H(26)777). 

It is known that 3-aminobenzo[6]furan can be prepared from o-cyanophenols and a-halogenocarbonyl compounds with subsequent Thorpe cyclization (73JPR779). The extension of this synthesis to heteroatom substituted benzo[6]furans is straightforward (76JPR313). The reaction of potassium salts of 3-cyano-2-pyridones (e.g. 27) with a-halogenocarbonyl compounds (esters, ketones) yields 2-alkoxy-3-cyanopyridines which can be cyclized in the presence of sodium ethoxide to give 3-aminofuro[2,3-6]pyridines (Scheme 6). 

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