Rhodium-catalyzed synthesis pyridines

Takahashi [31]. To get good yields, nitrobenzene was added as a hydrogen acceptor (Scheme 1.11a). But on running the carbonylation of azobenzene via cobalt catalysis, quinazoUne was obtained as the terminal product Furthermore, Chatani and coworkers described a rhodium-catalyzed synthesis of maleimides starting from a combination of alkynes and pyridine-2-yhnethylamine in the presence of CO (Scheme 1.11b) [53]. 

Park and coworkers developed a rhodium-catalyzed synthesis of pyri-dines from 2i/-azirines and carbenoids [72]. In the presence of catalytic amount of [Rh2(esp)2], highly substituted pyridines were produced in good to excellent yields (Scheme 3.34). This procedure was applied by Liang and CO workers in the synthesis of CFs-containing pyridines recently [73]. 

The rhodium-catalyzed synthesis of 2-picolylamines and imidazo[l,5-a]pyridines from pyridotriazoles has been achieved (Scheme 3.16) [16], For the preparation of 2-picolylamines (Example 3.4), the reaction was operationally simple and consisted of stirring a dinuclear rhodium catalyst with the two reagents at 120 °C. This approach tolerated a broad spectrum of preexisting functional groups, and even 3(2-/0-pyridazinone was successfully used. For the preparation of the imidazo[l,5-fl]pyridines, a two-stage approach was used for the preparation of the heterocycles that included an initial N-H insertion followed by cyclization. 

A synthesis of a set of 2-pyridylpyrroles has been described, involving annulation of 1,3-dicarbonyl compounds with 2-(aminomethyl)pyridine under acidic conditions, as illustrated by the construction of compound 437 (Equation 121) <20020L435>. Likewise, pyrroles have also been obtained from reactions between 1,3-diaryl-l,3-dicarbonyl compounds and imines or oximes promoted by the TiCU/Zn-system <2004SL2239>. Yet another approach involves rhodium-catalyzed reactions of isonitriles with 1,3-dicarbonyl synthons, which enables for instance preparation of fluorinated pyrroles <20010L421>. 

Cheng and co-workers reported a one-pot synthesis of substituted pyridines through a rhodium-catalyzed C-H alkenylation of a,(3-unsaturated ketoximes 287 with symmetrical alkyne substrates 288. 67t-Electro-cyclization of the azatriene intermediates 289 and subsequent loss of water afforded the desired pyridines 290 in moderate to good yields. ... 

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. 

Rhodium-catalyzed chelation-assisted C—H bond functionalization reactions (enantioselective annulation of aryl imines, dihydropyridine synthesis from imines and ahcynes, one-pot synthesis of pyridines from imines and alkynes, 2-arylpyridine alkylation with imines) 12ACR814. Synthesis of pyridine and dihydropyridine derivatives by regjo- and stereoselective addition to N-activated pyridines 12CRV2642. 

Wan and coworkers reported a rhodium-catalyzed [2 -I- 2 + 2] cycloaddition of oximes and diynes for the synthesis of pyridines in 2013 [45]. In their mechanistic study, they exclude the dehydration of oxime to generate the corresponding nitrile followed by the cycloaddition of the nitrile and the alkynes to afford the pyridine as the pathway. As only a trace amount of benzonitrile was produced from oxime under the reaetion conditions. Additionally, pyridine product was detected in less than 20% yield when benzonitrile was subjected to the reaetion with diyne instead of oxime (Scheme 3.19). EtOh was tested as solvent here as well, but not produeed. Later on, they found that by using Rh (NBD)2BF4/MeO-Biphep as the eatalyst system, the reaction can be performed in EtOH [46]. 

A rhodium-catalyzed one-pot synthesis of substituted pyridine derivatives from a,(3-unsaturated ketoximes and alkynes was developed in 2008 by Cheng and coworkers [99], Good yields of the desired pyri-dines can be obtained (Scheme 3.48). The reaction was proposed to proceed via rhodium-catalyzed chelation-assisted activation of the (3—C—H bond of a,(3-unsaturated ketoximes and subsequent reaction with alkynes followed by reductive elimination, intramolecular electro-cyclization, and aromatization to give highly substituted pyridine derivatives finally [100]. Later on, in their further studies, substituted isoquinolines and tetrahydroquinoline derivatives can be prepared by this catalyst system as well [101]. Their reaction mechanism was supported by isolation of the ort/jo-alkenylation products. Here, only asymmetric internal alkynes can be applied. 

Ellman, Bergman, and coworker reported a rhodium-catalyzed procedure for the synthesis of pyridines from alkynes and a,/ -unsaturated N-benzyl aldimines and ketimines in 2008 [107]. The reaction proceeded via C-H alkenylation/electrocyclization/aromatization sequence through dihydropyridine intermediates. The C-H activated complex was isolated and determination by X-ray analysis. Good yields of highly substituted pyridines were produced in one-pot manner (Scheme 3.50). 

Allyl amines and alkynes were explored as starting materials for pyridines synthesis by Jun and coworkers as well [109]. The reaction proceeded through a sequential Cu(II)-promoted dehydrogenation of the allylamine and Rh(III)-catalyzed iV-annulation of the resulting a,/3-unsaturated imine and alkyne. Moderate to good yields of pyridines can be isolated (Scheme 3.52). This transformation was later on explored with ruthenium catalyst [110]. In the presence of [ RuCl2(p-cymene) 2] (0.1 equiv.), KPFe (0.1 equiv.), and Cu(OAc)2 (1 equiv.) in tAmOH at 100°C, the desired pyridine derivatives were formed in good yields. In this case, the reaction started with C-H activation and then insertion to alkynes which is different from the rhodium catalyzed case. 

The complex has enjoyed relatively little use in organic synthesis. For iridium-catalyzed homogeneous hydrogenation of alkenes, Crabtree s iridium complex ((1,5-Cycloocta-diene)(tricyclohexylphosphine)(pyridine)iridium(I) Hexafluoro-phosphate) is generally preferred, although this readily prepared Ir complex is active. It is more reactive than its rhodium counterpart in the catalytic isomerization of butenyl- to allylsilanes. ... 

In contrast to carbocyclic alkyne cyclotrimerizations, the catalytic pyridine synthesis from alkynes and nitriles relies exclusively on cobalt catalysts with a few exceptions where rhodium [16] and iron complexes [17] could be applied. The cobalt-catalyzed pyridine synthesis can even be carried out in a one-potreac-tion generating the catalyst from C0CI2 6 H20/NaBH4 -1- nitrile/alkyne in situ [18]. 

The synthesis of chiral racemic atropisomeric pyridines by cobalt-catalyzed [2 + 2 + 2] cycloaddition between diynes and nitriles was reported in 2006 by Hrdina et al. using standard CpCo catalysts [CpCo(CO)2, CpCo(C2H4)2, CpCo(COD)] [34], On the other hand, chiral complexes of type II were used by Gutnov et al. in 2004 [35] and by Hapke et al. in 2010 [36] for the synthesis of enantiomerically enriched atropisomers of 2-arylpyridines (Scheme 1.18). This topic is described in detail in Chapter 9. It is noteworthy that the 2004 paper contains the first examples of asymmetric cobalt-catalyzed [2 - - 2 - - 2] cycloadditions. At that time, it had been preceded by only three articles dealing with asymmetric nickel-catalyzed transformations [37]. Then enantioselective metal-catalyzed [2 -i- 2 - - 2] cycloadditions gained popularity, mostly with iridium- and rhodium-based catalysts, as shown in Chapter 9. 

While application of the transition-metal-catalyzed [2 - - 2 - - 2] cycloaddition reaction and its variants for the construction of a benzene unit led to a plethora of natural products with different molecular structures and architectures, its use for the construction of a pyridine moiety within a natural product synthesis is less well developed. The reason for this is uncertain and should not account for the pyridine formation per se the co-cyclization of two alkynes with a nitrile unit to give a pyridine core can be catalyzed efficiently by cobalt, ruthenium, and cationic rhodium complexes, as shown in many methodology-oriented studies [35]. 

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