Insertion reactions five-membered heterocycle synthesis

A Ni°-based system related to those already described in connection with syntheses of both cyclobut-enediones and several five-membered heterocycles (Sections 9.4.2.1, 9.4.3.3 and 9.4.3.5) is also capable of catalyzing pyridone synthesis from isocyanates and alkynes. However, the structures found for the isolable metallacyclic intennediates in this system imply a completely different insertion sequence isocyanate first, followed by the two alkynes (Scheme 35). As a consequence, the regiochemistry found in the products of reaction of unsymmetrical alkynes is the reverse of that typical of Co larger substituents end up at positions 4 and 6. Thus, starting wiA the carbonyl carbon of the isocyanate, each carbon-caib-on bond forming event is strongly regioselective for the less-hindered alkyne caibon (equation 46). The... 

The transition metal catalyzed synthesis of seven membered and larger heterocycles attracted considerably less attention than the preparation of their five and six membered analogues. Typical examples in this chapter include the formation of heterocycles in insertion reactions, or through carbon-heteroatom bond formation. Although the formation of some macrocyclic natural products was also achieved in cross-coupling reactions they will not be discussed in detail. 

The formation of five- and six-membered heterocycles by radical cyclization is discussed in a comprehensive review <2004H(63)1903>. Representative examples of ring syntheses involving carbenoid (Table 6) or nitrenoid (Table 7) intermediates are given. In many cases, the free carbene or nitrene is probably not involved, and the distinction between insertion and addition reactions given in the tables is not always clear cut. Such reactions are particularly useful for the preparation of tricyclic compounds. The application of carbenes and carbenoids in the synthesis of heterocyles is summarized in a review <1996AHC(65)93>. 

Rapoport and co-workers have reported a general synthesis of nitrogen, oxygen, and sulphur heterocycles (218) by rhodium-catalysed intramolecular N-H, 0-H, or S-H insertion reactions.of keto-ester precursors (217)- This reaction is well documented as an efficient route to B-lactams but this group has now shown that the reaction works well for the synthesis of five-and six-membered nitrogen heterocycles (Scheme 22). The reaction fails for seven-membered nitrogen heterocycles in this case C-H insertion to give a eyelopentanone is the preferred reaction mode. 

The insertion of CO into Pd-carbon bonds has also been employed in several tandem/cascade reactions that afford five-membered nitrogen heterocycles [97]. A representative example of this approach to the construction of heterocydes involves synthesis of isoindolinones via the Pd-catalyzed coupling of 2-bromobenzaldehyde with two equivalents of a primary amine under an atmosphere of CO [97bj. As shown below (Eq. (1.57)), this method was used for the preparation of 144 in 64% yield. The mechanism of this reaction is likely via initial, reversible condensation of 2-bromobenzaldehyde with 2 equiv of the amine to form an aminal 145. Oxidative addition of the aryl bromide to Pd° followed by CO insertion provides the acylpalladium spedes 146, which is then captured by the pendant aminal to afford the observed product. An alternative mechanism involving intramolecular imine insertion into the Pd—C bond of a related acylpalladium species, followed by formation of a paUadium-amido complex and C—N bond-forming reductive elimination has also been proposed [97b],... 

In 2013, Carreira and coworkers presented an attractive strategy for the synthesis of chiral pyrrolidones via ruthenium-catalyzed intramolecular hydrocar-bamoylation of allylic formamides under CO atmosphere (Eq. (7.2)) [7]. A formal ruthenium-catalyzed intramolecular insertion into the formamide C-H bond and concomitant C-C bond formation by olefin hydrocarbamoylation were involved in the reaction, which made the reaction complete atom economy. The cycliza-tion performed with a broad substrate scope. More interestingly, even homoallylic and bis-homoallylic formamide substrates were used, the reactions afforded five-membered nitrogen-containing heterocycles only. 

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