Transition metal complexes triynes

Nitrogen-containing 15-membered trialkyne macrocycles, such as l,6,ll-frw(aiylsulfonyl)-l,6,ll-triazacyclopentadeca-3,8,13-triynes and enediynes as 1,6,11-frw(arylsulfonyl)-1,6,11-triazacyclopentadeca-3-ene-8,13-diynes have been prepared and subjected to a [2+2+2]-cyclotrimerization process catalyzed by transition metal complexes, e.g., RhCl(CO)(PPh3)2 <05JOC2033>. The reaction of pemosylated diethylenetriamine and 2-substituted propan-1,3-... 

Complexation of triynes to Pd(0) has been reported to give homoleptic palladium alkyne complexes that show a trigonal-planar arrangement with all of the alkyne carbons and Pd in the same plane. Complex 73 is a macrocyclic complex synthesized by reaction of the triyne with Pd(PPh3)4- Due to coordination to the metal, the alkyne carbons are shifted to the center of the cycle and their substituents deviate from linearity by about 22°. Complex 74 undergoes clean intramolecular cyclization at room temperature upon addition of PPh3 (Equation (24)). No intermediate complexes were detected in the course of this reaction, which is an example of the important cycloisomerization of alkynes and enynes catalyzed, among other transition metal complexes, by Pd(0) derivatives. 

Cycloaddition of aUcynes catalysed by transition metals is one of the most efficient and valuable ways to prepare benzene and pyridine systems [12], Among the possible catalytic systems able to catalyse this reaction, cobalt and iron complexes containing NHCs as ligands have shown high catalytic activity in the intramolecular cyclotrimerisation of triynes 36 (Scheme 5.10) [13]. The reaction was catalysed with low loading of a combination of zinc powder and CoC or FeClj with two or three equivalents of IPr carbene, respectively. 

The central six-membered ring unit in the illudalane or pterosin class of sesquiterpenes makes them a suitable target for a proof of the synthetic power of the transition-metal-catalyzed [2 + 2 + 2] alkyne cycloaddition in natural product synthesis. A first example in this field was provided by the intramolecular version of the [2 + 2 + 2] alkyne cyclotrimerization in the synthesis of calomelanolactone (15) [8] and pterosin Z (16), both of which have been isolated Ifom the silver fern Pityrogramma calome-lanos (Scheme 7.4) [9]. Wilkinson s complex served here as the catalyst, and the cyclotrimerization of triyne 13 proceeded at room temperature to give the tricycle 14. The latter was used as a common synthetic intermediate for completion of the synthesis of calomelanolactone (15) and pterosin Z (16) within four and three synthetic steps, respectively. 

The reaction of [2+2+2] cycloaddition of acetylenes to form benzene has been known since the mid-nineteenth century. The first transition metal (nickel) complex used as an intermediate in the [2+2+2] cycloaddition reaction of alkynes was published by Reppe [1]. Pioneering work by Yamazaki considered the use of cobalt complexes to initiate the trimer-ization of diphenylacetylene to produce hexasubstituted benzenes [54]. Vollhardt used cobalt complexes to catalyze the reactions of [2+2+2] cycloaddition for obtaining natural products [55]. Since then, a variety of transition complexes of 8-10 elements like rhodium, nickel, and palladium have been found to be efficient catalysts for this reaction. However, enantioselective cycloaddition is restricted to a few examples. Mori has published data on the use of a chiral nickel catalyst for the intermolecular reaction of triynes with acetylene leading to the generation of an asymmetric carbon atom [56]. Star has published data on a chiral cobalt complex catalyzing the intramolecular cycloaddition of triynes to generate a product with helical chirality [57]. 

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