Pauson-Khand reaction catalytic asymmetric

Abstract The transition metal mediated conversion of alkynes, alkenes, and carbon monoxide in a formal [2 + 2+1] cycloaddition process, commonly known as the Pauson-Khand reaction (PKR), is an elegant method for the construction of cyclopentenone scaffolds. During the last decade, significant improvements have been achieved in this area. For instance, catalytic PKR variants are nowadays possible with different metal sources. In addition, new asymmetric approaches were established and the reaction has been applied as a key step in various total syntheses. Recent work has also focused on the development of CO-free conditions, incorporating transfer carbonylation reactions. This review attempts to cover the most important developments in this area. 

The asymmetric catalytic Pauson-Khand reaction met success in the late 1990s. Not only the conventional Co catalyst but also other metal complexes, such as Ti, Rh, and Ir, are applicable to the reaction. Asymmetric hydrocyanation of vinylar-enes is accomplished using Ni complex of chiral diphosphite. Further studies on the scope and limitation are expected. 

Parasites, antimicrobials for, 12, 458 Pauson-Khand reaction allenic substrates, 11, 352 and allenynes, 10, 356-357 with aminocarbonylation, 11, 531 asymmetric catalysts, in desymmetrizations, 11, 357 catalytic... 

There has been significant interest in the development of a catalytic asymmetric Pauson-Khand type reaction because of its vast potential in organic synthesis. A boom in research activity in this field has focused in two areas - the development of catalytic Pauson-Khand type cyclizations and of stoichiometric syntheses of optically active cyclopentenones via the Pauson-Khand reaction, including a recent report of the first intramolecular catalytic asymmetric Pauson-Khand type cyclization. In this review, the existing catalytic systems will be briefly surveyed followed by a detailed analysis of the asymmetric variant. The stoichiometric syntheses of optically active cyclopentenones will also be discussed. 

Although tremendous advances in the catalytic Pauson-Khand reaction have been made, the development of an asymmetric version did not share the same degree of success. Several asymmetric Pauson-Khand reactions were reported using chiral auxiliaries. However, those systems required stoichiometric amounts of cobalt as well as the chiral source. Attempts at using a catalytic amount of cobalt did not give satisfactory results. By contrast, the use of titanium chiral catalyst S,Sy (EBTHI)Ti(CO)2 (EBTHI = ethylene-l,2-bis(tiM,5,6,7-tetrahydro-l-indenyl)... 

Catalyst for the first catalytic asymmetric Pauson-Khand reaction. 

The cyclopentenone 277 and a small amount of the cyclopentanone 278 are obtained by the carbonylation (1 atm) of titanacycle 276, generated from 1,6-enyne 275 and 273 [120], However, this Pauson-Khand type reaction of the 1,6-enyne proceeds with a catalytic amount of Cp2Ti(CO)2. Furthermore, asymmetric... 

Catalytic Asymmetric Pauson-Khand Type Reaction. 10... 

The availability of a chiral version of Cp2Ti(CO)2 was instrumental in the development of the first catalytic asymmetric Pauson-Khand type reaction [39]. This work utilized a catalyst containing the ethylene-1,2-bis( 17 -4,5,6,7-tetrahydro-l-indenyl) (EBTHI) ligand (Fig. 4,16) first introduced into Group 4 chemistry by Brintzinger [40]. Complexes containing this ligand have proven extremely effective in a number of applications in asymmetric catalysis [41]. 

The greater part of this chapter is concerned with the Diels-Alder and hetero-Diels-Alder reaction. The asymmetric version of both of these reactions can be catalysed with metal-based Lewis acids and also organocatalysts. The catalytic asymmetric 1,3-dipolar cycloaddition of nitrones and azomethine ylides is also discussed. Again, most success in this area has been achieved using metal-based Lewis acids and the use of organocatalysts is begiiming to be explored. This chapter concludes with a brief account of recent research into the asymmetric [2+2]-cycloaddition, catalysed by enantiomerically pure Lewis acids and amine bases, and also the Pauson-Khand [2- -2- -l] cycloaddition mediated by titanium, rhodium and iridium complexes. 

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