Cobalt Pauson-Khand reaction

Perez-Castells and colleagues used Co fCOlj to transform N-(2-ethynylphenyl)-N-(prop-l-enyl) acetamide to a cyclopenta[(t]indol-2-one (Scheme 2, equation 1) [7]. Saito and colleagues adapted a Pauson-Khand reaction, using either COj(CO)g or Mo(CO), to the syntheses of IH-pyrrolo[2,3-fc]indol-2-ones and 2//-thieno[2,3-( ]indol-2-ones (equation 2) [8, 9]. Molybdenum is actually superior to cobalt in these Pauson-Khand reactions vide infra). Mukai and coworkers used a cobalt Pauson-Khand reaction to synthesize pyrrolo[2,3-b]indoles including the alkaloid physostigmine (equation 3) [10,11]. 

RCM of 132 to the medium-sized enyne 135, for example, appears to be highly unlikely. This transformation was achieved by conversion of 132 to the cobalt complex 133, which is cyclized to the protected cycloenyne 134. Deprotection yields 135, and a subsequent Pauson-Khand reaction yields the interesting tricyclic structure 136 (Scheme 27) [125c]. 

The intermolecular Pauson-Khand reaction of the resulting S/P-cobalt complexes with norbornadiene was studied under thermal and A -oxide activation conditions. Thus, heating the diastereomerically pure complex (R = Ph, R = Cy) with ten equivalents of norbornadiene at 50 °C in toluene afforded the corresponding exo-cyclopentenone in a quantitative yield and with an enantio-selectivity of 99% ee. Under similar conditions, the analogous trimethylsilyl complex (R = TMS, R = Cy) afforded the expected product in a high yield but with a lower enantioselectivity of 57% ee. In order to increase this enantio-selectivity, these authors performed this reaction at room temperature in dichloromethane as the solvent and in the presence of NMO, which allowed an enantioselectivity of 97% ee to be reached. These authors assumed that the thermal activation promoted the isomerisation of the S/P ligand leading to a nonstereoselective process. 

Later, Chung et al. successfully developed an intramolecular Pauson-Khand reaction in water without any cosolvent by using aqueous colloidal cobalt nanoparticles as catalysts. The catalyst was prepared by reducing an aqueous solution of cobalt acetate containing sodium dode-cyl sulfate (SDS) surfactant. The cobalt nanoparticle could be reused eight times without any loss of catalytic activity (Eq. 4.57).107... 

A combination of Co-mediated amino-carbonylation and a Pauson-Khand reaction was described by Pericas and colleagues [286], with the formation of five new bonds in a single operation. Reaction of l-chloro-2-phenylacetylene 6/4-34 and dicobalt octacarbonyl gave the two cobalt complexes 6/4-36 and 6/4-37 via 6/4-35, which were treated with an amine 6/4-38. The final products of this domino process are azadi- and azatriquinanes 6/4-40 with 6/4-39 as an intermediate, which can also be isolated and separately transformed into 6/4-40 (Scheme 6/4.11). 

Under the conditions of the cobalt-mediated carbonylative A-oxide-promoted cocyclization (Pauson-Khand reaction) at room temperature, compound 547 provides exocyclic 1,3-diene 548 as the major product (>98%) together with only traces of the corresponding carbonylative product 549. Owing to the relative instability of the diene, it is more efficient to perform a one-pot cobalt cyclization/Diels-Alder process after A-oxide-promoted cyclization of the cobalt complexes. Compound 550 is obtained as a single diastereomer in 39% overall yield if MTAD is used as a dienophile (Scheme 90) <2003JOC2975>. 

The Pauson-Khand reaction (PKR) [96] consists of the synthesis of cyclopen-tenones by reaction of an alkene with a dicobalthexacarbonyl complexed alkyne (Scheme 57) and has recently emerged as one of the methods of choice for the obtainment of five-membered carbocyclic rings [97]. Its unique atom connectivity, which involves the two unsaturated carbons of the reagents and the carbon atom of a carbon monoxide ligand of cobalt usually in a regioselective manner (Scheme 57), has brought to refer to PKR as a [2 -I- 2 + 1] cycloaddition. 

S. Son, S. Lee, Y. Chung, S. Kim, and T Hyeon, The first intramolecular Pauson—Khand reaction in water using aqueous colloidal cobalt nanoparticles as catalysts. Organ. Lett. 4,277—279 (2002). 

Transition-metal-promoted cycloaddition is of much interest as a powerful tool for synthesis of carbocyclic stmcture in a single step. Utilization of carbon monoxide as a component of the cycloaddition reaction is now widely known as the Pauson-Khand reaction, which results in cyclopentenone formation starting from an alkyne, an alkene, and carbon monoxide mediated by cobalt catalyst. Although mechanistic understanding is limited, a commonly accepted mechanism is shown in Scheme 4.16. Formation of dicobalt-alkyne complex followed by alkene... 

Several reports have appeared on the effect of additives on the Pauson-Khand reaction employing an alkyne-Co2(CO)6 complex. For example, addition of phosphine oxide improves the yields of cyclopentenones 119], while addition of dimethyl sulfoxide accelerates the reaction considerably [20]. Furthermore, it has been reported that the Pauson-Khand reaction proceeds even at room temperature when a tertiary amine M-oxide, such as trimethylamine M-oxide or N-methylmorpholine M-oxide, is added to the alkyne-Co2(CO)6 complex in the presence of alkenes [21]. These results suggest that in the Pauson-Khand reaction generation of coordinatively unsaturated cobalt species by the attack of oxides on the carbonyl ligand of the alkyne-Co2(CO)6 complex [22] is the key step. With this knowledge in mind, we examined further the effect of various other additives on the reaction to obtain information on the mechanism of this rearrangement. 

Some of the most striking examples for an intramolecular Pauson-Khand reaction involving a tetrasubstituted double bond are the cobalt-mediated cyc-lizations of bicyclopropylidene derivatives 234 leading to the interesting spirocyclopropanated tricyclic products 235. The successful cyclizations even of the trimethylsilyl-substituted enynes 234 demonstrate the unique reactivity of the strained double bond in the bicyclopropylidene moiety of these molecules (Scheme 55) [145]. 

The Pauson-Khand reaction has been used to obtain 4/5/5 systems from /3-lactams having unsaturated 3,4-substituents. Thus, the reaction of 443 with cobalt octacarbonyl in the presence of TMANO gave 444 in 80% yield C1996TL6901, 1998JOC6786>. 

The Pauson-Khand reaction provides a route to the 4/6/5 system from 3,4-disubstituted /3-lactams having both alkenyl and alkynyl groups, and will allow the presence of some functional groups on the substituents. The reaction of cobalt octacarbonyl and TMANO with 448 furnished 449 in 55% yield as a mixture of diastereoisomers in a ratio of 70 30 <1998JOC6786>. 

Some of the most exciting reactions in organic chemistry are based on transition metals. How about these two for example The first is the Heck reaction, which allows nucleophilic addition to an unactivated alkene. Catalytic palladium (Pd) is needed to make the reaction go. The second, the Pauson-Khand reaction, is a special method of making five-membered rings from three components an alkene, an alkyne, and carbon monoxide (CO). It requires cobalt (Co). Neither of these reactions is possible without the metal. 

We have concentrated on palladium because it is the most important of the transition metals but we must not leave you with the idea that it is the only one. We shall end with two reactions unique to cobalt—the Pauson-Khand reaction that we mentioned right at the start of the chapter and the Vollhardt co-trimerization. You will sec at once that cobalt has a special affinity with alkynes and with carbon monoxide. 

The Pauson-Khand reaction starts with the replacement of two CO molecules, one from each Co atom, with the alkyne to form a double a complex with two C-Co a bonds, again one to each Co atom. One CO molecule is then replaced by the alkene and this n complex in its turn gives a a complex with one C-Co a bond and one new C-C a bond, and a C-Co bond is sacrificed in a ligand coupling reaction. Then a carbonyl insertion follows and reductive elimination gives the product, initially as a cobalt complex. 

Similarly, Chung et al. described a cobalt-catalyzed route to 5.5.5.6 tetracyclic compounds. Tetracyclic dienones were prepared by double Pauson-Khand reaction of triynes. Interestingly, reactions of triynes such as 38 with CO in the presence of 2.5 mol% of Co2(CO)s did not give any [5.5.5.5]fenes-trane derivative but a bridged system (39) (Scheme 19). 

Pauson-Khand reaction cobalt-alkyne complexes in organic synthesis, 117... 

Recently, colloidal cobalt has been used for catalytic Pauson-Khand reactions.149 531 Bearing in mind the encouraging results from other nanoparticle-catalysed reactions in ionic liquids, such catalysts may prove to be highly promising. 

Considerable efforts have been made to develop asymmetrical variants of the classical Pauson-Khand reaction. Initial investigations have shown that compounds derived from cobalt complexes of type 1, in which a carbonyl ligand is replaced by a chiral phosphane (glyphos), react with high enantioselectivity [22], However, the procedure is too complex to be of preparative value. The concept of Kerr et al., who achieved significant enantioselectivities (max. 44 % ee) in intermolecular Pauson-Khand reactions by... 

Pauson-Khand Cycloaddition. Pauson Khand cycloaddition (see Pauson-Khand Reaction) is a cobalt-mediated method to prepare cyclopentenone from the cyclization of an alkyne with an alkene and CO (equation 14). This method is widely used to produce cychc ketones. Originally, stoichiometric amounts of Co2(CO)g were used in these reactions with the cobalt carbonyl being the CO source. However, it was shown that a strict temperature profile and high-purity reagents allowed the use of catalytic amounts of Co2(CO)g for reactions with 1 atm of CO. Currently, there is intense interest in developing catalytic cobalt starting materials for use in Pauson-Khand reactions. 

Pauson-Khand Bicyclization. Alkynyl and enol ether derivatives have been studied in the cobalt-mediated intramolecular Pauson-Khand reaction and found to provide high diastere-oselectivity, superior to previous work with the auxiliary 2-phenylcyclohexanol. The 3-substituted auxiliary alcohol (3) provides higher selectivity than the 2-substituted analog. Also, the alkynyl ether derivatives exhibit higher reactivity and selectivity than the corresponding enol ether derivatives (eq 6). 

Electronic effects on alkene regioselectivity in the Pauson-Khand reaction have also been observed. The regioselectivity observed in cycloadditions of norbomen-2-ones has been interpreted as arising from an electronic preference for attachment of the 5 C-S of the alkene to an alkyne carbon rather than cobalt in the bond-forming insertion step (equation 13). In these systems electronic and steric effects have been separated by carrying out identical reactions with the corresponding norbomen-2-ols, in which the... 

The Pauson-Khand reaction is a well-known method for preparing cydopente-nones by the [2 + 2 + 1] cycloaddition reaction of alkyne, alkene and CO. While reactions using stoichiometric amounts of Co2(CO)g were initially examined, catalytic versions with cobalt, titanium, rhodium, iridium, and ruthenium complexes have recently been developed. Whilst the intramolecular version is rather easy, the inter-molecular version is a very difficult problem that has not yet been solved [76]. 

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