Cycloaddition transition-metal-promoted

Nelson J. H. Transition Metal-Promoted Intramolecular [4 + 2 Diels-Alder Cycloadditions of Phospholes With Dienophilic Ligands in Phosphorus-31 NMR Spectral Prop. Compd. Charact. Struct. Anal. 1994 203, Ed. Quin L. and Verkade J. G., Pb. VCH N.Y. 

Balme G, Bouyssi D, Monteiro N (2006) The Virtue of Michael-Type Addition Processes in the Design of Transition Metal-Promoted Cyclizative Cascade Reactions. 19 115-148 Barluenga J, Rodriguez F, Fanands FJ, Fldrez J (2004) Cycloaddition Reaction of Group 6 Fischer Carbene Complexes. 23 59-121 Basset J-M, see Candy J-P (2005) 16 151-210... 

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... 

Abstract Cascade reactions involving a transition metal-promoted step and a Michael-type addition process have emerged as a powerful tool to construct cyclic and polycyclic structures. In this review, recent advances in this field are presented. The first part is related to cycloaddition reactions based on zwitterionic jr-allylPd complexes. The second part deals with Michael initiated metal-catalyzed cyclofunctionalization reactions of unactivated C C jt-bonds. Parts three and four feature reactions where an initial Michael addition reaction is followed by either a coupling reaction or an electrophilic trapping. Part five is devoted to Michael terminated reactions. 

The introduction of transition metal catalysts has led to a revolution in the field of organic synthesis. Some of the most powerful applications have involved transition metal-promoted cycloadditions [1,2,3]. These methodologies have provided for the rapid construction of complex carbo- and heterocycHc structures... 

To date, the most commonly used transition metal-promoted cycloaddition in organic synthesis is the Pauson-Khand reaction. First reported by Pauson and Khandin 1973 [9],this transformation is the cobalt-mediated [2+2+1] cycloaddition of an alkyne, an alkene and carbon monoxide to form a cyclopentenone, Eq. (1). Although mechanistic understanding is Hmited, the accepted mechanism for the transformation is depicted in Fig. 2. Loss of two equivalents of CO followed by complexation of an alkyne produces 1. Subsequent loss of CO from... 

Fig.1. Total synthesis applications of transition metal-promoted cycloadditions...

Transition metal promoted higher-order cycloadditions J. H. Rigby, Acc. Chem. Res. 1993, 26, 579. 

Acetylenes can undergo a number of thermal and transition metal promoted cycloaddition reactions. Besides the [2 + 2 + 2] cycloaddition (see Sect. 5) the reaction of acetylenes with late transition metal (so-called Fischer ) carbenes is noteworthy for the synthesis of highly and regioselectively functionalized naphthalene derivatives (Dotz reaction), while the co-cycloaddition of acetylenes with alkenes and carbon monoxide gives cyclopentenones (Pauson-Khand reaction) [159,160]. 

While the number of transition-metal-promoted cycloadditions of acetylenes is quite large... 

Table 11.1 is adapted from Hoffmann, R. Woodward, R. B. /. Am. Chem. Soc. 1965, 87, 2046. Cycloaddition reactions involving more than a total of six electrons in the two iz systems are known as higher order cycloadditions. Transition metals have been found to be effective in promoting such reactions. Rigby, J. H. Acc. Chem. Res. 1993, 26, 579. 

Synthesis of / -lactams via transition metal promoted Staudinger [2-1-2] cycloaddition of a ketene and an imine has been reviewed (63 references). " ... 

It is believed that clay minerals promote organic reactions via an acid catalysis [2a]. They are often activated by doping with transition metals to enrich the number of Lewis-acid sites by cationic exchange [4]. Alternative radical pathways have also been proposed [5] in agreement with the observation that clay-catalyzed Diels-Alder reactions are accelerated in the presence of radical sources [6], Montmorillonite K-10 doped with Fe(III) efficiently catalyzes the Diels-Alder reaction of cyclopentadiene (1) with methyl vinyl ketone at room temperature [7] (Table 4.1). In water the diastereoselectivity is higher than in organic media in the absence of clay the cycloaddition proceeds at a much slower rate. 

As discussed in Section 6.9 1, 3-dienes and dienophiles in which multiple bonds are not activated by electron-withdrawing or electron-releasing substituents fail to undergo cycloaddition except under the most severe conditions. Particular difficulty is encountered in the cycloaddition of two unactivated species since homodimerization can be a competitive and dominant reaction pathway. The use of transition-metal catalysts, however, has proved to be a valuable solution. Complexation of unactivated substrates to such catalysts promotes both inter- and intramolecular cycloadditions. Consequently, the cycloaddition of such unactivated compounds, that is, simple unsubstituted dienes and alkenes, catalyzed by transition metals is a major, important area of study.655 In addition, theoretical problems of the transformation have frequently been addressed in the more recent literature. 

The reaction of methylenecyclopropanes with transition metal complexes is well known to promote a catalytic a-ir cycloaddition reaction with unsaturated compounds, in which a trimethylenemethane complex might exist71-76. Recently, much interest has been focused on the interaction of strained silicon-carbon bonds with transition metal complexes. In particular, the reaction of siliranes with acetylene in the presence of transition metal catalysts was extensively investigated by Seyferth s and Ishikawa s groups77-79. In the course of our studies on alkylidenesilirane, we found that palladium catalyzed reaction of Z-79 and E-79 with unsaturated compounds displayed ring expansion reaction modes that depend on the (Z) and (E) regiochemistry of 79 as well as the... 

Among the carbonylative cycloaddition reactions, the Pauson-Khand (P-K) reaction, in which an alkyne, an alkene, and carbon monoxide are condensed in a formal [2+2+1] cycloaddition to form cyclopentenones, has attracted considerable attention [3]. Significant progress in this reaction has been made in this decade. In the past, a stoichiometric amount of Co2(CO)8 was used as the source of CO. Various additive promoters, such as amines, amine N-oxides, phosphanes, ethers, and sulfides, have been developed thus far for a stoichiometric P-K reaction to proceed under milder reaction conditions. Other transition-metal carbonyl complexes, such as Fe(CO)4(acetone), W(CO)5(tetrahydrofuran), W(CO)5F, Cp2Mo2(CO)4, where Cp is cyclopentadienyl, and Mo(CO)6, are also used as the source of CO in place of Co2(CO)8. There has been significant interest in developing catalytic variants of the P-K reaction. Rautenstrauch et al. [4] reported the first catalytic P-K reaction in which alkenes are limited to reactive alkenes, such as ethylene and norbornene. Since 1994 when Jeong et al. [5] reported the first catalytic intramolecular P-K reaction, most attention has been focused on the modification of the cobalt catalytic system [3]. Recently, other transition-metal complexes, such as Ti [6], Rh [7], and Ir complexes [8], have been found to be active for intramolecular P-K reactions. 

Abstract This review gives an insight into the growing field of transition metal-catalyzed cascades. More particularly, we have focused on the construction of complex molecules from acyclic precursors. Several approaches have been devised. We have not covered palladium-mediated cyclizations, multiple Heck reactions, or ruthenium-catalyzed metathesis reactions because they are discussed in others chapters of this book. This manuscript is composed of two main parts. In the first part, we emphasize cascade sequences involving cycloaddition, cycloisomerization, or ene-type reactions. Most of these reaction sequences involve a transition metal-catalyzed step that is either followed by another reaction promoted by the same catalyst or by a purely thermal reaction. A simple change in the temperature of the reaction mixture is often the only technical requirement to go from one step to another. The second part covers the cascades relying on transition metalo carbenoid intermediates, which have recently undergone tremendous... 

The use of alkynes in transition metal catalyzed reactions is often complicated by their tendency to undergo cyclo-tiimerization and -tetramerization. Thus, it is useful to note that a phosphite-modified catalyst, Ni(COD)2Aris(o-phenylphenyl) phosphite (TOPP), promotes codimerization of alkynes with methylenecyclopropane and its a ylidene analogs. Both electron-rich and electron-poor alkynes participate in cycloaddition with moderate regioselectivity. Opposite regiochemistiy is sometimes observed widi disubstituted alkylidene systems (equations 97-99). 

The cycloaddition of free carbenes to alkenes to give cyclopropanes is well known (see equation 10.2). Transition metal-carbene complexes, acting either stoichiometrically or catalytically, promote cyclopropanation, sometimes in a synthetically-useful manner. Several mechanistic pathways have been observed, some of which involve mid-transition metal alkylidenes. Two of the most common of these are outlined in Scheme 10.6.67... 

Two transition metal catalyzed [27t + 2strained hydrocarbons, reacts with exo-tricyclo[3.2.1.0 " ]oct-6-ene (5) to give tetracyclo[3.3.0.0 .0 ]octane (6) in quantitative yield. The endo-isomer is unreactive. ... 

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