Intermolecular reactions carbopalladation

In their pioneering work on the catalytic carbopalladation reaction of 1,2-heptadiene with phenyl iodide in the presence of a suitable base, Shimizu and Tsuji observed the formation of the corresponding substituted 1,3-dienes 62 via a / -hydride elimination from the 7z>allyl intermediate 61 [61]. Based on these observations, a three-component Heck-Diels-Alder cascade process has been developed by Grigg and co-workers [73]. A wide variety of aryl and heteroaryl iodides were used for the intermolecular reaction with dimethylallene to afford the corresponding 1,3-dienes. These subsequently react in situ with N-methylmaleimide to give the bicyclic adducts 63 (Scheme 8.30). 

The reaction is thought to proceed by co-ordination of the alkene with the organopalladium(II) species, followed by carbopalladation. Subsequent p-hydride elimination regenerates an alkene and releases palladium(II). This is reduced (reductive elimination) to palladium(O) in the presence of a base, to allow further oxidative addition and continuation of the cycle (1.211). The carbopalladation and p-hydride elimination steps occur syn selectively. Excellent regioselectivity, even for intermolecular reactions, is often observed, with the palladium normally adding to the internal position of terminal alkenes (except when the alkene substituent is electron-rich as in enamines or enol derivatives), thereby leading to linear substitution products. 

Numerous examples of Heck-type reactions are known, where the common /3-H-elimination usually following the carbopalladation step is inhibited because of stractural or stereochemical reasons. Either the intermolecular reaction with an additional reagent or another cyclization reaction then terminates the Pd-catalyzed process. Such reactions are discussed below, again starting from substrates related to the substructure shown in Figure 1. 

There are only a few cases of an intermolecular reaction of a 7r-allylpalladium complex with an alkene. The carbopalladation of norbomadiene with a stoichiometric amount of a TT-allylpalladium complex to yield an allyl-substituted a--norbomenylpalladium species has been reported In the context of mechanistic studies of Pd-catalyzed alkene dimerization, the insertion of ethylene into a cationic 7r-allylpalladium complex was also reported as a stoichiometric reaction in 1996 (Scheme... 

Grigg and Xu have developed a variety of so-called queuing cascades involving allenes. The intra-intermolecular carbopalladation sequence of the <9-iodo-A-methyl-A -(methylallyl)aniline 142 and 1,1-dimethylallene 143 with subsequent / -dehydropalladation leads to the 1,3-dienyl-substituted indole derivative 144, which is immediately trapped by an added dienophile (e.g., A-methylmaleimide) in a Diels-Alder reaction to yield 145 (Scheme 37)7 ... 

Ma and co-workers have reported the selective synthesis of pyrrolidine derivatives through a three-component reaction based on a conceptually related strategy (Scheme 8.29) [72], Beginning with the catalytic intermolecular carbopalladation of y-allenic malonate 57 in the presence of a base, they succeeded in intercepting the internal carbonucleophile 58 with an imine such as the N-benzylidene p-toluenesulfonamide 59. The attack of the newly formed heteronucleophile on the 7r-allyl palladium intermediate affords the functionalized pyrrolidine 60 with high... 

Whereas the intermolecular Heck reaction is limited to unhindered alkenes, the intramolecular version permits the participation of even hindered substituted alkenes, and many cyclic compounds can be prepared by the intramolecular Heck reaction [37]. The stereospecific synthesis of an A ring synthon of la-hydroxyvitamin D has been carried out. Cyclization of the (7T)-alkene 88 gives the (fT)-exo-diene 90, and the (Z)-alkene 91 affords the (Z)-exo-diene 92 [38]. These reactions are stereospecific, and can be understood by cis carbopalladation to form 89 and the. sun-elimination mechanism. 

Oxypalladation of vinyl ether, followed by alkene insertion, is an interesting synthetic route to functionalized cyclic ethers. In prostaglandin synthesis, the oxypalladation of ethyl vinyl ether (40) with the protected cyclopentenediol 39 generates 41 and its intramolecular alkene insertion generates 42. The intermolecular insertion of the alkene 43, and /1-elimination of 44 occurred as one-pot reaction at room temperature, giving the final product 45 in 72% yield [46], The stereochemistry of the product shows that the alkene insertion (carbopalladation of 41) is syn. It should be noted that the elimination of /1-hydrogen from the intermediate 42 is not possible, because there is no /1-hydrogen syn coplanar to the Pd and, instead, the insertion of alkene 43 occurs. 

Carbopalladation occurs with soft carbon nucleophiles. The PdCl2 complex of COD (100) is difficult to dissolve in organic solvents. However, when a heterogeneous mixture of the complex, malonate and Na2C03 in ether is stirred at room temperature, the new complex 101 is formed. This reaction is the first example of C—C bond formation and carbopalladation in the history of organopalladium chemistry. The double bond becomes electron deficient by the coordination of Pd(II), and attack of the carbon nucleophile becomes possible. The Pd-carbon n-bond in complex 101 is stabilized by coordination of the remaining alkene. The carbanion is generated by treatment of 101 with a base, and the cyclopropane 102 is formed by intramolecular nucleophilic attack. Overall, the cyclopropanation occurs by attack of the carbanion twice on the alkenic bond activated by Pd(II). The bicyclo[3.3.0]octane 103 was obtained by intermolecular attack of malonate on the complex 101 [11]. 

As discussed in conjunction with the intermolecular cascade carbopalladation reaction shown in Scheme 4, it has been very difficult to satisfactorily control both queuing or pair -selectivity and regioselectivity of intermolecular cascade carbopalladation processes. Consequently, essentially all of the cascade carbopalladation reactions discussed here are at least partially intramolecular. The currently known cyclic cascade carbopalladation processes can be classified into a few to several types shown in Scheme 6. 

There are at least two issues to be addressed regarding the Type lie circular cascade process shown in Scheme 42. One is the regioselectivity in the initial intermolecular carbopalladation. Since it is not very difficult to differentiate the two terminal positions of a. j-diyncs, this is not a serious problem in most cases. A more serious problem is the exclusive formation of fulvene derivatives observed in a couple of cases [124] (Scheme 45). It is not very clear what the scope of the fulvene formation is and whether the course of the reaction could be altered to give benzene derivatives. 

The same authors also reported on palladium-catalyzed domino cycli-zation-anion capture reactions employing allene (69) as a relay switch (Scheme 10) [52], Such a reaction of the alkynyl-tethered aryl iodide 68 starts with an oxidative addition to the catalytic metal species, and is followed by an intramolecular carbopalladation of the triple bond. An intermolecular car-... 

The palladium-catalyzed reaction of allyl chloride 11 with the benzyne precursor 104 to produces phenanthrene derivatives 131 is also known [83]. A plausible mechanism for this intermolecular benzyne-benzyne-alkene insertion reaction is shown in Scheme 38. Initially n-allyl palladium chloride la is formed from Pd(0) and 11. Benzyne 106, which is generated from the reaction of CsF and 104, inserted into la to afford the aryl palladium intermediate 132. A second benzyne insertion into 132 produce 133 and subsequent carbopalladation to the alkene afford the cyclized intermediate 134. f>- Iydride elimination from 134 followed by isomerization gave 9-methylphenanthrene 131. 

A palladium(II)-catalyzed three component coupling reaction was established by Lu, who performed the intermolecular carbopalladation involving propargyl alcohols and alkenes, and this was followed consecutively by allylic chloride insertion to the C-Pd bond and its quenching by p-heteroatom elimination in the presence of an excess of chloride ions. An example is shown below <03TL467>. 

---