Alkene derivatives carbopalladation

Konno T, Taku K, Ishihara T. Highly stereoselective one-pot synthesis of tetrasubstituted alkenes via carbopalladation reaction of fluorine-containing acetylene derivatives. J. Fluorine Chem. 2006 127 966 972. 

Five-membered ring closures have been observed when o-halostyrene derivatives such as 113 were coupled with alkenes under palladium catalysis. Apparently, an intramolecular carbopalladation with S-exo-trig ring closure to give 114-R can favorably compete with / -hydride elimination in the first-formed intermediate to yield 115-R This reaction mode for the halostyrene is observed especially under Jeffery conditions, when the alkene is ethene or propene (Scheme 31). Under the same conditions, however, < -dibromobenzene gives very high yields of o-dialkenylbenzene derivatives (see Scheme 2). ... 

When the carbopalladation of the bicyclopropylidene is performed in the presence of methyl acrylate, the reaction takes a different course (Scheme 8.34) [79]. The 1,3-diene intermediate 75 reacts in situ with the dienophile to give the spiro[2.5]octane derivative 76. An extension of this cascade Heck-Diels-Alder reaction involving l,3-dicyclopropyl-l,2-propadiene as the alkene partner, an alkenyl or aryl halide and a dienophile has been reported [80]. 

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. 

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. 

Oxidative carbonylation of alkenes is a unique reaction of Pd(II). Three types of oxidative carbonylation to give -substituted acid derivatives 130, a, -unsaturated esters 132 and succinate derivatives 134 are known, which can be understood by the following mechanism. Palladation of alkenes with PdX2, followed by CO insertion, generates the acylpalladium intermediate 129 whose reductive elimination affords -substituted carboxylic acid derivatives 130 (path a). Reaction in alcohol in the presence of a base starts by the formation of the alkoxycarbonylpalladium 128. Carbopalladation of alkene with 128 generates 131. Then y3-H elimination of the intermediate 131 yields the a-unsaturated ester 132 (path b). Further CO insertion to 131 gives the acylpalladium intermediate 133 and its alcoholysis yields the succinate derivative 134 (path c). Formation of the jS-alkoxy ester 130 (X-OR) is regarded as nucleophilic substitution of Pd-X in 131 with alcohols. 

D.i.a. Formation of Cyclopropane Derivatives by Two Successive Intramolecular Carbopalladations. Intramolecular carbopalladation starting from 1,( —l)-dienes with a suitable leaving group at the 2-position and a substituent at the (n-l)-position of the alkene terminator leads to a neopentylpalladium intermediate, which can only continue the cascade by a 3-eJto-tng-carbopalladation to eventually form bicyclo[(n—2). 1.0]alkenes. This sequence works equally well for ring sizes five, six, and seven in the first formed ring (Scheme 22) and even heterocyclic systems can be constructed by this mode (Scheme 22). 

D.i.b. Insertion of Another Alkenyl Unit In certain cases, however, the 3-exo-trig process may be retarded and an additional alkene moiety participates in the cascade carbopalladation. A pioneering example of this kind has been demonstrated by Overman and co-workers in their total synthesis of scopadulcic acid A, starting from an iodoaUcenyl-substituted methylenecycloheptene derivative (Scheme 24). The first intramolecular carbopalladation occurs across the disubstituted double bond of the exomethylene group, and the trisubstituted endocyclic double bond acts as the terminator to give a tricyclic system, which was further elaborated to the natural product (Scheme 24). It is remarkable that all three quaternary carbon centers can be created by intramolecular Heck reactions. 

Three simpler ort/io-substituted iodobenzene derivatives with two alkene moieties in the side chains have been cascade cycUzed to give methylenespiroalkane-annelated indanes (Scheme 26) and bicyclic systems (Scheme 27). This outcome clearly demonstrates that the intramolecular carbopalladations are determined by entropic factors, which always favor the formation of the smaller possible ring sizes. 

The 5-exo intramolecular Heck reaction has been employed to construct both meso-chimonanthine 105 and (-)-chimonanthine 106 (Scheme 16). The synthetically most challenging structural features of these bispyrroloindoline alkaloids are their vicinal quaternary centers. The synthetic plan relies on two sequential 5-exo carbopallada-tions to stereoselectively produce pentacycles 102 and 104 from closely related intermediates. Heck cyclization of 100 requires a challenging tetrasubstituted alkene insertion to provide 101. A second 5-exo carbopalladation reaction adjacent to the newly formed quaternary center installs the second quaternary center and oxindole unit. The tartrate-derived ene-diamide 100 underwent bis-5-cJct) carbopalladation when... 

Yang has reported a related tandem cydization for the synthesis of pyrroloindoline derivatives that also proceeds though a mechanism involving alkene aminopalladation followed by carbopalladation of a second alkene [46]. As shown below, the 2-allylaniline derivative 48 was converted to 49 in 95% yield through treatment with a catalyst composed of Pd(OAc)2 and pyridine (Eq. (1.22)). Use of (-)-sparteine as a ligand in this reaction provided 49 with up to 91% ee. 

Ma has developed a three-component allene carboamination reaction for the stereoselective synthesis of 2,5-as-disubstituted pyrrolidine derivatives [54]. A representative transformation involving allene 58, 4-iodoanisole, and imine 59 that generates 60 in 90% yield is shown below (Eq. (1.28)). The reaction is believed to proceed through the intermediate Jt-allylpalladium complex 62, which is formed by carbopalladation of the alkene to give 61 followed by addition of the malonate anion to the activated imine. Intramolecular capture of the allylpalladium moiety by the pendant nitrogen nucleophile affords the pyrrolidine product. A related asymmetric synthesis of pyrazolidines that employs azodicarboxylates as one of the electrophilic components has also been reported [55]. The pyrazolidine products are obtained with up to 84% ee when chiral bis oxazolines are employed as ligands. 

The carbopalladation of a double bond in a Cj-bridge of a bicyclic alkene leads to an intermediate, which does not contain a syn-oriented P-hydrogen and thus cannot undergo a syn-P-hydride eHmination to recreate a double bond. Such carbopalladation intermediates of, for example, norbornene with arylpalladium hahdes therefore find other modes of reaction (Section 8.3.7). In the presence of formic acid or potassium formate as a hydride source, norbornene (65), norbornene derivatives, and heteroanalogs such as 247 and 248, as well as bicyclooctene[2.2.2]octene (251), under typical Heck conditions undergo hydroarylation and hydroalkenyla-tion reactions (Scheme 8.52) [374]. A number of hydroarylation products of type... 

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