Jt-allylpalladium

Palladium can be the leaving atom if the substrate is a Jt-allylpalladium complex (an T complex). Ions of ZCHZ compounds react with such complexes in the presence of triphenylphosphine, for example. 

The vinylcyclopropane 144, bearing two electron-withdrawing groups, undergoes the intermolecular palladium-catalyzed [3 + 2]cycloaddition reaction of the Jt-allylpalladium intermediate 145 with a,/ -unsaturated esters or ketones to provide a useful method for forming the cyclopentane ring of 146 [74], (Scheme 51)... 

A nice and convergent approach to both compounds makes use of RCM to form the 5-membered building block 71, which mimics the carbohydrate part of the nucleosides. The necessary diene precursor 69 is readily assembled via Evans aldol chemistry. RCM then affords the ring in almost quantitative yield (69->70), leaving the chiral centers and the free hydroxyl group intact. Removal of the chiral auxiliary by reductive cleavage, attachment of the base by means of jt-allylpalladium chemistry, and a final deprotection step complete these highly efficient syntheses [46]. 

The proposed mechanism involves the usual oxidative addition of the aryl halide to the Pd(0) complex affording a Pd(II) intermediate (Ar-Pd-Hal), subsequent coordination of allene 8 and migratory insertion of the allene into the Pd-C bond to form the jt-allylpalladium(II) species 123. A remarkable C-C bond cleavage of 123 leads by decarbopalladation to 1,3-diene 120 and a-hydroxyalkylpalladium species 124. /8-H elimination of 124 affords aldehyde 121 and the H-Pd-Hal species, which delivers Pd(0) again by reaction with base (Scheme 14.29). The originally expected cyclization of intermediate 123 by employment of the internal nucleophilic hydroxyl group to form a pyran derivative 122 was observed in a single case only (Scheme 14.29). 

Shimizu and Tsuji [4] reported the first highly regioselective synthesis of 1,2-di-substituted allylic amines through capture of a Jt-allylpalladium complex by pyrrolidine (Scheme 16.2). This methodology has since been extended to a wide range of amines and allenes [5]. 

The reaction was further applied to the synthesis of spiro heterocycles (Scheme 16.4) [8], The oxidative addition of an iodide to a Pd(0) species generates an ArPdl species, into which an internal olefin inserts to form an alkylpalladium complex otherwise difficult to access. Allene participates in the reaction at this stage to provide a jt-allylpalladium complex, which is attacked by the amine intramolecularly to afford the procuct. 

A one-pot synthesis of 3,3-disubstituted indolines was achieved by taking advantage of a sequential carbopalladation of allene, nucleophile attack, intramolecular insertion of an olefm and termination with NaBPh4 (Scheme 16.6) [10]. First, a Pd(0) species reacts with iodothiophene selectively to afford ArPdl, probably because the oxidative addition step is facilitated by coordination with the adjacent sulfur atom. Second, the ArPdl adds to allene, giving a Jt-allylpalladium complex, which is captured by a 2-iodoaniline derivative to afford an isolable allylic compound. Under more severe conditions, the oxidative addition of iodide to Pd(0) followed by the insertion of an internal olefm takes place to give an alkylpalladium complex, which is transmetallated with NaBPh4 to release the product. 

The palladium-catalyzed reaction of iodobenzene and an allenyl malonate provided vinylcyclopropane in a highly regioselective manner (Scheme 16.7) [11, 12]. A jT-allylpalladium complex, generated by the addition of PhPdl to a 2-allenyl malonate, can be trapped by an internal malonate anion to afford a vinylcyclopropyl derivative. The site selectivity in this cyclization is dependent on the nature of the entering RX groups, catalytic systems involving phosphine ligands, solvents and bases. 

The possibility of Jt-allylpalladium complex formation through carbopalladation is excluded from the observation that no four- and/or six-membered rings are produced. The reaction apparently proceeds via an alternative pathway which involves a sequence of Jt-coordination of PhPdl to an allenic terminal double bond, oxypallada-tion and ensuing reductive elimination (Scheme 16.9). 

First, oxidative addition of 2-iodophenol to a Pd(0) species gives rise to an arylpal-ladium complex, which in turn undergoes carbonylation followed by insertion of allene to generate a 2-acyl-jt-allylpalladium complex. Attack by an internal hydroxyl group gives an a-exo-methylene ketone (Scheme 16.11). 

An a-allenic sulfonamide undergoes Pd-catalyzed carbonylative cyclization with iodobenzene, affording a mixture of isomeric heterocycles (Scheme 16.12) [17]. The coupling reaction of an allene with a PhCOPdl species takes place at the allenyl central catrbon to form a 2-acyl-Jt-allylpalladium complex, which is attacked by an internal sulfonamide group in an endo mode, affording a mixture of isomeric heterocycles (Scheme 16.13). 

Homoallylic alcohols are provided by Pd-catalyzed reaction of iodobenzene, allene and aldehydes (Scheme 16.15) [19, 20]. A nucleophilic allylindium intermediate is generated through transmetallation of a Jt-allylpalladium species with indium. Such a Jt-allylpalladium complex can alternatively be provided through carbopalladation of ArPdl to a proximate acetylene followed by insertion of allene. 

The reaction of an allenylcyclobutanol with ArPdl would provide four possible jT-allylpalladium complexes, that is, two anti- and two syn-isomers. The rearrangement would, however, take place more favorably via two anti-isomers, A and B, which are equilibrated. Consequently, the products can be provided in a highly dia-stereoselective manner via thermodynamically more stable intermediate A (Scheme 16.22) [26],... 

Ma and Zhao reported a highly regio- and diastereoselective synthetic method for 2-amino-3-alken-l-ols and 4-amino-2-( )-alken-l-ols by the palladium-catalyzed reaction of 2,3-allenols, aryl iodides and amines (Scheme 16.24) [29]. Carbopalladation of PhPdl to the allene probably generates a thermodynamically more stable anti-Jt-allylpalladium species for steric reasons. Regioselectivity of the amine attack depends largely on the stereoelectronic effect on the a-substituents. 

The efficiency of chirality transfer of chiral 2,3-allenic acids can be much increased by switching the Jt-allylpalladium mechanism to a coordinative cycliza-tion-reductive elimination route (Scheme 16.25) [30]. 

Three-component assembly of allenes, organic halides and arylboronic acids has been reported in which Suzuki coupling of a Jt-allylpalladium complex with an orga-noboronic acid is utilized (Scheme 16.26) [31], Addition of phosphorus ligands to the reaction mixture greatly decreases either the product yields or E/Z ratios. The decrease in E/Z ratio may be explained based on the fact that donor ligands readily promote anti-syn rearrangement of a Jt-allylpalladium species via a cr-allylpalladium intermediate. 

In the absence of a nucleophile, the reaction of allenes with aryl bromides provides 1,3-dienes in good yield (Scheme 16.27) [32], The reaction is very sensitive to the reaction temperature, solvent, base and amount of phosphine used. The formation of a 1,3-diene may be explained by either /3-hydrogen elimination or deprotonation at the a-carbon of the Jt-allylpalladium intermediate. 

Synthetically useful allylstannanes are provided by palladium-catalyzed carbostan-nylation using hexamethylditin (Scheme 16.58) [63]. The reaction mechanism can be rationalized by transmetallation between ditin and a Jt-allylpalladium complex produced by reaction of an allene with an arylpalladium iodide. In this process, hexamethylditin is added to the reaction mixture slowly via a syringe pump to suppress its high reactivity towards the arylpalladium species leading to an arylstannane. 

Scheme 16.90 Ene reaction of an allene with a Jt-allylpalladium complex.

The stereoselectivity of the allene attack has been demonstrated by the catalytic reaction of cis and trans seven-membered allenic compounds, in which cis- and trans-fused 5,7-ring systems are provided in 76 and 40% yield, respectively, via Jt-allylpalladium intermediates (Scheme 16.91). 

The following observations are intriguing from both mechanistic and synthetic viewpoints (Scheme 16.92). In the stoichiometric reactions, electron-withdrawing ligands (e.g. dba) on palladium are necessary for the olefmic double bond to attack a jt-allylpalladium group. The resulting electrophilic Jt-allylpalladium group becomes... 

A bromoallene was demonstrated to act as an allyl dication equivalent. When treated with Pd(0) in an alcoholic solvent, an ei-hydroxybromoallene provides a mediumsized heterocycle (Scheme 16.101) [106]. The oxidative addition of a bromoallene to Pd(0) generates an allenylpalladium species, which is successively transformed into a Jt-allylpalladium complex through the attack of the hydroxyl group on the sp carbon followed by the protonation of the resulting Pd-carbene complex. Finally, the products are provided as a mixture of regioisomers by the nucleophilic attack of the external methanol. 

In 1998, Yamamoto et al. reported the first catalytic enantioselective allylation of imines with allyltributylstannane in the presence of a chiral 7i-allylpalladium complex 23 (Scheme 9) [15]. The imines derived from aromatic aldehydes underwent the allylation with high ee values. Unfortunately, the allylation reaction of aliphatic imines resulted in modest enantioselectivities. They proposed that a bis-Jt-allylpalladium complex is a reactive intermediate for the allylation and reacts with imines as a nucleophile. The bis-Jt-allylpalladium complex seemed the most likely candidate for the Stille coupling [16]. Indeed, the Stille coupling reaction takes place in the presence of triphenylphosphine even if imines are present, whereas the allylation of imines occurs in the absence of the phosphine [17]. They suggested the phosphine ligand played a key role in controlling the... 

Hydrocarbonation of enyne proceeds via hydropalladation of enyne with 16, which affords the exo methylene Jt-allylpalladium complex. Reductive elimination would lead to formation of 5. 

In the hydrocarbonation of methylenecyclopropanes 8 with nitriles, the hydro-palladation of 8 with 16 gives the alkylpalladium complexes 23 and/or 24 (Scheme 5). The complex 23 would undergo rearrangement by distal bond cleavage to give the Jt-allylpalladium 25 (route A). The reductive elimination of Pd(0) from 25 produces 9. The palladium complex 24 would isomerize to the Jt-allylpalladium complex 27 via proximal bond cleaved ring-opened intermediate 26 (route B). The reductive elimination of Pd(0) from 27 gives 10. 

The hydrocarbonation of 3,3-dihexylcyclopropene proceeds via the formation of palladacyclobutene intermediate 28 (Scheme 6). The pallada-ene type reaction between 28 and 1 produces the Jt-allylpalladium intermediate 29. Reductive elimination gives the allylated products 12 and/or 13. 

The Pd-catalyzed hydrocarbonations of methyleneaziridines 14 do not proceed through the formation of a Jt-allylpalladium intermediates, instead via a chelation effect. The hydropalladation of methyleneaziridines with the Pd(II) hydride species 16, followed by reductive elimination gives the non-ring-opened products 15. It is noteworthy to mention that the palladium-catalyzed intermolecular or intramolecular addition of nitriles to carbon-carbon multiple bonds can be explained by the hydropalladation mechanism, except for the intramolecular addition to the C=C triple bond of alkynes (vide infra). 

---