Heck reaction alkene carbopalladation

Larhed, M., Hallberg, A. The Heck reaction (alkene substitution via carbopalladation-dehydropalladation) and related carbopalladation reactions, in Handbook of Organopalladium Chemistry for Organic Synthesis (eds. Negishi, E.-i.,De Meijere, A.), 1,1133-1178 (Wiley-... 

IV.2 The Heck Reaction (Alkene Substitution via Carbopalladation-Dehydropalladation) and Related Carbopalladation Reactions... 

Negishi E, de Meijere A (2002) Handbook of organopalladium chemistry for organic synthesis, Chapter IV.2. The Heck Reaction (Alkene substitution via carbopalladation-dehydropal-ladation). J Wiley Interscience, New York... 

All reactions described in this section are explained by (i) the oxidative addition of a halide to generate the arylpalladium halide 14 (ii) insertion of an alkene to form 15, which is regarded as carbopalladation of alkenes and (iii) formation of the new alkene 16 by elimination of /I-hydrogen (dehydropalladation). The reaction was reported independently by Mizoroki [3] and by Heck [4], and is called the Mizoroki Heck or Heck reaction [5]. 

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. 

A couple of prototypical examples of the cyclic version of the Heck reaction, defined as a process consisting of alkene carbopalladation followed by -elimination, were reported during the 1984-1985 period [9,10]. Almost concurrently, seminal examples of both the non-Heck cyclic carbopallation reactions [10,30] were reported during the 1983-1985 period. Thus, with due respect paid to earlier discoveries of alkyne cyclooligomerization via cascade carbopalladation [7,8] as well as copolymerization [24] and cocyclization [25,... 

Substituent Effects on Hydwpalladation and Carbopalladation. As repeatedly mentioned earlier, Pd(II) species are electrophilic. So, hydropalladation and carbopalladation as well as other addition reactions of Pd(II) complexes are accelerated by electron-donating substituents in Tr-compounds. Any substituents can also exert steric and some other kinds of effects as well. So, the overall substituent effects are the sum of all these factors, of which electronic and steric effects are usually the most dominant ones. The rates of the Heck reaction of various alkenes decrease in the following order CH2=CH2 > CH2=CHOAc > CH2=CHMe > CH2=CHPh > CH2=CMePh. 

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. 

A cascade Heck reaction with termination by nucleophiles is considered to start with an oxidative addition of a heteroatom-carbon bond (starter) onto a palladium(O) species (startup reaction), followed by carbopalladation of a nonaromatic carbon-carbon double or triple bond without subsequent dehydropalladation (relay), a second and possibly further carbopalladation of a carbon-carbon double or triple bond (second etc. relay). The terminating step is a displacement of the palladium residue by an appropriate nucleophile. It is crucial for a successful cascade carbopalladation that no premature dehydropalladation takes place, and that can be prevented by using alkynes and 1,1-disubstituted alkenes (or certain cycloalkenes) as relay stations since they give kinetically stable alkenyl- or neopentylpalladium intermediates, respectively. In addition, reaction of haloalkenes with alkenes in certain cases may form rr-allyl complexes, which are then trapped by various nucleophiles. 

In principle, carbonylative cyclization, that is, acylpalladation or Ac—Pd process, or noncarbonylative cyclization, that is, sample carbopalladation or C—Pd process, in the presence of CO and a Pd catalyst. Various possibilities with halo alkenes as representative substrates are shown in Scheme 2P Those processes that incorporate CO in the cyclization processes are discussed in Part VI including Sects. VI.4-VI.6. hi this section, those cases that do not incorporate CO during the cychzation processes but do so only after cyclization will be discussed. Such cychc carbopalladation-carbonylative termination tandem and cascade processes are represented by the Type II C—Pd process in Scheme 2, which may take place in competition with the other processes shown in Scheme 2, especially the cyclic Heck reaction (Type 1 C—Pd process) and cyclic carbopalladation involving cyclopropa-nation (Type 111 C— Pd process). 

A detailed investigation with 10 summarized in Table 2 indicates that premature esterification and cyclopropanation (Type HI C— Pd process in Scheme 2) can occur as dominant side reactions but that, under the optimized conditions (entry 7), both can be suppressed to insignificant levels (<3%). It is also important to note that, in marked contrast with the cyclic acylpalladation (Type n Ac—Pd) discussed in Sect. VI.4.1.1, monosubstituted alkenes that can readily participate in dehydropalladation (e.g., 11) cannot undergo the cyclic carbopalladation-carbonylative esterification tandem process (Type II C-Pd) since they merely undergo the cyclic Heck reaction (Type I C— Pd process in Scheme 14). The contrasting behavior mentioned above may be attributable to a chelation effect exerted by the carbonyl group in the acylpalladation (Scheme 15), which is lacking in the carbopalladation shown in Scheme 14. 

Alkenes that can provide hydrogen atoms /3 and syn to Pd, such as monosubstituted alkenes, may not be used in the cyclic carbopalladation-carbonylative trapping process, as the reaction is dominated by the cyclic Heck reaction. The difference between this process and the Type II Ac—Pd process (Sect. VI.4.1.1) may be attributable to a chelation effect in the latter preventing otherwise competitive dehydropalladation. 

Carbopalladation is the reaction of a cr-bonded organopalladium complex I with an unsaturated molecule (such as an alkene 2) to yield the migratory insertion product 3 (Scheme 1). The reaction is tremendously flexible, allowing for a wide variety of structural types for both reactants 1 and 2. The precursors of palladium complexes 1 are commonly alkenyl or aryl halides or triflates (8 and 9, respectively), the reaction of which is more commonly termed the Heck reaction. Allylic systems 10, which react to provide -Tr-allylpalladium complexes, can participate in the reaction as can benzylic precursors 11. Acylpalladium complexes 12 also react and are commonly generated in the same reaction vessel by Pd-catalyzed carbonylation. Their unsaturated reaction partners include alkenes 2, alkynes 4, dienes 6, allenes, and arenes, all of which can be electron rich or poor. Carbopalladation occurs in a syn fashion allowing the installation of stereocenters (2- 3) or control of alkene geometry (4- 5). 

Side chain introduction by carbopalladation has been utilized in a total synthesis of an-thramycin methyl ether (32) (Scheme Heck reaction of the alkenyl triflate 30 with acrylamide installs the necessary three-carbon chain in moderate yield. The desired alkene geometry and oxidation state are observed in the dienamide 31 with no need for protection of the primary amide. The organopalladium precursor can also be part of the side chain being introduced as illustrated in a synthesis of prostaglandin E2 33. ... 

An example of the use of an intermolecular carbopalladation in complex molecule synthesis is the preparation of a PAF (platelet activating factor) antagonist (Scheme 11). In the key step, an intermolecular Heck reaction of 2-naphthyl triflate with 2,3-dihydrofuran 71 yields 2-naphthyl-2,3-dihydrofuran 72 in 52% yield with excellent enantioselectivity. The reaction presumably occurs via the cationic manifold and the alkene is isomerized by a hy-dropalladation/dehydropalladation reaction. The minor product 2,5-dihydrofuran 73 is obtained in 26% yield with modest enantioselectivity favoring the opposite absolute configuration at the key center. Critical to the reaction is the use of the sterically demanding and highly basic proton sponge [l,8-bis(dimethylamino)naphthalene] as the base. It is... 

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... 

A mechanism is now proposed for Mizoroki-Heck reactions involving Pd(OAc)2 as precursor associated with PPh3 (Scheme 1.22). From the rate constants of the main steps given in Scheme 1.22, it appears that, for comparable iodobenzene and styrene concentrations, the overall carbopalladation (complexation/insertion of the alkene) from PhPd(OAc)(PPh3)2... 

This is illustrated in the mechanism of the Mizoroki-Heck reaction depicted in Scheme 1.22. Indeed, three main factors contribute to slow down the fast oxidative addition of Phi (i) the anion AcO delivered by the precursor Pd(OAc)2, which stabilizes Pd L2 as the less reactive Pd°L2(OAc) (ii) the base (NEts) which indirectly stabilizes Pd L2(OAc) by preventing its decomposition by protons to the more reactive bent Pd L2 (iii) the alhene by complexation of Pd°L2(OAc) to form the nonreactive ( -CH2=CHR)Pd°L2(OAc). On the other hand, the slow carbopalladation is accelerated by the base and by the acetate ions which generate ArPd(OAc)L2, which in turn is more reactive than the postulated ArPdIL2. The base, the alkene and the acetate ions play, then, the same dual role in Mizoroki-Heck reactions deceleration of the oxidative addition and acceleration of the slow carbopalladation step. Whenever the oxidative addition is fast (e.g. with aryl iodides or activated aryl bromides), this dual effect favours the efficiency of the catalytic reaction by bringing the rate of the oxidative addition closer to the rate of the carbopalladation [Im, 34]. 

Regioselectivity is one of the major problems of Mizoroki-Heck reactions. It is supposed to be affected by the type of mechanism ionic versus neutral, when the palladium is ligated by bidentate P P ligands. The ligand dppp has been taken as a model for the investigation of the regioselectivity. Cabri and Candiani [Ig] have reported that a mixture of branched and linear products is formed in Pd°(P P)-catalysed Mizoroki-Heck reactions performed from electron-rich alkenes and aryl halides (Scheme 1.26a) or aryl ttiflates in the presence of halide ions (Scheme 1.26b). This was rationalized by the so-called neutral mechanism (Scheme 1.27). The neutral complex ArPdX(P P) is formed in the oxidative addition of Pd°(pAp) yj Qj. Q aj.yj triflates in the presence of halides. The carbopalladation... 

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