Heck intermolecular

Brase reported an intramolecular asymmetric Heck-intermolecular Heck cascade reaction of l,3-bis(enolnonaflates) 131 to the highly congested bicyclic compound 132 [122] (Scheme 5). Although the level of asymmetric induction is low (up to 52% ee), this result shows that the concept of two leaving groups in the desymmetrization reaction can be applied. 

Scheme 6 Intramolecular Heck-intermolecular Suzuki sequences [66]...

Z-tamoxifen 403 tandem cyclization 290, 295 tandem Heck reaction-anion capture 253-4 tandem Heck reaction-phenoxide capture 253 tandem Heck reactions 251, 252-4 tandem intramolecular Heck-intermolecular Stille cross-coupling 255 taxol 140, 143,243,245 ( )-tazettine 146,234 telomerization 352 telomerization products 343, 345 template effect 140 teraconic anhydride 468 terminal acetylenes, synthesis of 216-20 terminal alkynes 6, 213 terminal 2,2-diorgano-l-aIkcnylboronates 51 terminal diynes 207 ternary complex 444 ternary coupling 177... 

Scheme 6-28 Tandem intramolecular Heck-intermolecular Stille cross couplings.

Fagnou and co-workers succeeded to combine Heck cyclization with direct arylation in 2009. This interesting domino palladium-catalyzed Heck-intermolecular direct arylation reaction gave new access to a variety of dihydrobenzofurans, indolines, and oxindoles. A variety of sulfur-containing heterocycles such as thiazoles, thiophenes, and benzothiophene could be employed as the direct arylation coupling partner as well and resulted in yields up to 99% (Scheme 2.35). As the authors demonstrated, in addition to... 

Intramolecular reactions with alkenes. While the intermolecular reaction is limited to unhindered alkenes, the intramolecular version permits the participation of even hindered substituted alkenes, and various cyclic compounds are prepared by the intramolecular Heck reaction. Particularly the... 

In 1996, the first examples of intermolecular microwave-assisted Heck reactions were published [85]. Among these, the successful coupling of iodoben-zene with 2,3-dihydrofuran in only 6 min was reported (Scheme 75). Interestingly, thermal heating procedures (125-150 °C) resulted in the formation of complex product mixtures affording less than 20% of the expected 2-phenyl-2,3-dihydrofuran. The authors hypothesize that this difference is the result of well-known advantages of microwave irradiation, e.g., elimination of wall effects and low thermal gradients in the reaction mixture. 

In 2004, Molander et al. developed another type of chiral sulfur-containing ligands for the intermolecular Heck reaction. Thus, their corresponding novel cyclopropane-based phosphorus/sulfur palladium complexes proved to be active as catalysts for the reaction between phenyltriflate and dihydrofuran, providing at high temperature a mixture of the expected product and its iso-merised analogue (Scheme 7.7). The major isomer C was obtained with a maximum enantioseleetivity of 63% ee. 

Shibasaki and coworkers [87] described the first enantioselective combination of this type in their synthesis of halenaquinone (6/1-162) (Scheme 6/1.43). The key step is an intermolecular Suzuki reaction of 6/1-159 and 6/1-160, followed by an enantioselective Heck reaction in the presence of (S)-BINAP to give 6/1-161. The ee-value was good, but the yield was low. 

Lamaty and coworkers described a straightforward combination of three Pd-cata-lyzed transformations first, an intermolecular nucleophilic substitution of an al-lylic bromide to form an aryl ether second, an intramolecular Heck-type transformation in which as the third reaction the intermediate palladium species is intercepted by a phenylboronic acid [124]. Thus, the reaction of a mixture of 2-iodophenol (6/1-253), methyl 2-bromomethylacrylate 6/1-254 and phenylboronic acid in the presence of catalytic amounts of Pd(OAc)2 led to 3,3-disubstituted 2,3-di-hydrobenzofuran 6/1-255 (Scheme 6/1.66). In addition to phenylboronic acid, several substituted boronic acids have also been used in this process. 

A few additional Pd-catalyzed schemes have been employed for Ilac type cyclization chemistry. Palladium-phenanthroline complexes were used by the Ragaini group to prepare indoles via the intermolecular cyclization of nitroarenes and alkynes in the presence of carbon monoxide <06JOC3748>. Jia and Zhu employed Pd-catalysis for the annulation of o-haloanilines with aldehydes <06JOC7826>. A one-pot Ugi/Heck reaction was employed in the preparation of polysubstituted indoles from a four-component reaction system of acrylic aldehydes, bromoanilines, acids, and isocyanides <06TL4683>. 

The Heck reaction, a palladium-catalyzed vinylic substitution, is conducted with olefins and organohalides or pseudohalides are frequently used as reactants [15, 16], One of the strengths of the method is that it enables the direct monofunctionalization of a vinylic carbon, which is difficult to achieve by other means. Numerous elegant transformations based on Heck chemistry have been developed in natural and non-natural product synthesis. Intermolecular reactions with cyclic and acyclic al-kenes, and intramolecular cyclization procedures, have led to the assembly of a variety of complex and sterically congested molecules. 

Palladium-catalyzed arylation of olefins and the analogous alkenylation (Heck reaction) are the useful synthetic methods for carbon-carbon bond formation.60 Although these reactions have been known for over 20 years, it was only in 1989 that the asymmetric Heck reaction was pioneered in independent work by Sato et al.60d and Carpenter et al.61 These scientists demonstrated that intramolecular cyclization of an alkenyl iodide or triflate yielded chiral cyclic compounds with approximately 45% ee. The first example of the intermolecular asymmetric Heck reaction was reported by Ozawa et al.60c Under appropriate conditions, the major product was obtained in over 96% ee for a variety of aryl triflates.62... 

Palladium chemistry involving heterocycles has its unique characteristics stemming from the heterocycles inherently different structural and electronic properties in comparison to the corresponding carbocyclic aryl compounds. One example illustrating the striking difference in reactivity between a heteroarene and a carbocyclic arene is the heteroaryl Heck reaction (vide infra, see Section 1.4). We define a heteroaryl Heck reaction as an intermolecular or an intramolecular Heck reaction occurring onto a heteroaryl recipient. Intermolecular Heck reactions of carbocyclic arenes as the recipients are rare [12a-d], whereas heterocycles including thiophenes, furans, thiazoles, oxazoles, imidazoles, pyrroles and indoles, etc. are excellent substrates. For instance, the heteroaryl Heck reaction of 2-chloro-3,6-diethylpyrazine (1) and benzoxazole occurred at the C(2) position of benzoxazole to elaborate pyrazinylbenzoxazole 2 [12e]. 

While intermolecular Heck reaction of a carbocyclic arene as the recipient is reluctant to occur, intramolecular Heck reaction of carbocyclic arenes has been well-precedented as illustrated by the following two examples [13]. 

One active field of research involving the Heck reaction is asymmetric Heck reactions (AHR). The objective is to achieve enantiomerically-enriched Heck products from racemic substrates using a catalytic amount of chiral ligands, making the process more practical and economical Although intermolecular Heck reactions that occurred onto carbocyclic arenes are rare, they readily take place onto many heterocycles including thiophenes, furans, thiazoles, oxazoles,... 

Normally, the oxidative addition of an aryl chloride to Pd(0) is reluctant to take place. But such a process is greatly accelerated in the presence of sterically hindered, electron-rich phosphine ligands [e.g., P(/-Bu)3 or tricyclohexylphosphine]. In late 1990s, Reetz [76] and Fu [77] successfully conducted intermolecular Heck reactions using arylchlorides as substrates, as exemplified by the conversion of p-chloroanisole to adduct 77 [77], The applications of this discovery will surely be reflected on future Heck reactions of non-activated heteroaryl chlorides. 

As will be seen in this chapter and in the rest of the book, the Heck reaction and its numerous variations represent a fantastically powerful set of tools available to the heterocyclic chemist. Although most Heck chemistry that involves pyrroles is intramolecular or entails synthesis of the pyrrole ring, a few intermolecular Heck reactions of pyrroles are known. Simple pyrroles (pyrrole, A-methylpyrrole, A-(phenylsulfonyl)pyrrole) react with 2-chloro-3,6-dialkylpyrazines under Heck conditions to give mixtures of C-2 and C-3 pyrrole-substituted pyrazines in low... 

The intermolecular Heck reaction of halopyridines provides an alternative route to functionalized pyridines, circumventing the functional group compatibility problems encountered in other methods. 3-Bromopyridine has often been used as a substrate for the Heck reaction [124-126]. For example, ketone 155 was obtained from the Heck reaction of 3-bromo-2-methoxy-5-chloropyridine (153) with allylic alcohol 154 [125]. The mechanism for such a synthetically useful coupling warrants additional comments oxidative addition of 3-bromopyridine 153 to Pd(0) proceeds as usual to give the palladium intermediate 156. Subsequent insertion of allylic alcohol 154 to 156 gives intermediate 157. Reductive elimination of 157 gives enol 158, which then isomerizes to afford ketone 155 as the ultimate product This tactic is frequently used in the synthesis of ketones from allylic alcohols. 

In one case, the intermolecular Heck reaction of 3-pyridyltriflate with ethyl acrylate was accelerated by LiCl to give 159 [127,128], Here, both electronic and steric effects all favored p-substitution. In another case, however, electronic effects prevailed and complete a-substitution was observed. In the presence of an electron-donating substituent (i.e., a protected amine), 3-bromopyridine 160 was coupled with f-butoxyethylene to give 3-pyridyl methyl ketone 162 [126]. The regiochemistry of the Heck reaction was governed by inductive effects, leading to intermediate 161. 

A reductive intermolecular Heck heteroarylation (hydroheteroarylation) of A-protected azabicyclo[2,2,l]heptene 165 has been used to construct 7-azabicyclo[2.2.1]heptane 166 in moderate yield [131, 132]. An asymmetric version of such a transformation to provide enantiomerically-enriched iV-protected epibatidine has also been described [128, 133]. It was found that introduction of Noyori s BINAP ligand resulted in the best enantioselectivities with 72-81% ee and a 53% yield. By using either the (R)- or (S)-BINAP ligand, either enantiomer was easily accessible. 

Heck, intramolecular Heck and heteroaryl Heck reactions 6.5.1 Intermolecular Heck reaction... 

The intermolecular Heck reaction of 3-bromofuran and tosylallyamine 88 gave adduct 89 under the classical Heck conditions [79], Subsequent Rh-catalyzed hydroformylation with ring closure occurred regioselectively to furnish the hydroxypyrrolidine, which was dehydrated using catalytic HC1 to afford dihydropyrrole 90. 

Generally, the intermolecular Heck reaction between 2-iodo-, 4-iodo- and 5-iodo-l-methylimidazoles and olefins suffers from low yields (< 25%). Therefore, these transformations are of limited synthetic utility [29]. In one case, variable yields for adduct 62 (15-58%) were observed for the Heck reaction of 5-bromo-l-methyl-2-phenylthio-lf/-imidazole (61) and a large excess of methyl acrylate [42]. 

An intramolecular heteroaryl Heck was the pivotal step in the synthesis of 5-butyl-1-methyl-l//-imidazo[4,5-c]quinolin-4(5//)-one (63), a potent antiasthmatic agent [46], The optimum yield was obtained under Jeffery s ligand-free conditions, echoing Ohta s observation for the intermolecular version. Once again, the Caryi—Caryi bond was constructed at the C(5) position of the imidazole ring. Another intramolecular heteroaryl Heck cyclization of pyrrole and imidazole derivatives was also reported to assemble annulated isoindoles [47]. 

Palladium chemistry of heterocycles has its idiosyncrasies stemming from their different structural properties from the corresponding carbocyclic aryl compounds. Even activated chloroheterocycles are sufficiently reactive to undergo Pd-catalyzed reactions. As a consequence of a and y activation of heteroaryl halides, Pd-catalyzed chemistry may take place regioselectively at the activated positions, a phenomenon rarely seen in carbocyclic aryl halides. In addition, another salient peculiarity in palladium chemistry of heterocycles is the so-called heteroaryl Heck reaction . For instance, while intermolecular palladium-catalyzed arylations of carbocyclic arenes are rare, palladium-catalyzed arylations of azoles and many other heterocycles readily take place. Therefore, the principal aim of this book is to highlight important palladium-mediated reactions of heterocycles with emphasis on the unique characteristics of individual heterocycles. 

Intermolecular, enantioselective Heck reactions require a cyclic olefin as substrate, since syn carbopal-ladation of a cyclic olefin results in a geometrically defined a-alkyl-palladium compound. By necessity, the subsequent syn dehydropalladation must take place away from the newly formed chiral centre, thereby affording a chiral product. 

The use of cyclic alkenes as substrates or the preparation of cyclic structures in the Heck reaction allows an asymmetric variation of the Heck reaction. An example of an intermolecular process is the addition of arenes to 1,2-dihydro furan using BINAP as the ligand, reported by Hayashi [23], Since the addition of palladium-aryl occurs in a syn fashion to a cyclic compound, the 13-hydride elimination cannot take place at the carbon that carries the phenyl group just added (carbon 1), and therefore it takes place at the carbon atom at the other side of palladium (carbon 3). The normal Heck products would not be chiral because an alkene is formed at the position where the aryl group is added. A side-reaction that occurs is the isomerisation of the alkene. Figure 13.20 illustrates this, omitting catalyst details and isomerisation products. 

Intermolecular or intramolecular Heck reaction that occurs onto a heteroaryl recipient. 

Palladium(0)-catalyzed cross-coupling of aryl halides and alkenes (i.e., the Heck reaction) is widely used in organic chemistry. Oxidative Heck reactions can be achieved by forming the Pd -aryl intermediate via direct palladation of an arene C - H bond. Intramolecular reactions of this type were described in Sect. 4.1.2, but considerable effort has also been directed toward the development of intermolecular reactions. Early examples by Fu-jiwara and others used organic peroxides and related oxidants to promote catalytic turnover [182-184]. This section will highlight several recent examples that use BQ or dioxygen as the stoichiometric oxidant. 

In Rao s total synthesis of niphatesines, a key intermediate 91 was elaborated from an intermolecular Heck reaction of 3-bromopyridine with non-8-en-ol <93TL8329>. In another case, Bracher et al. synthesized a natur ly occurring P-carboline, infractine (93), from p-carboline-l-triflate (92) in a two step process consisting of a Heck reaction with methyl acrylate followed by a hydrogenation <95PHA182>. Their approach provided an expeditious route to infractine, although the Heck reaction was low yielding. 

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