Domino reactions Heck-type reaction

A similar approach was used by the Alcaide group [183] in the synthesis of tricyclic (3-lactams 6/1-391 from 6/1-390 (Scheme 6/1.99). In this domino process the primarily obtained it-allyl-Pd-complex reacts with the N-nucleophile of the urethane moiety to form a C-N-bond and a vinyl halide. The final step is then an intramolecular Heck-type reaction of the vinyl halide with the alkyne moiety and re-... 

Domino-Heck Type Reactions of N-Benzoyl-2-Azabicyclo [2.2.1 ] Hept-5-ene-3-one... 

Keywords Alkynyl lactams, Heck reaction, Domino-Heck type reaction, rearrangement... 

Scheme 25 Formation of three new rings from 2-bromoalka-1, m-dien-n-ynes in a domino sequence of two intramolecular Heck-type reactions and 67r-electrocyclization...

The formation of compound 175 could be rationalized in terms of an unprecedented domino allene amidation/intramolecular Heck-type reaction. Compound 176 must be the nonisolable intermediate. A likely mechanism for 176 should involve a (ji-allyl)palladium intermediate. The allene-palladium complex 177 is formed initially and suffers a nucleophilic attack by the bromide to produce a cr-allylpalladium intermediate, which rapidly equilibrates to the corresponding (ji-allyl)palladium intermediate 178. Then, an intramolecular amidation reaction on the (ji-allyl)palladium complex must account for intermediate 176 formation. Compound 176 evolves to tricycle 175 via a Heck-type-coupling reaction. The alkenylpalladium intermediate 179, generated in the 7-exo-dig cyclization of bro-moenyne 176, was trapped by the bromide anion to yield the fused tricycle 175 (Scheme 62). Thus, the same catalytic system is able to promote two different, but sequential catalytic cycles. 

The Ni-catalysed Heck reaction is rather rare. Although the attempted Ni(0)-catalysed cyclization of iodide 107 gave a mixture of many products, the pentacyclic nitrone 108 was isolated in 40% yield by the domino Heck-type reaction, reductive... 

A broad variety of special aldehydes and ketones are easily accessible by Heck-type reactions with allylic alcohols and their homologs [3]. The potential for the synthesis of carbocydic structures is illustrated by the macrocyde 11 [4] which obviously is the product of a fourfold Heck reaction (Scheme 3). A domino process consisting of a double Heck reaction followed by an intramolecular Aldol condensation leads to the annulated ring system 15 [5]. 

In the synthesis of the steroid (+)-equilenin (302) Nemoto et al. [153] also used a palladium(II)-catalysed domino process which includes a ring expansion followed by a Mizoroki-Heck-type reaction (Scheme 8.74). Interestingly, almost complete reversion of... 

Divinylbenzene and related compounds undergo an internal domino acetoxy-palladation (Wacker-type, 1) and subsequent carbMalladation reaction (Heck-type, 3) to form indenes (Experimental Procedure below). " ... 

Grigg and coworkers developed bimetallic domino reactions such as the electro-chemically driven Pd/Cr Nozaki-Hiyama-Kishi reaction [69], the Pd/In Barbier-type allylation [70], Heck/Tsuji-Trost reaction/1,3 dipolar cycloaddition [71], the Heck reaction/metathesis [72], and several other processes [73-75]. A first example for an anion capture approach, which was performed on solid phase, is the reaction of 6/1-134 and 6/1-135 in the presence of CO and piperidine to give 6/1-136. Liberation from solid phase was achieved with HF, leading to 6/1-137 (Scheme 6/1.30) [76]. 

Toyota, Ihara and coworkers [178] used a combination of a Wacker- and a Heck-type transformation to construct the cedrane skeleton. Thus, reaction of 6/1-374 using 10mol% Pd(OAc)2 under an atmosphere of 02 led to the domino product 6/1-375 in 30% yield. In addition, 58% of the mono-cyclized compound 6/1-376 was obtained (Scheme 6/1.94). 

Domino Heck-Diels-Alder type reaction has been demonstrated by the reaction of l,3-dicydopropyl-l,2-propadiene with iodobenzene in the presence of dimethyl maleate under palladium catalysis (Scheme 16.28) [33]. 

As an extension of the Heck reaction, Pd-catalyzed hydroarylation of alkynes and alkenes continnes to attract high level of research interest in simple couphng processes and in cyclization reactions. The use of this type of transformation as part of a domino reaction will be of increasing interest. The research in the field of domino reactions is attracting considerable attention in synthetic organic chemistry since it enables the rapid assembly of complex molecirles in one-pot processes. Very elegant examples of palladium-catalyzed cascade processes where a single catalytic cycle entails several sequential bond transformations have been recently reported [la, b, 2a, b, c]. 

Another potentially powerfnl sequence arises by combining one or two intramolecular Heck-type couplings with an intra- or intermolecular Diels-Alder addition (for early examples of inter-intermolecular one-pot domino Heck-Diels-Alder reactions see Refs. [49] and [50]). An all-intramolecular version of such a sequence has been shown to proceed reasonably smoothly for terminally alkoxycarbonyl-substituted 2-bromotrideca-l,ll-dien-6-ynes under palladium catalysis at 130 °C. At 80 °C, the sequential reaction stops after the two consecutive Heck-type cyclizations and subsequent /3-hydride elimination to give a 1,3,6-triene apparently only the ( )-isomer undergoes the intramolecular Diels-Alder reaction, as the (Z)-l,3,6-triene is observed accompanying the tetracyclic system obtained at 130 °C (Scheme 36). 

Various types of domino reactions have been reported in the recent past. The sequential or cascade combination of an olefin metathesis with an intramolecular Heck reaction provides access to various bicycUc spirocyclic ring systems in good yields. Recently, a one-pot metathesis-Heck cascade was employed in the constraction of various ring systems (Scheme 57). " ... 

In this section, only examples of Mizoroki-Heck reactions where a proper addition of the cr -aryl- or a -alkeny Ipalladium(II) complex to a double bond of an alkene or alkyne occurs are considered. As a consequence, an often-met deviation from the classic Mizoroki-Heck mechanism, the so-called cyclopalladation, will not be treated in further detail [12, 18]. However, as it is of some importance, especially in heterocycle formation and mainly because it will be encountered later during polycyclization cases, it shall be mentioned briefly below. Palladacycles are assumed to be intermediates in intramolecular Mizoroki-Heck reactions when j3-elimination of the formed intermediate cannot occur. These are frequently postulated as intermediates during intramolecular aryl-aryl Mizoroki-Heck reactions under dehydrohalogenation (Scheme 6.1). The reactivity of these palladacycles is strongly correlated to their size. Six-membered and larger palladacycles quickly undergo reductive elimination, whereas the five-membered species can, for example, lead to Mizoroki-Heck-type domino or cascade processes [18,19]. 

In most of the palladium-catalysed domino processes known so far, the Mizoroki-Heck reaction - the palladium(0)-catalysed reaction of aryl halides or triflates as well as of alkenyl halides or triflates with alkenes or alkynes - has been apphed as the starting transformation accordingly to our classification (Table 8.1). It has been combined with another Mizoroki-Heck reaction [6] or a cross-coupling reaction [7], such as Suzuki, Stille or Sonogashira reactions. In other examples, a Tsuji-Trost reaction [8], a carbonylation, a pericyclic or an aldol reaction has been employed as the second step. On the other hand, cross-couphng reactions have also been used as the first step followed by, for example, a Mizoroki-Heck reaction or Tsuji-Trost reactions, palladation of alkynes or allenes [9], carbonylations [10], aminations [11] or palladium(II)-catalysedWacker-type reactions [12] were employed as the first step. A novel illustrative example of the latter procedure is the efficient enantioselective synthesis of vitamin E [13]. 

Based on a transformation described by Catellani and coworkers [80], Lautens s group [81] developed a series of syntheses of carbocycles and heterocycles from aryl iodide, alkyl halides and Mizoroki-Heck acceptors. In an early example, the authors described a three-component domino reaction catalysed by palladium for the synthesis of benzo-annulated oxacycles 144 (Scheme 8.37). To do so, they used an m-iodoaryl iodoalkyl ether 143, an alkene substimted with an electron-withdrawing group, such as t-butyl acrylate and an iodoalkane such as -BuI in the presence of norbomene. It is proposed that, after the oxidative addition of the aryliodide, a Mizoroki-Heck-type reaction with nor-bornene and a C—H activation first takes place to form a palladacycle PdCl, which is then alkylated with the iodoalkane (Scheme 8.37). A second C—H activation occurs and then, via the formation of the oxacycle OCl, norbomene is eliminated. Finally, the aryl-palladium species obtained reacts with the acrylate. The alkylation step of palladacycles of the type PdCl and PdCl was studied in more detail by Echavarren and coworkers [82] using computational methods. They concluded that, after a C—H activation, the formation of a C(sp )—C(sp ) bond between the palladacycle PdCl and an iodoalkane presumably proceeds by oxidative addition to form a palladium(IV) species to give PdC2. This stays, in contrast with the reaction between a C(sp )—X electrophile (vinyl or aromatic halide) and PdCl, to form a new C(sp )—C(sp ) bond which takes place through a transmetallation. 

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