Cycloisomerization proposed mechanism

The [4+ 4]-homolog of the [4 + 2]-Alder-ene reaction (Equation (48)) is thermally forbidden. However, in the presence of iron(m) 2,4-pentanedioate (Fe(acac)3) and 2,2 -bipyridine (bipy) ligand, Takacs57 found that triene 77 cyclizes to form cyclopentane 78 (Equation (49)), constituting an unprecedented formal [4 + 4]-ene cycloisomerization. The proposed mechanism for this transformation involves oxidative cyclization followed by /3-hydride elimination and reductive elimination to yield the cyclized product (Scheme 18). 

The proposed mechanism of the above cycloisomerizations are depicted in Scheme 11.30. The oxidative coupling of a metal to an enyne yields a bicyclic metaUacyclopentene, which is a common intermediate. The reductive elimination and subsequent retro-[2+2] cycloaddition gave vinylcyclopentene derivatives, while the two patterns of P-elimination and subsequent reductive eUmination gave cychc 1,3- and 1,4-dienes, respectively. The existence of a carbene complex intermediate might explain the isomerization of the olefinic moiety. 

Scheme 9.5 Proposed mechanism of Rh (I)-catalyzed N-propargyl enamine cycloisomerization.

Mild Ni(0)-catalysed rearrangements of l-acyl-2-vinylcyclopropanes to substituted dihydrofurans have been developed.86 The room temperature isomerizations afford dihydrofuran products in high yield. A highly substituted, stereochemically defined cyclopropane has been employed in the rearrangement to evaluate the reaction mechanism. The Cu(II)-catalysed cycloisomerization of tertiary 5-en-l-yn-3-ols with a 1,2-alkyl shift affords stereoselectively tri- and tetra-cyclic compounds of high molecular complexity (Scheme 29).87 A proposed mechanism has been outlined in which... 

Iridium-catalyzed intramolecular l,n-enyne metathesis has been studied as a unique tool for the synthesis of various types of cyclic compounds. Reactions of this type depend on both the structure of substrates and the nature of catalyst systems used (411). Recently, the cycloisomerization of various 1,6-enynes have been shown to be catalyzed by [Ir(cod)Cl]2/dppf (494). These reactions are highly stereoselective, and generate the (Z)-isomer preferentially over the ( )-isomer (Scheme 63). The proposed mechanism (Scheme 64) involves oxidative cyclization of the enyne at Ir(I) to give the trivalent iridacyclopentene. The intermediate undergoes (3-hydride elimination to give the irida-1,3-diene, which experiences steric repulsion between the metal fragment and the cis substituent on the... 

An extension of Hashmi s Au(III)-catalyzed phenol synthesis [81] to furan substrates 9 bearing an additional alkyne moiety allowed the preparation of C6-C7-heterofused benzofuran 11 (Scheme 9.3) [82]. According to the proposed mechanism, the Au(III)-catalyzed arene formation reaction generates o-alkynylphenol 10. A subsequent Au(III)-catalyzed cycloisomerization of the latter, following the general mechanism for an intramolecular nucleophilic addition of heteroatom to transition metal-activated carbon-carbon multiple bonds, gives 11 (Scheme 9.3). 

Recently, Yamamoto extended the cycloisomerization-1,3-migration approach toward the construction of indole cores possessing a C3-sulfonyl group. Thus, cydoisomerization of ortho-alkynylsulfonamides 146 occurred in the presence of Au(III)-catalyst to produce 3-sulfonylindoles 147 via a 1,3-migration of a sulfanyl group (Scheme 9.55) [216]. The proposed mechanism is similar to that reported for... 

SCHEME 3.46 Proposed mechanism for the gold(IIt)-catalyzed A -coupling/cycloisomerization reaction. 

Scheme 15 Proposed mechanism for cycloisomerization of aromatic homo- and bis-homopropargylic alcohols mediated by amines...

The reactions of propargylic aziridines with a platinum catalyst in aqueous media led the cycloisomerization of aziridines 39 forming pyrroles 40 (Scheme 13) [45]. According to the proposed mechanism, the platinum coordinates with carbon-carbon triple bond that is followed by attack of the aziridine nitrogen on the alk5me forming a pyrrolyl-platinum species, which undergoes aromatization to form the final pyrrole products. 

Proposed Mechanisms Different mechanistic pathways have been proposed for the metal-catalyzed cycloisomerization reactions. In the case of enynes, these are highlighted as (i) the metaUocyclopentene pathway, (ii) the tf-metal pathway, and (iii) the vinylmetal pathway (Scheme 7.10) [30]. 

SCHEME 7.25 (a) Zwitterions between metals and alkynes or alkenes and (b) proposed mechanism for the cycloisomerization of enynes... 

This system was described in one report and has been synthesized by a copper-assisted cycloisomerization of alkynyl imines. The authors proposed the following mechanism at first, 372 could undergo a base-induced propargyl-allenyl isomerization to form 373 next, coordination of copper to the terminal double bond of the allene (intermediate 374) would make it subjected to intramolecular nucleophilic attack to produce a zwitterion 375. The latter would isomerize into the more stable zwitterionic intermediate 376, which would be transformed to the thiazole 377 (Scheme 55) <2001JA2074>. 

Cycloisomerization of 1,6-diene 25 is effected by a number of transition metal catalysts. For example, both rhodium trichloride [22, 23] and Wilkinson s catalyst [24, 25] promote this reaction efficiently to give methylenecyclopentane 26 (Scheme 7.12). In the latter case, the active catalyst species is beheved to be [Rh(PPh3)2HCl2]. A mechanism proposed for this cycloisomerization is shown in Scheme 7.13. Coordination of a diene to [Rh(PPh3)2HCl2] and insertion of one of the olefin moieties of the diene into the [Rh]-H bond gives complex II.3a. Carbocychzation affords alkyl-[Rh] intermediate II.3i,. Subsequent reductive ehmination of the methylenecyclopentane regenerates the active catalyst species. 

Another rhodium vinylidene-mediated reaction for the preparation of substituted naphthalenes was discovered by Dankwardt in the course of studies on 6-endo-dig cyclizations ofenynes [6]. The majority ofhis substrates (not shown), including those bearing internal alkynes, reacted via a typical cationic cycloisomerization mechanism in the presence of alkynophilic metal complexes. In the case of silylalkynes, however, the use of [Rh(CO)2Cl]2 as a catalyst unexpectedly led to the formation of predominantly 4-silyl-l-silyloxy naphthalenes (12, Scheme 9.3). Clearly, a distinct mechanism is operative. The author s proposed catalytic cycle involves the formation of Rh(I) vinylidene intermediate 14 via 1,2-silyl-migration. A nucleophilic addition reaction is thought to occur between the enol-ether and the electrophilic vinylidene a-position of 14. Subsequent H-migration would be expected to provide the observed product. Formally a 67t-electrocyclization process, this type of reaction is promoted by W(0)-and Ru(II)-catalysts (Chapters 5 and 6). 

Double cyclization of iodoenynes is proposed to occur through a Rh(I)-acetylide intermediate 106, which is in equilibrium with vinylidene lOS (Scheme 9.18). Organic base deprotonates the metal center in the course of nucleophilic displacement and removes HI from the reaction medium. Once alkenylidene complex 107 is generated, it undergoes [2 + 2]-cycloaddition and subsequent breakdown to release cycloisomerized product 110 in the same fashion as that discussed previously (Scheme 9.4). Deuterium labeling studies support this mechanism. 

A ruthenium based catalytic system was developed by Trost and coworkers and used for the intermolecular Alder-ene reaction of unactivated alkynes and alkenes [30]. In initial attempts to develop an intramolecular version it was found that CpRu(COD)Cl catalyzed 1,6-enyne cycloisomerizations only if the olefins were monosubstituted. They recently discovered that if the cationic ruthenium catalyst CpRu(CH3CN)3+PF6 is used the reaction can tolerate 1,2-di- or tri-substituted alkenes and enables the cycloisomerization of 1,6- and 1,7-enynes [31]. The formation of metallacyclopentene and a /3-hydride elimination mechanism was proposed and the cycloisomerization product was formed in favor of the 1,4-diene. A... 

Considering the mechanistic rationales of the transition metal-catalyzed enyne cycloisomerization, different catalytic pathways have been proposed, depending on the reaction conditions and the choice of metal catalyst [3-5, 45], Complexation of the transition metal to alkene or alkyne moieties can activate one or both of them. Depending on the manner of formation of the intermediates, three major mechanisms have been proposed. The simultaneous coordination of both unsaturated bonds to the transition metal led to the formation of metallacydes, which is the most common pathway in transition metal-catalyzed cycloisomerization reactions. Hydrometalation of the alkyne led to the corresponding vinylmetal species, which reacts in turn with olefins via carbometalation. The last possible pathway involves the formation of a Jt-allyl complex which could further react with the alkyne moiety. The Jt-allyl complex could be formed either with a functional group at the allylic position or via direct C-H activation. Here the three major pathways will be discussed in a generalized form to illustrate the mechanisms (Scheme 8). 

The mechanism of these transformations seems to be substrate-dependent and only the cycloisomerization of aryl and primary iodides was thought to proceed as shown in Scheme 31. The stereoselectivity of the isomerization of 110 to 111 is better accommodated with the intermediacy of l-methyl-5-hexenyl radical59. Later, it was proposed that the isomerization of 6 to 109 also proceeds via a radical-mediated atom transfer process initiated by homolytic fragmentation of an ate-complex intermediate 112 (Scheme 32)60. 

A number of cycloisomerization reactions of enynes to construct five-membered car-bocycles with a variety of transition metal catalysts have been reported thus far [24]. The mechanisms that have been proposed for the cycloisomerization of enynes include 1) hydrometallation of alkyne followed by carbometallation of the olefin ... 

A mechanism which involved the allylic carbon-hydrogen bond activation of the alkene moiety was proposed for the cycloisomerization of 1,6-diyne to alkylidenecy-cloheptene on the basis of stereochemical consideration and deuterium labeling experiment (Scheme 12.7). 

The alcoholic solvent was essential for this catalytic cycloisomerization [27]. On the basis of studies using the known ruthenium hydrides and deuterium-labeling substrates, a mechanism involving an intermediary ruthenacyclopentane was proposed (Eq. 12.25). 

Shortly after the discovery of enyne metathesis, Trost began developing cycloisomerization reactions of enynes using Pd(ll) and Pt(ll) metallacyclic catalysts (429-433), which are mechanistically divergent from the metal-carbene reactions. The first of these metal catalyzed cycloisomerization reactions of 1,6-enynes appeared in 1985 (434). The reaction mechanism is proposed to involve initial enyne n complexation of the metal catalyst, which in this case is a cyclometalated Pd(II) cyclopentadiene, followed by oxidative cyclometala-tion of the enyne to form a tetradentate, putative Pd(IV) intermediate [Scheme 42(a)]. Subsequent reductive elimination of the cyclometalated catalyst releases a cyclobutene that rings opens to the 1,3-diene product. Although this scheme represents the fundamental mechanism for enyne metathesis and is useful in the synthesis of complex 1,3-cyclic dienes [Scheme 42(fe)], variations in the reaction pathway due to selective n complexation or alternative cyclobutene reactivity (e.g., isomerization, p-hydride elimination, path 2, Scheme 40) leads to variability in the reaction products. Strong evidence for intermediacy of cyclobutene species derives from the stereospecificity of the reaction. Alkene... 

Electrophilic Au(I) complexes or their halide AuX analogoues typically cyclize enynes (I, Scheme 58) (475) by a 5-exo-dig pathway to give a variety of cycloisomerization and addition derivatives. The mechanism is proposed to involve formation of a cyclopropyl gold-carbene intermediate... 

Propose a mechanism for the following copper-catalyzed furan synthesis involving a tandem propargylation/cycloisomerization step. ... 

RajanBabu has developed an asymmetric protocol for the heterodimerization of vinyl-arenes and ethenej The use of Hayashi s novel, weakly chelating phosphine 91 is critical to the success of this asymmetric reaction (Scheme 68). 1,6-Dienes (e.g., 92) also undergo direct cycloisomerization in the presence of bis[allyl(bromo)nickel] to afford meth-ylenecyclopentane products (e.g., 93 Scheme 69). The scope of the intramolecular process allows preparation of a variety of carbocyclic and heterocyclic ring systems. A reaction mechanism involving in situ generation of a nickel hydride catalyst, alkene hydro-metalation, cyclization, and p-hydride elimination has been proposed. ... 

A mechanism proposed for this cycloisomerization is shown in (Scheme 26). Coordination of the diene to [Rh(PPhs)2HCl2] and insertion of one of the olefin moieties of the diene into the [Rh]-H bond gives complex G-V. Carbocyclization... 

Schmalz and coworkers recently reported an interesting and highly efficient Au(I)-catalyzed cascade cycloisomerization of geminal acyl-alkynylcydopropanes 102 into the densely functionalized furans 103(Scheme 8.41) [160]. This reaction proceeded under very mild reaction conditions and a variety of nucleophiles, such as alcohols, including tert-butanol, phenols, acetic acid, 2-pyrrolidone, and indole could be employed. In addition, this transformation was shown to be catalyzed by Cu(II)-and Ag-trifiates, albeit with somewhat lower efficiency. Two mechanisms, including concerted and stepwise formation of a furan ring, were proposed by the authors for this cascade transformation (Scheme 8.42). 

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