Cycloisomerization reaction

In 2009, Marinetti and co-workers reported the preparation and structural data of NHC-Pt complexes and their catalytic activity in model 1,6-enyne cycloisomerization reactions. The elaboration of square-planar Pt complexes 

In this context, the synthesis of a new family of Pt six-membered metal-acyclic NHC complexes was reported.This new platinacyclic complex was then used in an enantioselective 1,6-enyne cycloisomerization to afford, under mild conditions, the expected fused azabicycles in very high enantiomeric excesses and good to excellent yields (Equation (10.34)). 

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Complex 38 also turned out to be an efficient catalyst for cycloisomerization reactions of enynes 41 (Scheme 8) [16, 17]. This seems reasonable if one considers the fact that Fe(0) is isoelectronic to Rh(+1), which is also a catalyst for Alder-ene cycloisomerizations [18, 19]. 

Scheme 8 Catalytic role of iron in cycloisomerization reactions [17]...

Similar to this cycloaddition, ferrate 40 also proved to be catalytically active in [5 + 2]-cycloadditions, as discussed for ferrate 38 (eq. 2 in Scheme 11). As for the cycloisomerization reactions, ferrate 40 also turned out to be reactive toward... 

Silane reduces the palladium acetate in 119 to the palladium hydride 120, which undergoes reductive elimination to provide the organic product and the catalytic Pd(II) species. This mechanistic hypothesis was supported by the use of EtsSiD as the reductant product was formed with D incorporation at only the methyl group [70]. This reaction is best performed with a Pd(0) precatalyst in the presence of acetic acid and 10 eq. of silane, which suppresses the competitive cycloisomerization reaction [70]. 

An intramolecular palladium-catalyzed cycloisomerization of enyne 170 was used to access the antifungal agent, chokol C (Scheme 43).102 The choice of ligand and catalyst was essential to the efficiency of the Alder-ene reaction. Enone 171 was obtained as a single olefinic isomer resulting from migration of only Ha during the cycloisomerization reaction. 

Kibayashi and co-workers103 implemented the palladium-catalyzed cycloisomerization reaction in a stereoselective total synthesis of enantiomerically pure (+)-streptazolin. The cycloisomerization of enyne 172 to provide diene 173 was remarkably selective when performed in the presence of A,Ar -bis(benzylidene)ethylenediamine (BBEDA) as a ligand and water as a proton source (Scheme 44). 

The Diels-Alder reaction outlined above is a typical example of the utilization of axially chiral allenes, accessible through 1,6-addition or other methods, to generate selectively new stereogenic centers. This transfer of chirality is also possible via in-termolecular Diels-Alder reactions of vinylallenes [57], aldol reactions of allenyl eno-lates [19f] and Ireland-Claisen rearrangements of silyl allenylketene acetals [58]. Furthermore, it has been utilized recently in the diastereoselective oxidation of titanium allenyl enolates (formed by deprotonation of /3-allenecarboxylates of type 65 and transmetalation with titanocene dichloride) with dimethyl dioxirane (DMDO) [25, 59] and in subsequent acid- or gold-catalyzed cycloisomerization reactions of a-hydroxyallenes into 2,5-dihydrofurans (cf. Chapter 15) [25, 59, 60],... 

In the cycloisomerization reaction of 271, high diastereoselectivity was also observed, depending on the nature of the R group connected to the nitrogen atom [138],... 

Vinylallene 198 itself undergoes a variety of dimerization and cycloisomerization reactions on heating at 170 °C in the gas phase [162],... 

In other Pd(II)-catalyzed reactions, combining a cyclization with a coupling reaction, the furans which stem from a simple cycloisomerization reaction without coupling are often observed as side-products, occasionally in significant yield. Several examples have been reported by Ma and co-workers [74, 75],... 

The first example involving a rhodium catalyst in an ene reaction was reported by Schmitz in 1976. An intramolecular cyclization of a diene occurred to give a pyrrole when exposed to rhodium trichloride in isobutanol (Eq. 2) [15]. Subsequently to this work, Grigg utilized Wilkinson s catalyst to effect a similar cycloisomerization reaction (Eq. 3) [16]. Opplozer and Eurstner showed that a n -allyl-rhodium species could be formed from an allyl carbonate or acetate and intercepted intramolecularly by an alkene to afford 1,4-dienes (Eq. 4). Hydridotetrakis(triphenylphosphine)rhodium(l) proved to be the most efficient catalyst for this particular transformation. A direct comparison was made between this catalyst and palladium bis(dibenzylidene) acetone, in which it was determined that rhodium might offer an additional stereochemical perspective. In the latter case, this type of reaction is typically referred to as a metallo-ene reaction [17]. 

Brummond [28] was the first to illustrate that cross-conjugated trienes could be obtained via an allenic Alder-ene reaction catalyzed by [Rh(CO)2Cl]2 (Eq. 14). Selective formation of the cross-conjugated triene was enabled by a selective cycloisomerization reaction occurring with the distal double bond of the aUene. Typically directing groups on the allene, differential substitution of the aUene termini, or intramolecularization are required for constitutional group selectivity. However, rhodium(f), unlike other transition metals examined, facihtated selective cyclization with the distal double bond of the allene in nearly aU the cases examined. 

If photochemical apparatus is not available, the cycloisomerization reaction can be conducted using trimethylamine N-oxide to promote oxidative decarbonylation of molybdenum hexacarbonyl in a mixture of EtjN and EtgO, followed by addition of 1-phenyl-3-butyn-1-ol (1). In the submitters hands, this procedure required somewhat higher loading of molybdenum hexacarbonyl, and purification of the 2-phenyl-2,3-dihydrofuran (2) product required silica gel chromatography. 

Uemura and coworkers discovered another unique rhodium vinylidene-mediated cycloisomerization reaction [11]. They found that in the presence of an electron-rich Rh(I)-complex, [ RhCl(iPr3P)2]2, (Z)-hexa-3-en-l,5-diynes bearing an alkyl substituent at one terminus undergo cycloisomerization to give allylbenzenes (Equation 9.3). 

Intramolecular examples of iron-catalyzed formal Alder-ene reactions, which are also denoted cycloisomerization reactions, were described in the late 1980s by the groups of Tietze and Takacs in reactions directed towards cyclopentane [6, 7], cyclohexane [8], piperidine [9] and tetrahydropyran derivatives [10]. 

Scheme 6. Asymmetric Rh-catalyzed cycloisomerization reaction via a new procedure.

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). 

Jt-allyl complex can be generated after cyclization, as suggested by Takacs in a Fe(0)-catalyzed cyclization of polyenes. It also can be preformed if an active functional group is present in the allylic position. The palladium-catalyzed intramolecular cycloisomerization reaction of allylic acetates is an efficient method for constructing five- or six-membered rings [56, 57]. An asymmetric approach to this transformation has been studied and so far only poor enantioselectivity has been achieved (0-20% ee) [58]. Very recently, Zhang et al. also reported a Rh-catalyzed cycloisomerization involving a Jt-allylrhodium intermediate formed from an allylic halide [59]. 

Rh-catalyzed Asymmetric Cycloisomerization Reaction Synthesis of (3-Oxo-2-pentylidenecyclopentyl)acetaldehyde... 

In the first asymmetric cycloisomerization reaction, the cyclopentenol derivative 82 was prepared from 80 in the presence of (—)-CAMP 81 (Scheme 5.16) [83]. The low asymmetric control (14% ee) was attributed to the reversibility of the cyc-lization. It should be noted that this reaction is not suitable for the preparation of six-membered rings. 

Our interest in this chapter is in silver-catalyzed cycloisomerization reactions. Therefore, we shall present different silver-catalyzed cycloisomerization reactions as a function of the nucleophilic and electrophilic moiety. Cycloisomerization reactions including the classical ene-yne cycloisomerization (with X = CHR, Scheme 5.1), and the related heterocyclization reactions with heteroatoms embedded in unsaturated systems (X = NR, O Scheme 5.1) belong to the same reaction family. In addition, the alkynyl part can be exchanged for an allene unit. Internal or external nucleophiles (Nu) can then stabilize, through cascade reactions, the positive charge created.24... 

Heterocyclization reactions with saturated moieties (alcohols, amines, thiols, etc.) or acids on unsaturated counterparts (alkenes, allenes, alkynes, etc.) are not covered in this chapter since they are addition, and not isomerization, reactions. Silver is also widely used as an activating agent for producing highly reactive metallic cations (anion metathesis), which, in turn, may catalyze cycloisomerization reactions. This aspect is covered only when the silver control experiments give substantial positive results. 

A selection of the literature is also necessary in order to give the reader an overview of silver chemistry in the field of cycloisomerization reactions. Therefore, this chapter is not intended to be an exhaustive review of the literature, since more recent specialized reviews can be accessed for that purpose.3-10,26... 

R = H) 1 could selectively undergo a cycloisomerization reaction to produce various furan rings 2 under mild conditions with rhodium(I) or silver(I) catalysts. 

Moreover, following the cycloisomerization reaction, a tandem dimerization reaction is also possible on the same substrates under Pd11, Ag1, and Aura catalysis, leading to different substituted furans (4 or 6) depending on the nature of the catalyst used (Scheme 5.5). Indeed, from compound 3 (Scheme 5.5), palladium(II) catalysis led to a 59% yield of 4, whereas silver(I) and gold(III) catalysis led to furans 5 and 6.41... 

Van der Eycken s group developed a silver(I)-mediated synthesis of substituted furo[2,3-6]pyrazines.53 Starting from -methoxybenzyl-protected 3,5-dichloropyr-azine-2(l//)-ones 26 (Scheme 5.13), after a regioselective microwave-assisted Sonogashira reaction with various terminal alkynes, the cycloisomerization reaction could occur using AgOTf (2 mol%) with trifluoroacetic acid (TFA, 5 equiv) to yield... 

Few examples of ene-yne cycloisomerization reactions are seen in the literature. The first results for ene-yne cycloisomerizations were with systems bearing an heteroatom (amine or oxygen) next to the alkene counterpart (forming an enamine or an enol ether). Indeed, Dake s group reported the cyclization of enesulfonamides on alkynes (69-70, Scheme 5.30) under catalysis by platinum and silver salts.85 Catalysis using AgOTf (1 1 mol%) was particularly efficient with systems such as 69 (Scheme 5.30)... 

Belmont s group87 reported a cycloisomerization reaction on quinolines 77 (Scheme 5.34) bearing a silyl enol ether group on position 3 and an alkynyl group on position 2, leading to acridine derivatives 78. 

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