Olefin cyclization complex

Cyclization via intramolecular olefination of complex phosphonates remains the most important method of synthesis for complex natural macrocycles. Examples include syntheses of 20-membered macrolide antibiotic, aglycones of venturicidins A and B,108 oleandomycin (a 14-membered macrolide antibiotic), 109 the 19-membered macrocyclic antibiotic, anti-tumour agent (-t-)-hitachimycin,ll0 and the macrocyclic lactones (183).1H Cyclization of the phosphonate (184) under Masamune-Roush conditions has been used to synthesize the 28-membered macrolactam myxovirescin B.112... 

For the dimerization of 4,4 -dimethoxystilbene, it has been possible to demonstrate spectroelectrochemically [115] and at the rotating ring-disk electrode [116] that the product is formed mainly by radical dimerization of the intermediate radical cations [path B, Eq. (13)]. Fast derivative CV, however, supports for the same olefin a complex ECE pathway [path A, Eq. (13) [117]. Depending on the oxidation potential and the kind of the nucleophiles (acetate, water, or methanol), a tetrahydronaphthalene derivative (Table 6, number 3) [118], a monomer diacetate [118], a tetrahydrofuran [115], or a dimer dimethoxy compound is found. When methanol is replaced by aqueous dichloromethane or by aqueous acetonitrile emulsions as solvent, styrene (Table 6, number 4) [119a] and a-methylstyrene [119b] yield 2,5-diphenyltetrahydrofurans. In some cases cyclization occurs by electrophilic aromatic substitution (analogous to Table 6, number 3). 

The large number of synthetically useful intermolecular hydrodimerizations and intramolecular cyclizations of activated olefins to complex carbon skeletons involves in most cases radical anions as key intermediates [152]. 

Stereospecific 2,3-epoxidation of squalene, followed by a nonconcerted carbocationic cyclization and a series of carbocationic rearrangements, forms lanosterol [79-65-0] (77) in the first steps dedicated solely toward steroid synthesis (109,110). Several biomimetic, cationic cydizations to form steroids or steroidlike nuclei have been observed in the laboratory (111), and the total synthesis of lanosterol has been accomplished by a carbocation—olefin cyclization route (112). Through a complex series of enzyme-catalyzed reactions, lanosterol is converted to cholesterol (2). Cholesterol is the principal starting material for steroid hormone biosynthesis in animals. The cholesterol biosynthetic pathway is composed of at least 30 enzymatic reactions. Lanosterol and squalene appear to be normal constituents, in trace amounts, in tissues that are actively synthesizing cholesterol. 

This seems supported by the observation that the a-cyclobutylethyl-magnesium chloride rearrangement gives about equal amounts of ds- and tr nr-2-hexene. An incipient olefin w-complex would explain the large apparent amount of cis product, considering the thermodynamic stability of the cis olefin in comparison with the trans product. Of course a transition state in which olefinic character was not highly developed would also explain the observations. The reverse, cyclization process, has also been studied. 

Starting from tetrahydrocyclopenta[f)]furan-2-one 342, enyne 343, the substrate for the domino reaction, was prepared in 12 steps and with an overall yield of 45%. Exposure of 343 to the electron-rich gold(I) complex (t-Bu)2P(o-biphenyl)AuCl at room temperature afforded cis-hydrindanone 344 in 78% yield as a single stereoisomer (Scheme 14.54). The postulated mechanism involved Au(I) activation of the alkyne to initiate the cationic olefin cyclization of 346 to give carbocation 347, which then underwent a pinacol rearrangement to the final product 344. An originally attempted Lewis acid-catalyzed domino Prins/pinacol rearrangement of... 

As a preliminary mechanistic proposal, we hypothesize that the palladimn(ll)-phosphoramidite catalyst acts as a chiral n-acid to activate the amine iV-oxide substrate (Scheme 1S.291. similar to the mechanism proposed for the Overman rearrangement of allylic trichloroacetimidates. While it is not clear whether the reactive species is oxide-bound complex 119a or olefin-bound complex 119b, we propose heterocycle 120 as an intermediate in this cyclization-induced mechanism Grob-type fragmentation eventually reveals O-allylhydroxylamine 117 and the palladium(n)-phosphoramidite catalyst, which can reenter the catalytic cycle. 

One of the most novel methods of preparation of metal 7r-complexes involves the cyclization by trimerization of acetylene and its substituted derivatives. Both arene and olefin 71-complexes have been prepared by this method. 

Thus, one equivalent of dimethylaluminium chloride has been shown to result in an ene reaction to give the alcohol (46), compared to the use of two equivalents, which produces complex mixtures by means of cation-olefin cyclizations. ... 

It was not fully realized until my breakthrough using superacids (vide infra) that, to suppress the deprotonation of alkyl cations to olefins and the subsequent formation of complex mixtures by reactions of olefins with alkyl cations, such as alkylation, oligomerization, polymerization, and cyclization, acids much stronger than those known and used in the past were needed. 

The following compounds have been obtained from thiete 1,1-dioxide Substituted cycloheptatrienes, benzyl o-toluenethiosulfinate, pyrazoles, - naphthothiete 1,1-dioxides, and 3-subst1tuted thietane 1,1-dioxides.It is a dienophile in Diels-Alder reactions and undergoes cycloadditions with enamines, dienamines, and ynamines. Thiete 1,1-dioxide is a source of the novel intermediate, vinylsulfene (CH2=CHCH=SQ2). which undergoes cyclo-additions to strained olefinic double bonds, reacts with phenol to give allyl sulfonate derivatives or cyclizes unimolecularly to give an unsaturated sultene. - Platinum and iron complexes of thiete 1,1-dioxide have been reported. 

Hexacarbonyldicobalt complexes of alkynes have served as substrates in a variety of olefin metathesis reactions. There are several reasons for complex-ing an alkyne functionality prior to the metathesis step [ 125] (a) the alkyne may chelate the ruthenium center, leading to inhibition of the catalytically active species [125d] (b) the alkyne may participate in the metathesis reaction, giving undesired enyne metathesis products [125f] (c) the linear structure of the alkyne may prevent cyclization reactions due to steric reasons [125a-d] and (d) the hexacarbonylcobalt moiety can be used for further transformations [125c,f]. 

Hegedus et al. have thoroughly studied the homogeneous hydroamination of olefins in the presence of transition metal complexes. However, most of these reactions are either promoted or assisted, i.e. are stoichiometric reactions of an amine with a coordinated alkene [98-101] or, if catalytic, give rise to the oxidative hydroamination products, as for example in the cyclization of o-allylanilines to 2-alkylindoles [102, 103], i.e. are relevant to Wacker-type chemistry [104]. 

An enantioselective variant of the diene cydization reaction has been developed by application of chiral zirconocene derivatives, such as Brintzinger s catalyst (12) [10]. Mori and co-workers demonstrated that substituted dial-lylbenzylamine 25 could be cyclized to pyrrolidines 26 and 27 in a 2 1 ratio using chiral complex 12 in up to 79% yield with up to 95% ee (Eq. 4) [ 17,18]. This reaction was similarly applied to 2-substituted 1,6-dienes, which provided the analogous cyclopentane derivatives in up to 99% ee with similar diastereoselectivities [19]. When cyclic, internal olefins were used, spirocyclic compounds were isolated. The enantioselection in these reactions is thought to derive from either the ate or the transmetallation step. The stereoselectivity of this reaction has been extended to the selective reaction of enantiotopic olefin compounds to form bicyclic products such as 28, in 24% yield and 59% ee after deprotection (Eq. 5) [20]. 

Electronic factors also influenced the outcomes of these cyclization reactions cyclization of pyrrole 84 to bicyclic amine 85 is catalyzed by the sterically open complex 79a. In this reaction, initial insertion into the Y - H bond occurred in a Markovnikov fashion at the more hindered olefin (Scheme 19) [48]. The authors proposed that the Lewis basic aromatic ring stabilizes the electrophilic catalyst during the hydrometallation step, overriding steric factors. In the case of pyrroles and indenes, the less Lewis basic nitrogen contained in the aromatic systems allowed for the cyclization of 1,1-disubstituted alkenes. 

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