Trost cyclization

Palladium catalyzed cycloisomerizations of 6-cn-l-ynes lead most readily to five-membered rings. Palladium binds exclusively to terminal C = C triple bonds in the presence of internal ones and induces cyclizations with high chemoselectivity. Synthetically useful bis-exocyclic 1,3-dienes have been obtained in high yields, which can, for example, be applied in Diels-Alder reactions (B.M. Trost, 1989). 

Scheme 12. Trost s palladium(n)-catalyzed Alder ene cyclization process.

Trost and Ghadiri19 have found a Lewis-acid-mediated intramolecular cyclization of allyl sulfones. When the allyl sulfone 40 is treated with A1C13, polycondensed aromatic system 41 can be obtained in good yield (equation 24). The mechanism probably involves... 

Trost and coworkers137 have reported the polymer-supported palladium catalyzed cyclization of 1, l-bis(phenylsulfonyl)epoxyalkene 235 which gives cycloalkanes 236 and 237 in a 2 1 ratio (equation 143). This method has proven useful for the synthesis of macrocyclic compounds under neutral conditions without using high dilution technique. Temperature and concentrations are critical. The best results are achieved if a reaction mixture of 0.1-0.5 m is added to a preheated (at 65 °C) suspension of the catalyst. 

Trost, B.M., Godleski, S.A., Genet, J.P. (1978) A Total Synthesis of Racemic and Optically Active Ibogamine. Utilization and Mechanism of a New Silver Ion Assisted Palladium Catalyzed Cyclization. Journal of the American Chemical Society, 100, 3930-3931. 

Trost and his group reported a 6-endo cyclization en route to (-)-siccanin (Scheme 20). The minor diastereoisomer of the radical formed during cyclization yielded a THF derivative directly [98,99]. 

The use of 1,6-diene systems usually does not result in cyclization reactions with palladium ) salts. For example, with 1,6-heptadiene a /i-elimination takes place from the cqjr-intermediate to give diene 22 as the major product (equation 10)27. However, more recently Trost and Burgess21 have shown that with a 4,4-bis(phenylsulfonyl) derivative of 1,6-heptadiene (23) an insertion takes place to give a 5-membered ring product (24, equation 11). The final step of the latter reaction is oxidative cleavage of the palladium-carbon bond by CuCl2 to produce a carbon-chlorine bond. 

Pioneering studies of Trost and his co-workers have explored all the parameters of this reaction. An interesting piece of work has, for instance, shown that the presence of an ether or a silyl ether in a substrate also exerts a profound effect on the regioselectivity of the cyclization. Thus, a silyl ether group at the allylic position (202) furnishes the corresponding 1,3-diene 203, whereas an ether group at the homoallylic position gives exclusively the 1,4-diene 205 (Scheme 50).210... 

Trost et al 1 have observed product distribution to be dependent in part on the steric and electronic properties of the substrate. For example, linear enyne 48 (Equation (30)) cyclized exclusively to the Alder-ene product 49, whereas branching at the allylic position led to the formation of 1,3-diene 50 (Equation (31)) under similar conditions. Allylic ethers also give 1,3-dienes this effect was determined not to be the result of chelation, as methyl ethers and tert-butyldimethylsilyl ethers both gave dialkylidene cyclopentanes despite the large difference in coordinating ability. 

Trost et al.59 were the first to report enantioselectivity in the transition metal-catalyzed Alder-ene reaction. Several different acids were surveyed for the degree of efficacy in oxidizing the Pd(0) precursor to the active Pd(n) species and for compatibility with the catalyst, substrate, and product. Among acids surveyed were several chiral carboxylic acids products of reactions using these optically active acids were formed with modest enantioselectivity. (A)-binaphthoic acid gave the most promising result, with the cyclized product 83 obtained with 33% ee (Equation (52)). 

Trost [10] discovered a palladium-catalyzed enyne metathesis during the course of his study on palladium-catalyzed enyne cyclization. Treatment of the 1,6-enyne 25 with palladacyclopentadiene (TCPT, 26a) in the presence of tri-o-tolyl-phophite and dimethyl acetylene dicarboxylate (DMAD) in dichloroethane at 60°C led to cycloadduct 27 and vinylcyclopentene 28 in 97% yield in a ratio of 1 to 1 (Eq. 10). The latter compound 28 is clearly the metathesis product. 

The reaction mechanism was considered to be oxidative cyclization, and pal-ladacyclopentene 32 was formed. Reductive elimination then occurs to give cyclobutene 33, whose bond isomerization occurs to give diene 28. The insertion of alkyne (DMAD) into the carbon palladium bond of 32 followed by reductive elimination occurs to give [2+2+2] cocyclization product 27. Although the results of the reactions of E- and Z-isomers of 29 with palladium catalyst 26a were accommodated by this pathway, Trost considered the possibility of migration of substituents. Therefore, 13C-labeled substrate 25 13C was used for this reaction. 

Trost used a Sonogashira coupling, followed by reduction of the nitro group, to prepare 350, which in turn was converted to tricyclic lactam 351 by Pd-catalyzed cyclization (yield unreported) [309],... 

A rather different allene cyclization that takes place in tandem with an alkylative process has been described by Trost and Urabe [66] (Eq. 13.52). Exposure of ketoal-lene 169 to divinylmethylaluminum 170 in dichloromethane solution leads to 171 in 60% yield. The mechanism of this alkylative cyclization involves complexation of the Lewis acidic aluminum to the carbonyl oxygen atom, followed by ring closure, leading to zwitterion 172. Intramolecular transfer of a vinyl group from aluminum to carbon completes the process. 

Particularly interesting is the reaction of enynes with catalytic amounts of carbene complexes (Figure 3.50). If the chain-length between olefin and alkyne enables the formation of a five-membered or larger ring, then RCM can lead to the formation of vinyl-substituted cycloalkenes [866] or heterocycles. Examples of such reactions are given in Tables 3.18-3.20. It should, though, be taken into account that this reaction can also proceed by non-carbene-mediated pathways. Also Fischer-type carbene complexes and other complexes [867] can catalyze enyne cyclizations [267]. Trost [868] proposed that palladium-catalyzed enyne cyclizations proceed via metallacyclopentenes, which upon reductive elimination yield an intermediate cyclobutene. Also a Lewis acid-catalyzed, intramolecular [2 + 2] cycloaddition of, e.g., acceptor-substituted alkynes to an alkene to yield a cyclobutene can be considered as a possible mechanism of enyne cyclization. 

In 1992, Trost and his co-workers investigated desymmetrization of cyclic w j-o-diesters with lithium sulfonyl-methylenenitronate as a nucleophile in the presence of Trost s ligand 118, where the corresponding cyclic compounds are obtained with an excellent enantioselectivity via intramolecular cyclization (Scheme 15),103,103a Asymmetric cyclopropanation and lactone annulation are achieved according to this protocol (Scheme Nitroalkanes can also be employed as carbon-centered nucleophiles in lieu of malonates (Scheme 17). ... 

Trost and Tanoury found an interesting skeletal reorganization of enynes using a palladium catalyst.In this reaction, the second product is derived from a metathesis reaction (Equation (5)). It was speculated that the reaction would proceed by oxidative cyclization of enynes with the palladium complex followed by reductive elimination and then ring opening. To confirm this reaction mechanism, they obtained a compound having a cyclobutene ring, which was considered to be formed by the reductive elimination (Equation (6)). 

D. P. Curran, Radical Cyclization and Radical Reactions, in Comprehensive Organic Synthesis (Eds. B. M. Trost and I. Fleming), Pergamon Press, Oxford, 1991. 

Macrocyclization. Trost and Warner17 have effected efficient cyclization to ten-and fifteen-membered rings by use of Pd(0) supported on a polystyrene bearing phosphine ligands. Precursors with an epoxy vinyl terminal group proved particularly suitable. Thus, 1 in the presence of such a Pd(0) catalyst cyclizes to 2 and 3 in 71% yield. The products are isomeric at the double bond, since both are oxidized to the ketone 4. The same catalyst system converted 1 (n = 9) into two macrocyclic isomers in 66% yield. Both cyclizations are concentration dependent. The temperature is also critical, the reaction being particularly clean at 65°. 

Methylenecyclopentanes.2 Trost and Curran have used 1 as an electrophilic synthon for trimethylenemethane. Thus 1 reacts with the anion of 2 to give 3 in 72% yield. This product was oxidized to the disulfone, which was then cyclized to 4 by F. Various transformations are possible for the exocyclic methylene group. For the synthesis of coriolin (6), the group was converted to a pem-dimethyl group by cyclopropanation and hydrogenolysis. The product (5) was converted in several more steps into 6. 

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