Stereoselective cyclization reaction

Sowell, C.G., Wohn, R.L., and Little, R.D., Electtoreductive cyclization reactions. Stereoselection, creation of quaternary centers in bicychc frameworks, and a formal total synthesis of quadrone. Tetrahedron Lett., 31, 485, 1990. 

An efficient two-step annelation of functionalized orthoesters with trimethyl-silyloxyfuran derivatives has been reported that produces bicyclo[3. .0]lactones. ° The reaction in Scheme 7 shows an example in which the initial condensation between silyl enol ether and orthoester is followed by the radical cyclization reaction under standard conditions. It is worth underlining the complete diastereocontrol in which three contiguous stereocenters are generated in one step with >95% stereoselectivity. 

The cis configuration of 96 was elucidated by X-ray structure analysis. The data suggest that the cyclization reaction of the anion 95 generated from 94 to 91a proceeds stereoselectively in the solid state [16]. 

Enantiospecific syntheses of amino derivatives of benzo[ ]quinolizidine and indolo[2,3- ]quinolizidine compounds have also been achieved via A-acyliminium ion cyclization reactions, as an alternative to the more traditional Bischler-Napieralski chemistry (see Section 12.01.9.2.2). One interesting example involves the use of L-pyroglutamic acid as a chiral starting material to construct intermediates 240 via reaction with arylethylamine derivatives. Diisobutylaluminium hydride (DIBAL-H) reduction of the amide function in 240 and subsequent cyclization and further reduction afforded piperidine derivatives 241, which stereoselectively cyclized to benzo[ ]quinolizidine 242 upon treatment with boron trifluoride (Scheme 47) <1999JOC9729>. 

Ma et al. described the palladium(0)-eatalyzed three-component tandem double-addition-cyclization reaction of 2-(2,3-allenyl)malonate 218, Phi, and A-Ts-imine 219 for the stereoselective synthesis of 2,5-m-pyrrolidine 220... 

The key features of the catalytic cycle are trapping of the radical generated after cycliza-tion by an a,P-unsaturated carbonyl compound, reduction of the enol radical to give an enolate, and subsequent protonation of the titanocene alkoxide and enolate. The diaster-eoselectivity observed is essentially the same as that achieved in the simple cyclization reaction. An important point is that the tandem reactions can be carried out with alkynes as radical acceptors. The trapping of the formed vinyl radical with unsaturated carbonyl compounds occurs with very high stereoselectivity, as shown in Scheme 12.21. 

The examples illustrated in the almost 100 schemes in this chapter demonstrate how versatile donor-substituted allenes can be in synthetic processes. The major applications concern addition reactions and cycloadditions to the allenic double bonds, which furnish products with valuable functional groups. Of particular interest are metalations - usually at C-l of the allene unit - followed by reactions with electrophiles that deliver compounds which can often be used for cyclization reactions. A variety of highly substituted and functionalized heterocycles arises from these flexible methods, which cannot be obtained by other reactions. Many of these transformations proceed with good regioselectivity and excellent stereoselection. 

Alternative, also stereoselective, routes to allenic steroids take advantage of cationic cyclization reactions [108] or [2,3]-sigmatropic rearrangements [109]. For example, the allenic Michael acceptor 112 was prepared with 57% chemical yield by reaction of mestranol (111) with diethyl chlorophosphite and was found to inhibit the sterol biosynthesis of the pathogen responsible for Pneumocystis carinii pneumonia (PCP), the most abundant AIDS-related disease (Scheme 18.36) [110]. 

The anion radical species formed by the electroreduction of aliphatic esters show interesting reactivities, and the reduction of olefinic esters gives bicyclic products with high regio- and stereoselectivity. The electroreduction of the ester in the presence of chlorotrimethylsilane affords a tricyclic product (Scheme 21) [35, 40]. The mechanism of this cyclization reaction seems to be the addition of anion radical species, formed by the reduction of the ester group, to the carbon-carbon double bond. 

Figure 11 Proposed mechanism of cyclization of dehydrated NisA by NisC. The cyclization reaction shown results in the formation of the B-ring of nisin. The possible stabilization through a /3-turn-like structure via hydrogen bonding between the amide NH of Cys and the carbonyl of Dha/Dhb is shown and may explain the high stereoselectivity observed in nonenzymatic cyclizations involving four amino acids as discussed in the text. Reprinted with permission from B. Li W. A. van der Donk, J. Biol. Chem. 2007, 282, 21169-21175.

The electroreductive cyclization reaction of 6-heptene-2-one 166, producing CIS-1,2-dimethylcyclopentanol 169, was discovered more than twenty years ago [166]. In agreement with Baldwin s rules, the 5-exo product is obtained in a good yield. Since that time, the mechanism of this remarkable regio- and stereoselective reaction has been elucidated by Kariv-Miller et al. [167-169]. Reversible cyclization of the initially formed ketyl radical anion 167 provides either the cis or the trans distonic radical anion. Subsequent electron transfer and protonation from the kinetically preferred 168 leads to the major cis product 169. The thermodynamically preferred 170 is considered as a source of the trace amounts of the trans by-product 171 (Scheme 32). 

A -tritylaziridine-2-(5)-carboxaldehyde. The application of a novel, sequential, trans-acetalation oxonium ene cyclization has delivered a stereoselective synthesis of the C-aromatic taxane skeleton, and a combinatorial sequence of the regioselective propiolate-ene, catalytic enantioselective epoxidation and carbonyl-ene cyclization reactions has been used to complete the synthesis of the A-ring of a vitamin D hybrid analogue. 

Alternatively, the acidity of the aldehyde-derived CH or CH2 group can be enhanced by converting the isocyanide derived amide into an ester. According to this principle, tandem Ugi-Dieckmann was exploited in the context of carbapenem synthesis, where the first 4-membered ring was built through an intramolecular Ugi reaction of p-amino acid 66. Then, after a three-step manipulation of the carboxylic appendages, a Dieckmann cyclization afforded, stereoselectively, the desired carbapenem skeleton 67 [79]. 

A stereoselective one-pot synthesis of furo[3,2- ]pyran, 80, has been reported. The key step in the synthesis includes a double cyclization reaction along with a rearrangement (Scheme 16) <1998TL3605>. 

A. De Mesmaeker, P. Hoffmann, and B. Ernst, Stereoselective bond formation in carbohydrates by radical cyclization reactions. Tetrahedron Lett. 29 6383 (1988). 

Stereochemical investigation on the vinylogous 1,5-elimination reactions of 16 to give cyclopropylalkenes has revealed highswi stereoselectively of the intramolecular SN process (equation 18)30. The stereoselectivity of the cyclization reaction of 17 to give the ( )-isomer is improved by the increase in steric bulkiness of the sulfonyl substituent (equation 19)31. 

Treatment of functionalized vinyllithium, 28, with allylmaghesium bromide in the presence of zinc bromide leads to a stereoselectively substituted, metallated cyclopropane, 29, via a tandem metalla-Claisen-cyclization reaction (equation 48 )M. The produced cyclo-... 

The acetylacetone carbanion undergoes addition to the imine carbon atom of complex (92) but subsequent cyclization and deacylation processes occur (Scheme 42).212 The apical ammonia group is the most acidic and consequently is favoured to cyclize on to the carbonyl group. In the bis-(1,2-diaminoethane) complex related to the imine chelate (92), the two apical nitrogen atoms are no longer geometrically equivalent. Thus two products are formed when hydrogen cyanide is added to the complex and subsequent cyclization takes place (Scheme 43).213 However, the cyclization reaction is stereoselective. 

The stereoselectivity of cyclization reactions conducted under conditions of thermodynamic control can often be reliably predicted by estimation or calculation of the energy differences between the diastereomers of the cyclization product (H) or its immediate precursor (G). It has been shown that, even in cases where the (G) to (H) step is not reversible, thermodynamic control of the diastereomer ratio can be influenced through the use of cyclization substrates in which the neutralization step (G to H) is the slow step, thus allowing for equilibration of the diastereomers of (G). Thermodynamic equilibration of dia-stereomeric products will occur only if the reaction reverses to starting materials (A), or interconversion of the diastereomers of the intermediates (B) or (C) occurs in some other way (e.g. the C to D interconversion can equilibrate diastereomers if E = X). 

The use of Lewis acids in controlling the stereoselective outcome of radical cyclization reactions has been explored, in particular the effect of aluminium-based Lewis acids using low temperature Et3B/Bu3SnH-initiated procedures.171,172 For example, cyclization of propargyl ether (78) or allyl ether (79) in the presence of Lewis acid (80) can completely reverse the normal selectivity (Scheme 34).171 The effect of aluminium Lewis acids on the diastereoselectivity of 6-exo cyclization of unsaturated chiral menthol esters has been studied.172 Cyclization at low temperature in the presence of the Lewis acid MAD modified the de of the reaction from 31 to 98%. 

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