Stereochemistry Cope rearrangement

The Simmons-Smith cyclopropanation reaction Stereochemically controlled epoxidations Regio- and Stereocontrolled Reactions with Nucleophiles Claisen-Cope rearrangements Stereochemistry in the Claisen-Cope rearrangement The Claisen-Ireland rearrangement Pd-catalysed reactions of allylic alcohols Pd-allyl acetate complexes Stereochemistry of Pd-allyl cation complexes Pd and monoepoxides of dienes The control of remote chirality Recent developments Summary... 

The stereochemistry of acyclic anionic oxy-Cope rearrangements is consistent with a chair TS having a conformation that favors equatorial placement of both alkyl and oxy substituents and minimizes the number of 1,3-diaxial interactions.214 For the reactions shown below, the double-bond configuration is correctly predicted on the basis of the most stable TS available in the first three reactions. In the fourth reaction, the TSs are of comparable energy and a 2 1 mixture of E- and Z-isomers is formed. 

The mechanism and stereochemistry of the orthoester Claisen rearrangement is analogous to the Cope rearrangement. The reaction is stereospecific with respect to the double bond present in the initial allylic alcohol. In acyclic molecules, the stereochemistry of the product can usually be predicted on the basis of a chairlike TS.233 When steric effects or ring geometry preclude a chairlike structure, the reaction can proceed through a boatlike TS.234... 

The stereoselectivity achieved in the synthesis in Scheme 13.12 is the result of a preferred conformation for the base-catalyzed oxy-Cope rearrangement in Step B. Although the intermediate used in Step B was a mixture of stereoisomers, both gave predominantly the desired relative stereochemistry at C(4) and C(7). The stereoselectivity is based on the preferred chair conformation for the TS of the oxy-Cope rearrangement. 

In certain cases, the C-H activation/Cope rearrangement is so favorable that double C-H functionalization can occur as illustrated in Equation (38). The product 33 was formed in 99% ee with excellent control of stereochemistry at four centers due to the involvement of a cascade process rather than a direct C-H insertion. 

A new multistep synthesis of ( )-reserpine (109) has been published by Wender et al. (258). The key building block of the synthesis is cw-hexahydroiso-quinoline derivative 510, prepared by the extension of the previously elaborated (259) Diels-Alder addition-Cope rearrangement sequence. Further manipulation of 510 gave 2,3-secoreserpinediol derivative 512, which already possesses the required stereochemistry in ring E. Oxidative cyclization of 512 yielded 3-isoreserpinediol (513), which was transformed by the use of simple reaction... 

Now the stereochemistry. Assume the thermodynamically more stable iminium ion forms (Me groups cis). The Cope rearrangement occurs from a chair conformation. This puts the Ph, H2, and HI 1 all pointing up both before and after the rearrangement. Assuming the Mannich reaction occurs without a change in conformation (a reasonable assumption, considering the proximity of the nucleophilic and electrophilic centers), the Ph, H2, and HI 1 should all be cis in the product. 

A method for highly efficient asymmetric cyclopropanation with control of both relative and absolute stereochemistry uses vinyldiazomethanes and inexpensive a-hydroxy esters as chiral auxiliaries263. This method was also applied for stereoselective preparation of dihydroazulenes. A further improvement of this approach involves an enantioselective construction of seven-membered carbocycles (540) by incorporating an initial asymmetric cyclopropanation step into the tandem cyclopropanation-Cope rearrangement process using rhodium(II)-(5 )-N-[p-(tert-butyl)phenylsulfonyl]prolinate [RhjtS — TBSP)4] 539 as a chiral catalyst (equation 212)264. 

The stereochemistry of the Cope rearrangement has aroused considerable interest. Doering and Roth set out to determine whether a boatlike (83) or chairlike (84) transition state is preferred. Their experiment, the results of which... 

A new synthesis of reserpine (Scheme 19)60 makes use of a very neat synthesis of cw-hydroisoquinoline derivatives, e.g. (Ill), by means of a Diels- Alder /Cope rearrangement sequence. Manipulation of (111) by unexceptional methods then gives (112), which possesses the required stereochemistry in ring E. Oxidative cyclization of (112) affords 3-isoreserpinediol (113) but, unfortunately, some inside isomer, originating from the cyclization of C-2 with C-21, is also obtained. The synthesis also loses some elegance in the multi-stage conversion of 3-isoreserpinediol into 3-isoreserpine (114), since, in the Swem oxidation of the C-16 aldehyde cyanhydrin by means of DMSO with oxalyl chloride as activator, the over-oxidized products (115) and (116) were obtained. However, reduction of (115) gave 3-isoreserpine (114), which has previously been converted into reserpine by four different methods. 

According to the Woodward-Hoffmann rales, five concerted transition states are possible for the Claisen as well as the closely related Cope rearrangements chair, boat, twist, cross and plane (Table 6). Only the chair and boat TS have to be considered, as twist, cross and plane are antarafacial-anta-rafacial processes and require highly elevated temperatures. - For the correct prediction of product stereochemistry it is nevertheless crucial to know the preference for chair- or boat-like transition state in the actual 3,3-sigmatropic shift. 

The tandem Cope-Cltdsen rearrangement of triene (96 equation 14) creates a product with three new stereogenic centers. Only two of the four possible stereoisomers are formed, namely, aldehydes (100) and (98) in a 78 22 ratio. The factors that control the stereochemistry are the chair-like versus boat-like transition state of the Cope rearrangement (96 giving 97) and the formation of the carbon-carbon bond in... 

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