Sauer, Effiette L. O2013-11-082013-11-0820072007Source: Dissertation Abstracts International, Volume: 68-10, Section: B, page: 6674.http://hdl.handle.net/10393/29452http://dx.doi.org/10.20381/ruor-19754This thesis explores the tandem oxy-Cope/Claisen/ene reaction and its application towards the total synthesis of two natural products, wiedemannic acid and LL-S491beta. Drawing on earlier studies carried out on the oxy-Cope/ene rearrangement, the oxy-Cope/Claisen/ene reaction adds to the previous methodology by allowing for the formation of highly functionalized decalin cores bearing up to four contiguous stereocentres, including two adjacent quaternary carbons. The scaffolds accessed by this new tandem pericyclic cascade allow for an easy foray into the synthesis of numerous diterpenoid natural products. The first part of this study focuses on the development of the oxy-Cope/Claisen/ene reaction with respect to both its scope and diastereoselectivity. A combination of experimental methods and theoretical studies allow for the origins of the observed diastereoselectivity to be unveiled. Through the use of judicious substituent selection and/or the addition of remote stereocentres for conformational control, the selectivity of this cascade reaction is effectively controlled. Armed with a highly efficient and stereoselective method for the preparation of functionalized decalin cores, the second part of this study centres on the application of this method to total synthesis. The preparation of a wiedemannic acid analogue is successfully completed with four of its five adjoining stereocentres being effectively set during the key oxy-Cope/Claisen/ene reaction. Owing to a discrepancy in the reported structure of wiedemannic acid however, the synthesis of the natural product is not further pursued. Rather, a new target is chosen. Several innovative routes towards the synthesis of LL-S491beta are described, each relying on the key tandem reaction cascade to build the core of its pimarane skeleton. Finally, the last section of this work addresses some of the novel chemistry discovered along the way including a unique ruthenium-mediated lactonization reaction and an enolate isomerization pathway during the oxy-Cope/ene reaction.501 p.enChemistry, Organic.Thesis