A novel route to trans-THFs and the synthesis of sylvaticin

Williams, Oliver M. H.

January 2009

trans-2,5-Disubstituted-tetrahydrofurans (THFs) are a common structural motif in many biologically active natural products, particularly in the Annonaceous acetogenins. This thesis develops a new route for their synthesis and applies it to the total synthesis of the Annonaceous acetogenin sylvaticin. Chapter 1: Introduction – Synthetic routes to trans-2,5-substituted tetrahydrofurans This chapter reviews methods for the synthesis of trans-2,5-THFs that have been applied to natural products synthesis. Chapter 2: Results & Discussion – A Novel Route to trans-THFs The rearrangement of activated 2,5-disubstituted cis-THFs is reviewed and is developed into a new synthetic method for the synthesis of trans-THFs. The reaction proceeds via a hydride shift mechanism to form an oxonium ion. Intramolecular reduction by a tethered hydrosilane stereoselectively forms the trans-THF. The mechanism of the rearrangement is investigated with the use of different stereoisomers and a deuterium labelling study. A cross-over study is carried out which confirms the reaction occurs via the proposed hydride shift mechanism. Chapter 3: Introduction – The Annonaceous Acetogenins This chapter introduces the Annonaceous acetogenins, a biologically active class of natural products often found with THF rings in their structure. The three key areas for their synthesis are explored- the synthesis of the THF core, the synthesis of the butenolide ring, and their coupling. Chapter 4: Results & Discussion – The Synthesis of Sylvaticin The Annonaceous acetogenin sylvaticin is introduced, and its isolation in nature and biological activity reviewed. With the aid of a model system study to extend the scope of the reaction, the methodology developed in Chapter 2 is then applied to the synthesis of sylvaticin. The synthesis, the first to be reported, is completed in a total of 19 linear steps starting from commercially available tetradecatetraene. In order to prove the obtained structure is that found in nature, a comprehensive investigation is undertaken using Mosher ester derivatives and the synthesis of its bis-epimer, 4,36-epi,epi sylvaticin. Chapter 5: Experimental Full experimental procedures and characterisation of compounds are reported.

547.7

The Direct Detection and Kinetic Studies of Dimethylgermylene and Tetramethyldigermene In Solution By Nanosecond Laser Flash Photolysis / Dimethylgermylene and Tetramethyldigermene In Solution

Lollmahomed, Farahnaz Begum

10 1900

<p> Dimethylgermylene (GeMe2) has been generated by laser flash photolysis of 1,1dimethyl-3-phenylgermacyclopent-3-ene (23) and 1,1,3-trimethyl-4phenylgermacyclopent-3-ene (24) in hexanes at 25°C and its absorption maximum (λmax) has been unambiguously established to be 470 nm. GeMe2 decays with second-order kinetics under these conditions (2k/ε. = (10 ± 2) x 10^7 cm s^(-1)) to give Ge2Me4 (λmax = 370 nm). Kinetic studies of the reactions of GeMe2 and Ge2Me4 with typical germylene/digermene scavengers such as 1,3-dienes, olefins, alkynes, alkyl halides, group 14 metal hydrides, carboxylic acids, and amines have been carried out. </p> <p> GeMe2 reacts reversibly with MeOH, t-BuOH and THF to form Lewis acid-base complexes which exhibit relatively strong absorption bands that are blue-shifted with respect to GeMe2 (λmax ~ 295-310 nm). The decay of the Me2Ge-MeOH complex is accelerated in the presence of a Brnnsted acid (acetic acid or methanesulfonic acid) or base (MeONa). The reactions of the Me2Ge-THF complex with sodium methoxide, methanesulfonic acid, 4,4-dimethyl-1-pentene, 2,3-dimethyl-1-butadiene, acetic acid and CC4 have also been studied in THF. </p> <p> The photochemistry of two well-known precursors to GeMe2, namely dodecamethylcyclohexagermane (14) and dimethylphenyl(trimethylsilyl)germane (18) was reinvestigated. Laser flash photolysis of 14 in hexanes led to the formation of two transients, one with λmax= 490 nm (τ < & = 10 ns) and the second with λmax= 470 nm. The latter decays with second-order kinetics with concomitant formation of a new transient with λmax= 370 nm. The transient at 470 nm is assigned to GeMe2 and that at 370 nm to Ge2Me4, based on comparisons to the results obtained from laser flash photolysis of 23 and 24. Laser flash photolysis of 18-in hexane gives rise to two absorption bands centered at λmax = 300 nm and λmax = 430 nm, which are assigned to the dimethylphenylgerrnyl radical and the conjugated gerrnene derivative 38, respectively. GeMe2 cannot be detected in laser flash photolysis experiments with this compound. </p> / Thesis / Doctor of Philosophy (PhD)