Abstract Synthesis of Liriodenine, A Selective Muscarinic Antagonist Liriodenine, an 7-oxoaporphine alkaloid was found to inhibit tracheal and ileum contraction of guinea-pig induced by carbachol. It also showed to have cardiotonic effect but only one tenth potency compared with smooth muscle relaxation effect. The pharmacological activity was demonstrated that liriodenine is a selective muscarinic M3 subtype receptor antagonist. The structure of liriodenine is completely different from the known M3 antagonist (eg. 4-DAMP). To enhance the selectivity on muscarinic M3 antagonist activity, structural modification and SAR study is essential for liriodenine. In this thesis, we like to focus on the development of a new and facile synthesis of liriodenine. Application of the proposed synthetic method will be beneficial to design new lead as potential bronchodilators. Liriodenine was prepared by condensation of piperonal and aminoacetaldehyde dimethyl acetal, and then to form the 6, 7-methylenedioxyisoquinoline (27) via Pomeranz-Fritsch reaction. Then it was reacted with benzoyl chloride and trimethylsilyl cyanide to yield isoquinoline Reissert compound 28. The Reissert 28 was condensed with o-bromo- or o-iodobenzaldehydes to form the corresponding benzylisoquinoline esters 32 and 33, and then hydrolyzed to alcohols 34 and 35 and oxidized to ketone 36 and 37. Finally, intramolecular cyclization of the alcohols 34 and 35 react either by photo irradiation or tributyltin hydride or Pschorr reaction to finish the total synthesis of liriodenine. The yields of total synthesis of liriodenine were 19% for photocyclization, 17% for organotin hydride cyclization, and 6% for Pschorr cyclization. Cyclization by tributyltin hydride is the most effective way to prepare liriodenine with high yield and it should be able to apply in large scale synthesis.