Background: Solifenacin succinate is an active pharmaceutical drug molecule that is extremely effective in treating overactive bladder symptoms, such as urine incontinence, urgency, and frequent urination. The free base is yellow oil, and the salt solifenacin succinate forms yellowish crystals that are extremely stable and effective. Solifenacin is a very active antagonist due to its potent muscarinic M3 receptor antagonist characteristics. Furthermore, solifenacin is effective in the treatment of bowel syndrome (IBS) by blocking M3 receptors and a broad spectrum of bowel dysfunction. Objective: The objective of this study was to develop a practical and highly efficient scalable synthesis of enantiomerically pure solifenacin as an antimuscarinic agent. Methods: In this work, the Zn(OTf)2 catalyst was used to develop a novel, environmentally benign, high-yielding, and robust protocol for the synthesis of enantiomerically pure solifenacin succinate. Results: The synthesis of enantiomerically pure solifenacin succinate was achieved in seven steps using commercially available phenylethylamine and benzoyl chloride as the starting materials. We carried out the reaction optimization by treatment of (S)-1-phenyl-3,4-dihydroisoquinoline-2(1H)- carbonyl chloride and (R)-(-)-3-Quinuclidinolin in the presence of Zn(OTf)2 catalyst. Furthermore, the solifenacin-free base was treated with succinic acid to afford its corresponding salt. The highlight of this protocol is the use of 20 mol% Zn(OTf)2 catalyst for the first time. The readily available starting materials, robustness, easy operation, high yield, and low cost make the approach more attractive and highly applicable. Conclusion: In summary, we developed a novel Zn(OTf)2-catalysed environmentally benign, highyielding, and robust protocol for the synthesis of enantiomerically pure solifenacin succinate. The proposed strategy is highly cost-effective and avoids the use of hazardous and unsafe sensitive, strong bases as well as tedious work-up procedures. Effective synthesis was achieved using readily available starting materials and reagents. Thus, the protocol is highly efficient, compatible, and commercially viable for the synthesis of important solifenacin products.
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