Polymorphism in R-tamsulosin (an alpha blocker): The unexpected manifestation of a sulfonamide⋯o-diethoxybenzene heterosynthon

Abstract

A two point NH⋯O dimer or an infinite catemer are the most preferred motifs/synthons for sulfonamide structures. Such synthons are known to be so robust that they are only disrupted in the presence of highly activated O acceptors such as pyridine-N-oxide and sulfoxide. We demonstrate in this article that a multi-point synthon offered by much weaker ethoxy O and amine N acceptors can however strongly compete and disrupt the robust sulfonamide homosynthons. This has been illustrated with the synthon analysis in three polymorphic crystal structures of R-tamsulosin, an active drug used in the treatment of Benign Prostatic Hyperplasia (BPH) and its hydrochloride salt. These crystalline solids are characterized by Single crystal X-ray diffraction (SC-XRD), powder X-ray diffraction (PXRD), Fourier Transform Infrared (FT-IR) and Raman spectroscopy. Forms I, II of the free base and hydrochloride salt crystallize in the monoclinic P21, C2, and P21 space groups respectively with two molecules in the asymmetric unit (Z′=2), whereas, form III of freebase crystallize in the orthorhombic P212121 space group with Z′=1. Remarkably, all four crystal structures contain a totally unexpected sulfonamide⋯o-diethoxybenzene heterosynthon. The multi-point motifs observed in polymorphs are relatively stronger than those in the hydrochloride salt because of the gauche conformation of the tamsulosin linker chain which renders an additional hydrogen bond interaction with amine N acceptor, and resemble the crown ether sulfonamide recognition pattern. Observation of this new heterosynthon offers potential scope in the design of pharmaceutical cocrystals for sulfonamide bearing drug molecules. The present study also presents a detailed hydrogen bond motif analysis in 310 primary sulfonamide structures culled from the latest version of Cambridge Structural Database (CSD). The role of various competing groups is discussed in the context of understanding the most recurring sulfonamide homo and heterosynthons.