Three-Dimensional NMR Spectroscopy of Fluorinated Pharmaceutical Solids under Ultrafast Magic Angle Spinning.

High-resolution solid-state analysis of multicomponent molecular systems, e.g., pharmaceutical formulations, is a great challenge. Solid-state nuclear magnetic resonance (ssNMR) spectroscopy plays a critical role in the characterization of solid dosage forms due to its capabilities of chemical identification, quantification, and structural elucidation at a molecular level. However, the low NMR sensitivity as well as the high spectral complexity and low drug loading of multicomponent products hinder an in-depth investigation of the active pharmaceutical ingredient (API) at the natural isotopic abundance. Herein, we developed two new three-dimensional (3D) ssNMR methods, including 1H-19F-1H and 19F-19F-1H correlations and successfully applied them to characterize a fluorinated drug molecule, aprepitant, and its commercial nanoparticulate formulation EMEND (Merck & Co, Inc., Kenilworth, NJ, USA). These 1H-detection methods utilize the significantly enhanced sensitivity and resolution of 1H and 19F afforded by 60 kHz ultrafast magic angle spinning (MAS) and enable the analysis of milligram samples. The 3D techniques simultaneously provide homonuclear 1H-1H and 19F-19F, and heteronuclear 1H-19F correlations of the crystalline aprepitant without interferences from other pharmaceutical components in the drug product. Moreover, our results demonstrate that 19F is a highly sensitive spin for probing molecular details of fluorinated drug substances in solid formulations, due to its high isotopic abundance, large gyromagnetic ratio, and absence of signal interference from pharmaceutical excipients, as well as for characterizing structural properties of a broad range of fluorine-containing materials.