Development of a Control Strategy for Benzene Impurity in HPMCAS-Stabilized Spray-Dried Dispersion Drug Products Using a Science-Based and Risk-Based Approach.

PURPOSE: To develop a strategy to control benzene, an ICH Q3C Class 1 impurity that may be present in spray solvents at ppm concentration, in amorphous polymer-stabilized spray-dried dispersion (SDD) products. METHODS: Risk assessments included determining the probability for benzene concentration in primary spray solvents, the physical properties of volatiles, and the potential enrichment of benzene from solution to solid. Mechanistic understanding of benzene removal was gained through a benzene-spiked fate and tolerance (F&T) study simulating worst-case spray-drying conditions and application of diffusion models for secondary drying. RESULTS: The mass ratio of spray solution to solid presented the highest risk of benzene enrichment. With slow spray-drying kinetics, benzene was reduced about 700-fold. Under standard secondary-drying conditions to remove residual solvents, residual benzene was further removed. Using diffusion models, the maximum benzene concentration was approximated for SDDs dried to the in-process control (IPC) limit of primary solvents. CONCLUSIONS: Two critical control points were established to eliminate any risk of residual benzene reaching patients: (1) upstream control of benzene in solvents (≤10 ppm) and (2) IPC of residual solvents in polymer-stabilized SDDs.

Anti-oxidant constituents of the roots and stolons of licorice (Glycyrrhiza glabra).

As part of a search for new cancer chemopreventive agents, a new chalcone derivative (1), a novel group of neolignan lipid esters (2), and seven known phenolic compounds (formononetin, glabridin, hemileiocarpin, hispaglabridin B, isoliquiritigenin, 4'-O-methylglabridin, and paratocarpin B) (3-9) were isolated from the roots and stolons of licorice (Glycyrrhiza glabra). The structures of compound 1 and the individual components of isolate 2 were elucidated using various spectroscopic and chemical methods. All isolates were tested in an authentic peroxynitrite anti-oxidant assay. Of these compounds, hispaglabridin B (6), isoliquiritigenin (7), and paratocarpin B (9) were found to be the most potent anti-oxidant agents. Furthermore, isoliquiritigenin (7) was demonstrated to prevent the incidence of 1,2-dimethylhydrazine-induced colon and lung tumors in mice when administered at a dose of 300 mg/kg.