A Rapid 3-Day Excipient Screening Methodology and its Application in Identifying Chemical Stabilizers for Solid Formulations with Mixed Mechanisms of Degradation.

This study outlines a practical approach for assessing chemical instability by heating the drug-excipient binary mixtures or multi-excipient formulations at 75°C for 3 days before characterization. Differentiating itself from other excipient compatibility methods, our methodology necessitates a saturated aqueous slurry rather than arbitrarily fixed water content. This allows bulk and surface water in the excipient to contribute to drug degradation. The synergistic impact of surface water and elevated temperature expedites degradation kinetics, resulting in accelerated data generation. Among excipient compatibility methods available, our method is quantitative and merges with traditionally used methodologies. The devised nomograph enables extrapolation of shelf life at 20°C from experimental data obtained at 75°C. This methodology also helped identify stabilizers for the drug NVS-1 where traditional excipient compatibility programs had failed. Incorporation of monovalent salts, such as sodium/potassium chloride and sodium bicarbonate at 5% w/w, significantly enhanced the chemical stability of NVS-1, ensuring stable tablet formulations. Our hypothesis posits that stabilization is due to increased ionic strength in the slurry, which stabilizes an induced dipole within the polar NVS-1 drug. Additionally, the presence of ions in the moisture layer is anticipated to stabilize π-π stacking of two planar aromatic NVS-1 molecules. The expedited generation of experimental data allowed the identification of inorganic salts to supplement a standard excipient compatibility screening panel. Considering the economic implications of stability testing methodologies in effort, cost, and duration, a faster turnaround in chemical stability data enhances formulation selection. This ultimately facilitates the development of drug formulations with greater efficiency without delays.

Evaluation of hydroxypropyl methylcellulose matrix systems as swellable gastro-retentive drug delivery systems (GRDDS).

Utilizing gastro-retentive drug delivery systems (GRDDS) to increase absorption of weakly basic drugs by extending their transit time is a promising approach. Swellable systems were evaluated for this purpose. Such systems demonstrate dual mechanism of release-diffusion and erosion. GRDDS requires maintaining its dimensions, which demands diffusion as a predominant mechanism of release (Fickian). In this work, dypyridamole, a weakly basic drug, together with various grades of hydroxypropyl methylcellulose and different excipients were evaluated for release and swelling properties. Dissolution data were analyzed by curve fitting to various models to estimate predominant release mechanism. It was found that matrices containing a swellable diluent like microcrystalline cellulose demonstrated predominantly Fickian mechanism of release, whereas soluble diluents (lactose and mannitol) contributed to a mixed mechanism of release. Addition of copovidone increased the swelling and survivability, whereas sodium chloride altered the erosion behavior. A correlation between matrix weight loss and drug release was obtained, which further consolidated the analysis. Correlation for the soluble excipients was linear, whereas that for the swellable excipient was nonlinear, implying predominance of Fickian release mechanism for the latter. Hence, the selection of excipients can influence matrix survivability and release kinetics, which can be used for developing GRDDS.