Abstract
Stability studies are an integral part of the drug development process for any drug product. In addition to monitoring chemical degradation, the physical stability of a drug product must also be evaluated to ensure that the drug release and performance is not affected by storage. In this study, directly compressed tablets of 16 different formulations were exposed to an accelerated stability program to quantify changes in tablet breaking force, porosity, contact angle and disintegration time. Tablets were exposed to five different storage conditions from 37∘C/30% relative humidity (RH) to 70∘C/75%RH with testing after 2 and 4 weeks of storage. Each formulation contained two different fillers (47% w/w each), a disintegrant (5% w/w) and magnesium stearate (1% w/w). The results show that tablets stored at high humidity show increases in porosity and decreases in tensile strength, particularly if they contain a highly hygroscopic filler such as microcrystalline cellulose (MCC). For tablets stored at high temperature, the most commonly affected property was the tablet wettability, measured by sessile drop contact angle measurements. These results are considered in combination with the performance-controlling disintegration mechanism (Maclean et al., 2021) to identify the critical properties which influence the performance after storage.
Highlights
Stability testing is a crucial step in the development of any drug product
This study found that the behaviour on stability changed depending on the disintegrant used, for example, tablets containing croscarmellose sodium (CCS) were more strongly affected by storage at 37∘C/ 80%relative humidity (RH) despite still having a faster disintegration time than those con taining XPVP or low-substituted hydroxypropyl cellulose (L-HPC)
This study investigated the effects of accelerated storage conditions on the physical properties of directly compressed placebo tablets
Summary
The main focus of stability testing is on assessing the chemical degradation to ensure that the product remains safe throughout the duration of its shelf-life. Accelerated stability studies are routinely used to study chemical degradation, and this data is often used to extrapolate for long-term storage. Industrial interest in accelerated predictive techniques has grown rapidly (Qiu, 2018; Williams et al, 2017). A recent survey by Williams et al (2017) documented the properties currently being studied with risk-based predictive stability techniques in industry. By developing an improved understanding of the underlying mechanisms of physical change during storage, more appropriate pre dictive tools could be developed which better fit the needs of physical stability testing
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