Modelling the Evolution of Pore Structure during the Disintegration of Pharmaceutical Tablets

Oral dosage forms for drug delivery to the colon: an existing gap between research and commercial applications

Oral drug administration is the preferred route for pharmaceuticals, accounting for ~90% of the global pharmaceutical market due to its convenience and cost-effectiveness. This study provides a comprehensive scientific and technological analysis of the latest advances in oral dosage forms for colon-targeted drug delivery. Utilizing scientific and patent databases, along with a bibliometric analysis and bibliographical review, we compared the oral dosage forms (technology) with the specific application of the technology (colon delivery) using four search equations. Our findings reveal a gap in the publications and inventions associated with oral dosage forms for colon release compared to oral dosage forms for general applications. While tablets and capsules were found the most used dosage forms, other platforms such as nanoparticles, microparticles, and emulsions have been also explored. Enteric coatings are the most frequently applied excipient to prevent the early drug release in the stomach with pH-triggered systems being the predominant release mechanism. In summary, this review provides a comprehensive analysis of the last advancements and high-impact resources in the development of oral dosage forms for colon-targeted drug delivery, providing insights into the technological maturity of these approaches.

Mathematical models of dissolution testing: Challenges and opportunities toward real-time release testing

Real-time release testing (RTRt) of tablet dissolution can significantly improve manufacturing efficiency along with the adoption of continuous manufacturing in the pharmaceutical industry. To assure product quality without destructive testing, models for RTRt should be sufficiently reliable and robust. Whereas mechanistic models have merits of broader applicability and interpretability, data-driven models have been common approaches due to computational speed. This paper discusses challenges and opportunities in the application of mechanistic models for dissolution testing to enable RTRt of solid dosage. After a comprehensive literature review on mechanistic dissolution models and RTRt, the potential benefits and challenges of mechanistic models are presented. Compared to data-driven models, mechanistic models require less experimental data that can reduce time and cost for RTRt development. However, to enable the implementation of mechanistic models in RTRt, computational time should be short either by using a simple mechanistic model or by applying surrogate models.

Elucidating the effect of salt incorporation in tablets on tablet disintegratability

The disintegration of tablets plays a crucial role in facilitating drug release, and disintegrants are used in tablet formulations to promote the disintegration process. This study aimed to explore and understand the impact of salt incorporation on tablet disintegratability. The study was designed to modulate the microenvironment temperature of tablets through dissolution of salts incorporated in the formulation, with the aim to facilitate tablet disintegration. It was observed that the incorporation of salts generally prolonged tablet disintegration. The impact of incorporating salts on tablet properties was both concentration-dependent and multi-factorial. The observed effect of salts on tablet disintegration was likely influenced by a combination of factors, including different properties of the salts, enhanced solubility of components, the temperature difference between the tablet and the disintegration medium, the expansion of air resulting from increased microenvironment temperature, and the competition for water between salts and disintegrants. These factors collectively contributed to the overall impact of salts on tablet disintegration.