High shear wet granulation: Improved understanding of the effects of process variables on granule and tablet properties of a high-dose, high-hydrophobicity API based on quality by design and multivariate analysis approaches
High shear wet granulation (HSWG), as a widely used granulation technology, has been studied extensively. However, for the HSWG of formulations containing hydrophobic components, the influence of process variables on the properties of granules and tablets has not been reported. In the present study, based on a combination of quality by design and multivariate analysis (MVA) approaches, quercetin with high-dose and high-hydrophobicity was used to study the relationship between process variables, granule properties, and tablet properties in HSWG systematically. Control and response variables were determined using risk assessment.
Highlights
A high-dose, high-hydrophobicity API was used for HSWG.
Failure Modes and Effect Analysis was used to evaluate CPPs and CQAs in detail.
Evaluated the influence of process variables on granule and tablet properties.
Combination of QbD and MVA provides a paradigm for HSWG–based product development.
The optimal fitting empirical models established by Box-Behnken design showed that the liquid to solid ratio and impeller speed were the most important factors, which affected all product properties except Carr’s index and yield pressure. Instead, the influence of wet massing time was relatively small (only the effects on yield, granule size, granule hardness, and compression ratio were significant). Then, the process design space was obtained by limiting the related critical quality attributes, which was verified effectively. Scanning electron microscope images showed that smooth granules were produced using higher process parameters, whereas rough and porous granules resulted at lower process parameters.
Furthermore, the MVA results demonstrated that increasing the granule hardness led to an increase in the compression ratio and a decrease in tensile strength of the tablets. Tablet fragility and disintegration time were mainly affected by granule density and bulk density, respectively, and both were negatively correlated. The established research paradigm is not only conducive to the successful development of quercetin products, but also provides valuable guidance for improving HSWG–based product development with such formulation characteristics.
Article information: Binbin Liu, Jiamiao Wang, Qin Zhou, Lijie Zhao, Youjie Wang, Lan Shen, Yi Feng, Ruofei Du, High shear wet granulation: Improved understanding of the effects of process variables on granule and tablet properties of a high-dose, high-hydrophobicity API based on quality by design and multivariate analysis approaches, Advanced Powder Technology, 2021. https://doi.org/10.1016/j.apt.2021.11.021.