Litcius/Paper detail

Design Space Approach for the Optimization of Green Fluidized Bed Granulation Process in the Granulation of a Poorly Water-Soluble Fenofibrate Using Design of Experiment

Mohamed H. Fayed, Ahmed Alalaiwe, Ziyad S. Almalki, Doaa A. Helal

2022Pharmaceutics10 citationsDOIOpen Access PDF

Abstract

In the pharmaceutical industry, the systematic optimization of process variables using a quality-by-design (QbD) approach is highly precise, economic and ensures product quality. The current research presents the implementation of a design-of-experiment (DoE) driven QbD approach for the optimization of key process variables of the green fluidized bed granulation (GFBG) process. A 32 full-factorial design was performed to explore the effect of water amount (X1; 1–6% w/w) and spray rate (X2; 2–8 g/min) as key process variables on critical quality attributes (CQAs) of granules and tablets. Regression analysis have demonstrated that changing the levels of X1 and X2 significantly affect (p ≤ 0.05) the CQAs of granules and tablets. Particularly, X1 was found to have the pronounced effect on the CQAs. The GFBG process was optimized, and a design space (DS) was built using numerical optimization. It was found that X1 and X2 at high (5.69% w/w) and low (2 g/min) levels, respectively, demonstrated the optimum operating conditions. By optimizing X1 and X2, GFBG could enhance the disintegration and dissolution of tablets containing a poorly water-soluble drug. The prediction error values of dependent responses were less than 5% that confirm validity, robustness and accuracy of the generated DS in optimization of GFBG.

Topics & Concepts

Critical quality attributesQuality by DesignGranulationDesign of experimentsFactorial experimentFluidized bedProcess engineeringResponse surface methodologyProcess optimizationInteractionMathematicsComputer scienceParticle sizeChemistryMaterials scienceStatisticsEngineeringChemical engineeringComposite materialOrganic chemistryDrug Solubulity and Delivery SystemsProtein purification and stabilityGranular flow and fluidized beds