Experimental study of wet granulation in fluidized bed: Impact of the binder properties on the granule morphology

Abstract

In this work, the effect of the physicochemical properties of aqueous hydroxypropyl-cellulose (HPC) binder solutions and different pharmaceutical excipients (mannitol and anhydrous CaHPO 4) on the agglomeration kinetics and granule properties were investigated. First, a particle size distribution (PSD) analysis together with a detailed analysis of morphological properties of the excipient particles were performed. Second, the viscosity, density, surface tension and size of the spray droplets of binder solutions with different HPC concentrations were determined and wetting characteristics of the binders on the excipients were measured. Third, several fluid bed wet granulation experiments were conducted for pure excipients and their blends with binder solution of different HPC concentrations in a pilot plant Wurster granulator. The observed granule growth for different binder concentrations was a strong function of the binder concentration and the excipient solubility. For mannitol, a significant “coating” period followed by a slow granule growth was observed for the case with the diluted 5% binder. The “coating” period was significantly shorter for the 10% HPC binder and did not exist for the 15% HPC for which immediate and fast granule growth was observed. For anhydrous CaHPO 4 (trademark A-TAB), no growth was observed for the 10% HPC binder and a long coating period followed by fast granule growth was observed for the 15% HPC. Simple physically based criteria were also evaluated, which employ the morphological properties of excipients (size and surface roughness) together with physical properties of the used binder for prediction of the coating versus agglomeration regime at given flow conditions (collision velocity). As expected, a preferential coalescence and growth of the mannitol granules from the blend of mannitol + A-TAB was observed. Finally, the mechanical and morphological properties of the produced granules were measured and correlated to the HPC concentration of the binder used in the experiments. A clear correlation between the granule porosity (evaluated by X-ray tomography) and the binder concentration was found for the mannitol granules.