Growth kinetics and mechanism of wet granulation in a laboratory-scale high shear mixer: Effect of initial polydispersity of particle size

Abstract

The effect of initial polydispersity of particle size (unimodal versus bimodal distribution) and binder characteristics on the growth kinetics and mechanism of wet granulation was studied. Wet granulation of pharmaceutical powders with initial bimodal particle size distribution (PSD) presented growth kinetics consisting of two stages: fast growth followed by slow growth. The fast stage is controlled by the amount of binder and high probability of coalescence due to the collisions of small and large particles. The second stage is characterized by slow agglomeration of powder mixtures with water content 13.6% v/w, and slow breakage of powder mixtures with water content of 9.9% and 11.7% v/w. The wet granulation of powders with initial unimodal PSD exhibited slow growth kinetics consisting of one stage, since similar particle sizes do not promote agglomeration. The experimental results were better described by a population balance equation using a coalescence kernel that favors growth rate by collision between small and large particles. In general, the probability of a successful collision increased with higher size difference between particles, smaller particle size, and higher binder content.