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. 2024 Oct 22;25(8):251.
doi: 10.1208/s12249-024-02972-x.

Effects of Glass Bead Size on Dissolution Profiles in Flow-through Dissolution Systems (USP 4)

Hiroyuki Yoshida  1 Keita Teruya  2 Yasuhiro Abe  3 Takayuki Furuishi  2   4 Kaori Fukuzawa  2   5 Etsuo Yonemochi  2   6 Ken-Ichi Izutsu  3   6
Affiliations

Effects of Glass Bead Size on Dissolution Profiles in Flow-through Dissolution Systems (USP 4)

Hiroyuki Yoshida et al. AAPS PharmSciTech. .

Abstract

The effects of glass bead size in the conical space of flow-through cells on the dissolution profiles were investigated in a USP apparatus 4. Dissolution tests of disintegrating and non-disintegrating tablets in flow-through dissolution systems were performed using semi-high precision glass beads with diameters ranging from 0.5 mm to 1.5 mm. Computational fluid dynamics (CFD) was used to evaluate the effect of shear stress from the dissolution media flow. The use of smaller glass beads in a larger cell resulted in a faster dissolution of the model formulations under certain test conditions. The effect on the dissolution was highly dependent on the size of the beads in the top layer, including those in contact with the tablets. The absence of a bead-size effect on the dissolution of an orodispersible tablet in a small cell can be explained by the floating fragments during the test. CFD analysis showed that smaller bead diameters led to greater shear stress on the tablet, which was correlated with the dissolution rate. Hence, fluid flow through the narrow gaps between the small beads generated strong local flows, causing shear stress. The size of the glass beads used in flow-through cells affects the dissolution rate of tablets by altering the shear stress on the tablets in certain cases (e.g., direct deposition of the formulation on glass beads, large cells, and very low flow rates). Thus, glass bead size must be considered for a robust dissolution test in a flow-through cell system.

Keywords: dissolution testing; flow-through cell system; glass bead size; hydrodynamics; shear stress.

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