TY - JOUR
T1 - Effect of particle size and deformation behaviour on water ingress into tablets
AU - Skelbaek-Pedersen, Anne Linnet
AU - Al-Sharabi, Mohammed
AU - Vilhelmsen, Thomas Kvistgaard
AU - Rantanen, Jukka
AU - Zeitler, J. Axel
PY - 2020
Y1 - 2020
N2 - Drug release performance of tablets is often highly dependent on disintegration, and water ingress is typically the rate-limiting step of the disintegration process. Water ingress into tablets is known to be highly influenced by the microstructure of the tablet, particularly tablet porosity. Initial particle size distribution of the formulation and the predominant powder deformation behaviour during compression are expected to impact such microstructure, making both factors important to investigate in relation to water ingress into tablets. Two size fractions (<125 and 355-500 mu m) of plastically deforming microcrystalline cellulose (MCC) and fragmenting dicalcium phosphate (DCP) were compressed into tablets with porosities ranging from 5 to 30% (with 5% increments). The total porosity of the tablets was measured using terahertz time-domain spectroscopy and liquid transport into these tablets was quantified using a flow cell coupled to terahertz pulsed imaging. It was found that tablets compressed from large MCC particles resulted in slower water ingress compared to tablets prepared from small MCC particles. In contrast, no difference in liquid transport kinetics was observed for tablets prepared across both size fractions of DCP particles. These results highlight the complex interplay between material characteristics, the process induced microstructure, and the liquid transport process that ultimately determines the drug release performance of the tablets.
AB - Drug release performance of tablets is often highly dependent on disintegration, and water ingress is typically the rate-limiting step of the disintegration process. Water ingress into tablets is known to be highly influenced by the microstructure of the tablet, particularly tablet porosity. Initial particle size distribution of the formulation and the predominant powder deformation behaviour during compression are expected to impact such microstructure, making both factors important to investigate in relation to water ingress into tablets. Two size fractions (<125 and 355-500 mu m) of plastically deforming microcrystalline cellulose (MCC) and fragmenting dicalcium phosphate (DCP) were compressed into tablets with porosities ranging from 5 to 30% (with 5% increments). The total porosity of the tablets was measured using terahertz time-domain spectroscopy and liquid transport into these tablets was quantified using a flow cell coupled to terahertz pulsed imaging. It was found that tablets compressed from large MCC particles resulted in slower water ingress compared to tablets prepared from small MCC particles. In contrast, no difference in liquid transport kinetics was observed for tablets prepared across both size fractions of DCP particles. These results highlight the complex interplay between material characteristics, the process induced microstructure, and the liquid transport process that ultimately determines the drug release performance of the tablets.
KW - Tableting
KW - Deformation behaviour
KW - Water ingress
KW - Fragmentation
KW - Particle size
KW - MICROCRYSTALLINE CELLULOSE
KW - PHARMACEUTICAL TABLETS
KW - POWDER COMPACTS
KW - DISINTEGRATION
KW - TERAHERTZ
KW - POROSITY
KW - MECHANISM
KW - STRENGTH
U2 - 10.1016/j.ijpharm.2020.119645
DO - 10.1016/j.ijpharm.2020.119645
M3 - Journal article
C2 - 32679259
VL - 587
JO - International Journal of Pharmaceutics
JF - International Journal of Pharmaceutics
SN - 0378-5173
M1 - 119645
ER -