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Utilising micron scale 3D printed morphologies for particle adhesion reduction

Georgina Marsh Orcid Logo, Matt J. Bunker, Morgan R. Alexander, Ricky D. Wildman, Mark Nicholas, Clive J. Roberts

Powder Technology, Volume: 404, Start page: 117418

Swansea University Author: Georgina Marsh Orcid Logo

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DOI (Published version): 10.1016/j.powtec.2022.117418

Abstract

In the pharmaceutical industry, the ability to improve the understanding of the effect of surface roughness on interparticulate interactions is critical. Dry powder inhalers often possess poor efficiency, as the powder formulations are inherently adhesive and cohesive due to their size. The complex...

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Published in: Powder Technology
ISSN: 0032-5910 1873-328X
Published: Elsevier BV 2022
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URI: https://cronfa.swan.ac.uk/Record/cronfa64800
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Abstract: In the pharmaceutical industry, the ability to improve the understanding of the effect of surface roughness on interparticulate interactions is critical. Dry powder inhalers often possess poor efficiency, as the powder formulations are inherently adhesive and cohesive due to their size. The complex interplay of factors that affect interparticulate interactions, means it has been difficult to isolate the effect of surface morphology. Using two photon polymerisation, this study shows the fabrication of bespoke sub-micron geometric structures, with a consistent surface chemistry. These are used to investigate the effect of surface morphologies on particle adhesion by utilising AFM force-volume mapping, to model spheres and carrier particles. This demonstrates the significant effect varying surface morphology can have on particle-surface adhesion. This approach allows for the first time an in-depth examination of the local variation effect of surface features on particle adhesion and may facilitate the design and optimisation of powder processes.
Keywords: Two photon polymerisation, AFM, Particle-surface adhesion, Surface roughness
College: Faculty of Medicine, Health and Life Sciences
Funders: AstraZeneca and the EPSRC (EP/L01646X) for funding is gratefully acknowledged.
Start Page: 117418

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