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» Articles » PMID: 32957226

On the Permeability of TPMS Scaffolds

Overview
Journal J Mech Behav Biomed Mater
Publisher Elsevier
Specialty Biomedical Engineering
Date 2020 Sep 22
PMID 32957226
Citations 23
Authors
Jorge Santos
Tiago Pires
Barbara P Gouveia
Andre P G Castro
Paulo R Fernandes
Affiliations
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Abstract

This study presents an experimental evaluation of permeability of triply periodic minimal surfaces (TPMS). Permeability is widely used to characterize scaffolds for Tissue Engineering (TE) applications as it gives information about the structure porosity, pore size, tortuosity and pore interconnectivity which have an important impact in cell seeding and proliferation. Three different TPMS structures were used: Schwartz Diamond (SD), Gyroid (SG) and Schwartz Primitive (SP), in four different porosity levels (50, 60, 70 and 80%). Overall, the SG scaffold type was determined to be the most permeable one while the SD was the least permeable. Furthermore, the presence of microscopic inertial pressure losses was verified and the Forchheimer's law proved to be a good mathematical tool as a Darcy's law expansion for the calculation of the structure's permeability while the weak-inertia regime was hard to detect or quantify.

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