Additive Manufactured Scaffolds for Bone Tissue Engineering: Physical Characterization of Thermoplastic Composites with Functional Fillers: Physical Characterization of Thermoplastic Composites with Functional Fillers

Ravi Sinha, Alberto Sanchez, Maria Camara-Torres, Iñigo Calderon Uriszar-Aldaca, Andrea Roberto Calore, Jules Harings, Ambra Gambardella, Lucia Ciccarelli, Veronica Vanzanella, Michele Sisani, Marco Scatto, Rune Wendelbo, Sergio Perez, Sara Villanueva, Amaia Matanza, Alessandro Patelli, Nino Grizzuti, Carlos Mota, Lorenzo Moroni

Producción científica: Contribución a una revistaArtículorevisión exhaustiva

21 Citas (Scopus)
1 Descargas (Pure)

Resumen

Thermoplastic polymer–filler composites are excellent materials for bone tissue engineering (TE) scaffolds, combining the functionality of fillers with suitable load-bearing ability, biodegradability, and additive manufacturing (AM) compatibility of the polymer. Two key determinants of their utility are their rheological behavior in the molten state, determining AM processability and their mechanical load-bearing properties. We report here the characterization of both these physical properties for four bone TE relevant composite formulations with poly(ethylene oxide terephthalate)/poly(butylene terephthalate (PEOT/PBT) as a base polymer, which is often used to fabricate TE scaffolds. The fillers used were reduced graphene oxide (rGO), hydroxyapatite (HA), gentamicin intercalated in zirconium phosphate (ZrP-GTM) and ciprofloxacin intercalated in MgAl layered double hydroxide (MgAl-CFX). The rheological assessment showed that generally the viscous behavior dominated the elastic behavior (G″ > G′) for the studied composites, at empirically determined extrusion temperatures. Coupled rheological–thermal characterization of ZrP-GTM and HA composites showed that the fillers increased the solidification temperatures of the polymer melts during cooling. Both these findings have implications for the required extrusion temperatures and bonding between layers. Mechanical tests showed that the fillers generally not only made the polymer stiffer but more brittle in proportion to the filler fractions. Furthermore, the elastic moduli of scaffolds did not directly correlate with the corresponding bulk material properties, implying composite-specific AM processing effects on the mechanical properties. Finally, we show computational models to predict multimaterial scaffold elastic moduli using measured single material scaffold and bulk moduli. The reported characterizations are essential for assessing the AM processability and ultimately the suitability of the manufactured scaffolds for the envisioned bone regeneration application.
Idioma originalInglés
Páginas (desde-hasta)3788-3799
Número de páginas12
PublicaciónACS Applied Polymer Materials
Volumen3
N.º8
DOI
EstadoPublicada - 13 ago 2021

Palabras clave

  • Composites
  • Fillers
  • Rheology
  • Mechanical properties
  • Additive manufacturing
  • Modeling

Project and Funding Information

  • Project ID
  • info:eu-repo/grantAgreement/EC/H2020/685825/EU/Functionally graded Additive Manufacturing scaffolds by hybrid manufacturing/FAST
  • Funding Info
  • The work was supported by a Horizon 2020 Research and Innovation Programme grant from the European Union, called the FAST project (grant no. 685825, project website: http:// project-fast.eu). The authors acknowledge the support of the FAST project consortium for the various aspects of this work

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