Development and characterization of a PLGA-HA composite material to fabricate 3D-printed scaffolds for bone tissue engineering

Additive manufacturing is a rising field in bone tissue engineering. Additive fabrication offers reproducibility, high precision and rapid manufacture of custom patient-specific scaffolds. The development of appropriate composite materials for biomedical applications is critical to reach clinical ap...

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Bibliographic Details
Published in:Materials Science & Engineering C 2021-01, Vol.118, p.111334-111334, Article 111334
Main Authors: Babilotte, Joanna, Martin, Benoit, Guduric, Vera, Bareille, Reine, Agniel, Rémy, Roques, Samantha, Héroguez, Valérie, Dussauze, Marc, Gaudon, Manuel, Le Nihouannen, Damien, Catros, Sylvain
Format: Article
Language:English
Subjects:
Additive manufacturing
Animals
Biocompatibility
Biocompatible Materials
Biodegradation
Biomaterials
Biomedical materials
Bone and Bones
Bone tissue engineering
Bones
Cell proliferation
Cell viability
Chemical Sciences
Composite
Composite materials
Durapatite
Fabrication
Fused deposition modeling
Humans
Hydroxyapatite
Inflammation
Material chemistry
Materials science
Mechanical loading
Nanoparticles
Physicochemical properties
Polylactide-co-glycolide
Polymer
Printing, Three-Dimensional
Rapid manufacturing
Rats
Reproducibility of Results
Scaffolds
Stress concentration
Surgical implants
Three dimensional composites
Three dimensional models
Three dimensional printing
Tissue Engineering
Tissue Scaffolds
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Summary:Additive manufacturing is a rising field in bone tissue engineering. Additive fabrication offers reproducibility, high precision and rapid manufacture of custom patient-specific scaffolds. The development of appropriate composite materials for biomedical applications is critical to reach clinical application of these novel biomaterials. In this work, medical grade poly(lactic-co-glycolic) acid (PLGA) was mixed with hydroxyapatite nanoparticles (nHA) to fabricate 3D porous scaffolds by Fused Deposition Modeling. We have first confirmed that the composite material could be printed in a reproductive manner. Physical characterization demonstrated a low degradation of the material during manufacturing steps and an expected loading and homogeneous distribution of nHA. In vitro biodegradation of the scaffolds showed modifications of morphological and physicochemical properties over time. The composite scaffolds were biocompatible and high cell viability was observed in vitro, as well as a maintain of cell proliferation. As expected, the addition of nHA displayed a positive impact on osteodifferentiation in vitro. Furthermore, a limited inflammatory reaction was observed after subcutaneous implantation of the materials in the rat. Overall, this study suggests that this composite material is suitable for bone tissue engineering applications. •Manufacturing steps have a minor impact on material properties•Materials provide a biocompatible and osteopromotive support over two cell types•No major signals of inflammation observed, outlining material biocompatibility
ISSN:0928-4931
1873-0191
DOI:10.1016/j.msec.2020.111334