On the Fused Deposition Modelling of Personalised Bio-Scaffolds: Materials, Design, and Manufacturing Aspects

On the Fused Deposition Modelling of Personalised Bio-Scaffolds: Materials, Design, and Manufacturing Aspects

Bone tissue engineering (BTE) is an important field of research, essential in order to heal bone defects or replace impaired tissues and organs. As one of the most used additive manufacturing processes, 3D printing can produce biostructures in the field of tissue engineering for bones, orthopaedic t...

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Bibliographic Details
Published in:Bioengineering (Basel) Vol. 11; no. 8; p. 769
Main Authors: Sousa, Helena Cardoso, Ruben, Rui B, Viana, Júlio C
Format: Journal Article
Language:English
Published: Switzerland MDPI AG 31-07-2024
MDPI
Subjects:
3D printing
additive manufacturing
bio-scaffold
Biocompatibility
biocompatible
Biodegradability
Bioglass
Biological activity
Biological products
Biological properties
Biomedical materials
Biopolymers
Bone biomaterials
Bone healing
bone tissue engineering
Bones
Cell adhesion & migration
Cell differentiation
Composite materials
Construction equipment industry
Deposition
Extracellular matrix
Fractures
Fused deposition modeling
fused deposition modelling
Healing
Load
Low cost
Manufacturing
Mechanical properties
Mesenchymal stem cells
Organs
Orthopedics
Osteoporosis
Permeability
Physical properties
Polycaprolactone
Polylactic acid
Pore size
Porosity
Porous materials
Review
Scaffolds
Stem cells
Surgery
Surgical implants
Three dimensional printing
Tissue engineering
Toxicity
Transplants & implants
additive manufacturing
biodegradable
bone tissue engineering
fused deposition modelling
biocompatible
bio-scaffold
3D printing
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Description
Summary:Bone tissue engineering (BTE) is an important field of research, essential in order to heal bone defects or replace impaired tissues and organs. As one of the most used additive manufacturing processes, 3D printing can produce biostructures in the field of tissue engineering for bones, orthopaedic tissues, and organs. Scaffold manufacturing techniques and suitable materials with final structural, mechanical properties, and the biological response of the implanted biomaterials are an essential part of BTE. In fact, the scaffold is an essential component for tissue engineering where cells can attach, proliferate, and differentiate to develop functional tissue. Fused deposition modelling (FDM) is commonly employed in the 3D printing of tissue-engineering scaffolds. Scaffolds must have a good architecture, considering the porosity, permeability, degradation, and healing capabilities. In fact, the architecture of a scaffold is crucial, influencing not only the physical and mechanical properties but also the cellular behaviours of mesenchymal stem cells. Cells placed on/or within the scaffolds is a standard approach in tissue engineering. For bio-scaffolds, materials that are biocompatible and biodegradable, and can support cell growth are the ones chosen. These include polymers like polylactic acid (PLA), polycaprolactone (PCL), and certain bioglass or composite materials. This work comprehensively integrates aspects related to the optimisation of biocompatible and biodegradable composites with the low cost, simple, and stable FDM technology to successfully prepare the best designed composite porous bone-healing scaffolds. FDM can be used to produce low-cost bone scaffolds, with a suitable porosity and permeability.
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ISSN:2306-5354
2306-5354
DOI:10.3390/bioengineering11080769