Highly Porous 3D Printed Tantalum Scaffolds Have Better Biomechanical and Microstructural Properties than Titanium Scaffolds

Highly Porous 3D Printed Tantalum Scaffolds Have Better Biomechanical and Microstructural Properties than Titanium Scaffolds

Objective. To test the biomechanical properties of 3D printed tantalum and titanium porous scaffolds. Methods. Four types of tantalum and titanium scaffolds with four alternative pore diameters, #1 (1000-700 μm), #2 (700-1000 μm), #3 (500-800 μm), and #4 (800-500 μm), were molded by selective laser...

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Veröffentlicht in:BioMed research international 2021, Vol.2021, p.2899043-8, Article 2899043
Hauptverfasser: Fan, Huaquan, Deng, Shu, Tang, Wentao, Muheremu, Aikeremujiang, Wu, Xianzhe, He, Peng, Tan, Caihua, Wang, Guohua, Tang, Jianzhong, Guo, Kaixuan, Yang, Liu, Wang, Fuyou
Format: Artikel
Sprache:eng
Schlagworte:
3-D printers
3D printing
Additive manufacturing
Animals
Biocompatibility
Biomechanical Phenomena
Biomechanics
Biomedical materials
Biotechnology & Applied Microbiology
Bone surgery
Comparative analysis
Compression
Compression tests
Deformation
Engineering
Extracellular matrix
Fractures
Joint replacement surgery
Laser beam melting
Lasers
Life Sciences & Biomedicine
Materials
Materials research
Mechanical properties
Medicine, Research & Experimental
Modulus of elasticity
Orthopedic implants
Orthopedics
Porosity
Powder metallurgy
Printing, Three-Dimensional
Production processes
Research & Experimental Medicine
Scaffolds
Science & Technology
Stress, Mechanical
Stress-strain curves
Swine
Tantalum
Tantalum - chemistry
Three dimensional printing
Tissue Scaffolds - chemistry
Titanium
Titanium - chemistry
Titanium alloys
Transplants & implants
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Zusammenfassung:Objective. To test the biomechanical properties of 3D printed tantalum and titanium porous scaffolds. Methods. Four types of tantalum and titanium scaffolds with four alternative pore diameters, #1 (1000-700 μm), #2 (700-1000 μm), #3 (500-800 μm), and #4 (800-500 μm), were molded by selective laser melting technique, and the scaffolds were tested by scanning electronic microscope, uniaxial-compression tests, and Young’s modulus tests; they were compared with same size pig femoral bone scaffolds. Results. Under uniaxial-compression tests, equivalent stress of tantalum scaffold was 411±1.43 MPa, which was significantly larger than the titanium scaffolds (P
ISSN:2314-6133
2314-6141
DOI:10.1155/2021/2899043