3D printing of porous hydroxyapatite scaffolds intended for use in bone tissue engineering applications

Keyphrases

• Compressive Strength 100%
• Polyvinyl Alcohol 100%
• Tissue Engineering Applications 100%
• 3D Printing 100%
• Bone Tissue Engineering 100%
• Porous Hydroxyapatite Scaffold 100%
• Hydroxyapatite 66%
• Strength Testing 66%
• Powder Particles 33%
• Fourier Transform Infrared Spectroscopy (FT-IR) 33%
• Scanning Electron Microscopy 33%
• Microstructure 33%
• Characterization Techniques 33%
• Surface Roughness 33%
• Computed Tomography 33%
• Porosity 33%
• Mechanical Stability 33%
• Systematic Description 33%
• Precursor Material 33%
• Multi-connectivity 33%
• Osteoconduction 33%
• Green Parts 33%
• Flowability 33%
• Composite Powder 33%
• Interlayer Bonding 33%
• Osseointegration 33%
• Anisotropic Behavior 33%
• 3D Scaffold 33%
• Bone Scaffold 33%
• Ultimate Compressive Strength 33%
• Vacuum Oven 33%
• Designed Porosity 33%
• Flow Test 33%
• Alcohol-thermal Method 33%
• Funnel Flow 33%
• Thermal Degradation Products 33%

Engineering

• Compression Strength 100%
• Compressive Strength 100%
• Porosity 100%
• Three Dimensional Printing 100%
• Bone Tissue Engineering Application 100%
• Printed Scaffold 50%
• Powder Particle 25%
• Thermal Degradation 25%
• FTIR Spectroscopy 25%
• Sintering 25%
• Mechanical Stability 25%
• Precursor Material 25%
• Green Part 25%
• Degradation Product 25%
• Composite Powder 25%
• Interconnectivity 25%
• Anisotropic Behavior 25%
• Fabricated Scaffold 25%
• Interlayer Bond 25%

Material Science

• Compressive Strength 100%
• Three Dimensional Printing 100%
• Poly Vinyl Alcohol 75%
• Thermal Degradation 25%
• Fourier Transform Infrared Spectroscopy 25%
• Scanning Electron Microscopy 25%
• Sintering 25%
• Surface Roughness 25%
• Tomography 25%
• Mechanical Stability 25%
• Flowability 25%
• Composite Material 25%