Selective laser melted Ti6Al4V split-P TPMS lattices for bone tissue engineering

Keyphrases

• Ti-6Al-4V (Ti64) 100%
• Bone Tissue Engineering 100%
• Relative Density 100%
• Triply Periodic Minimal Surface 100%
• Selective Laser Melting 100%
• Elastic Modulus 66%
• Mechanical Properties 66%
• Cell Morphology 66%
• Load Capacity 66%
• Plateau Stress 66%
• Finite Element Analysis 33%
• Scanning Electron Microscopy 33%
• Cortical Bone 33%
• Trabecular Bone 33%
• Yield Strength 33%
• Power Law 33%
• Yield Stress 33%
• Mechanical Response 33%
• Stress Response 33%
• Stress-strain 33%
• Energy Absorption 33%
• Failure Mechanism 33%
• High Surface Area 33%
• Elastoplastic Behavior 33%
• Lattice Structure 33%
• Quasi-static 33%
• Surface-to-volume Ratio 33%
• Deformation Behavior 33%
• Lattice Type 33%
• Isotropy 33%
• Static Mechanical 33%
• Ultimate Strength 33%
• Mechanical Anisotropy 33%
• Stiffness Tensor 33%
• Load Bearing Application 33%
• Manufacturability 33%
• Triply Periodic Minimal Surface Structures 33%
• Bone Implants 33%
• Equivalent Stiffness 33%
• Energy Absorption Capacity 33%
• Stretch-dominated 33%
• Gibson-Ashby 33%

Engineering

• Bone Tissue Engineering 100%
• Triply Periodic Minimal Surface 100%
• Cell Morphology 66%
• Bearing Capacity 66%
• Modulus of Elasticity 66%
• Yield Point 66%
• Stiffness Tensor 33%
• Mechanical Response 33%
• Deformation Behavior 33%
• Failure Mechanism 33%
• High Surface Area 33%
• Stress-Strain Relations 33%
• Volume Ratio 33%
• Ultimate Strength 33%
• Bearing Application 33%
• Manufacturability 33%
• Bone Implant 33%
• Equivalent Stiffness 33%
• Energy Absorption Capacity 33%
• Selective Laser Melting 33%
• Finite Element Analysis 33%
• Spatial Distribution 33%
• Energy Absorption 33%