Combining multi-scale 3D printing technologies to engineer reinforced hydrogel-ceramic interfaces

Keyphrases

• Cartilage 100%
• Melt Electrowriting 100%
• Fiber-reinforced Hydrogel 100%
• 3D Printing Technology 100%
• Multiscale 3D Printing 100%
• Ceramic Interface 100%
• Chondral 66%
• Cartilage Matrix 66%
• Tissue Interface 66%
• Articular Cartilage 33%
• Reinforced 33%
• Regenerative Medicine 33%
• Polycaprolactone 33%
• Regeneration 33%
• Multi-material 33%
• Biofabrication 33%
• Connective Tissue 33%
• Structural Stability 33%
• Osteochondral Defect 33%
• Matrix Deposition 33%
• Surgical Implantation 33%
• Physiological Temperature 33%
• Microarchitecture 33%
• Osteogenesis 33%
• Self-crosslinking 33%
• Poloxamer 33%
• Extrusion-based 3D Printing 33%
• Composite Construct 33%
• Mechanical Reinforcement 33%
• Osteochondral Plug 33%
• Gelatin-based Hydrogel 33%
• Chondroprogenitor Cells 33%
• Tricalcium Phosphate 33%
• Advanced Composites 33%
• Adhesion Strength 33%
• Bone Support 33%
• Fiber Architecture 33%
• Biomorphic Ceramics 33%
• Setting Reaction 33%
• Polymeric Microfibers 33%
• Multi-material 3D Printing 33%
• Temperature Setting 33%
• Musculoskeletal Tissue 33%
• Nano-hydroxyapatite (n-HA) 33%
• Compressive Properties 33%
• Promising Strategies 33%
• Hydrogel Interfaces 33%
• Ceramic Ink 33%

Engineering

• Hydrogel 100%
• Multiscale 100%
• Ceramic Interface 100%
• Three Dimensional Printing 100%
• Engineering 40%
• Regenerative Medicine 20%
• Biofabrication 20%
• Microscale 20%
• Mechanical Reinforcement 20%
• Printing Approach 20%
• Biomimetics 20%
• Structural Stability 20%
• Osteochondral Defect 20%
• Setting Reaction 20%
• Cartilage Interface 20%
• Advanced Composite 20%
• Microfiber 20%

Material Science

• Hydrogel 100%
• Three Dimensional Printing 100%
• Melt Electrowriting 60%
• Composite Material 40%
• Bond Strength (Materials) 20%
• Bioceramic 20%