Keyphrases
Tissue Engineering
100%
Polyhydroxyalkanoates
100%
Biopolymers
100%
3D Printing
100%
Degradable Scaffold
100%
Poly(3-hydroxybutyrate-co-3-hydroxyvalerate)
100%
Enzymatically Degradable
100%
Human Dermal Fibroblasts
42%
P34HB
42%
Tunable Degradation
28%
Degradation Time
28%
Scaffold Mechanical Properties
16%
Printing Conditions
16%
Selective Laser Sintering
16%
Inorganic Filler
16%
In Vivo Conditions
16%
Smart Materials
16%
Thermoplasticity
16%
Biological Properties
16%
Selective Laser Melting
16%
Electrospinning
16%
High Tensile Strength
16%
Functional Materials
16%
Polyester
16%
Synthetic Polymers
16%
Nanoparticles
16%
Regenerative Medicine
16%
Print Resolution
16%
Biodegradable Polymers
16%
Biofabrication
16%
Fused Deposition Modeling
16%
Printing Techniques
16%
Melt Electrowriting
16%
Melt Electrospinning
16%
Biomedical Applications
16%
Environmentally Friendly
16%
Biocompatibility
16%
On Demand
16%
Bacterial Strains
16%
Natural Polymers
16%
High Thermal Stability
14%
Time Surface
14%
Cell Adherence
14%
Proliferation Rate
14%
Scaffold Surface
14%
Enzymes Solution
14%
Viability Rates
14%
Printing Materials
14%
Scaffold Fabrication
14%
Cell Spreading
14%
Material Science
Three Dimensional Printing
100%
Biopolymer
100%
Fibroblast
75%
Electrospinning
66%
Nanoparticle
33%
Ultimate Tensile Strength
33%
Selective Laser Sintering
33%
Functional Material
33%
Polyester
33%
Synthetic Polymer
33%
Thermoplasticity
33%
Melt Electrowriting
33%
Natural Polymer
33%
Fused Filament Fabrication
33%
Smart Material
33%
Dilution
25%
Thermal Stability
25%
Engineering
Three Dimensional Printing
100%
Tissue Regeneration
100%
Degradation Time
66%
Enzymatic Degradation
66%
Limited Number
33%
Dilution
33%
Scaffold Surface
33%
Scaffold Fabrication
33%
Biological Property
16%
