INIS
3d printing
10%
additives
100%
amides
100%
amino acids
100%
apatites
10%
applications
100%
body fluids
10%
bonding
10%
bone tissues
10%
carbon 20
10%
comparative evaluations
20%
copolymers
10%
cross-linking
10%
data
10%
deposition
30%
design
10%
ductility
10%
engineering
20%
esters
100%
extrusion
10%
flexibility
10%
glass
10%
hydrogen
10%
interactions
20%
manufacturing
100%
mechanical properties
10%
modeling
30%
molecular weight
20%
performance
20%
polyamides
10%
polyesters
90%
polymerization
10%
polymers
30%
processing
10%
rheology
10%
simulation
10%
solutions
10%
stability
10%
structure functions
10%
tissues
10%
toxicity
10%
transition temperature
10%
Keyphrases
3D Printing
11%
Active Solutions
11%
Additive Manufacturing
100%
Additive Manufacturing Application
22%
Amide Bond
11%
Amide Structure
11%
Amino Acids
11%
Amino Acids-based
100%
Biocompatibility
11%
Biodegradability
11%
Biomedical Applications
100%
Bone Apatite
11%
Bone Tissue Engineering
11%
Copolymer
11%
Crystallinity
11%
Degradability
11%
Ductility
11%
End-capping
11%
Fused Deposition Modeling
33%
Glycolide
11%
High Thermal Stability
11%
Hydrogen Bond Network
11%
Lactide
11%
Low Cytotoxicity
11%
Low Glass Transition Temperature
11%
Manufacturing Methods
11%
Mechanical Properties
11%
Melt Extrusion
11%
Polyamide
11%
Polyester
11%
Polyesteramide
100%
Polymer Interaction
11%
Polymer-cell Interaction
11%
Printing Performance
11%
Process Characteristics
11%
Processing Requirements
11%
Reactive Functional Groups
11%
Rheology Study
11%
Semi-crystalline
11%
Simulated Body Fluid
11%
Solution Polycondensation
11%
Steadiness
11%
Structure Function
11%
Thermomechanical Properties
11%
Tissue Engineering
11%
Tissue Engineering Applications
11%
Material Science
Amino Acids
100%
Body Fluid
11%
Copolymer
11%
Fused Filament Fabrication
33%
Glass Transition Temperature
11%
Hydrogen Bonding
11%
Polyamide
11%
Polycondensation
11%
Polyester
100%
Polymerization
11%
Rheology
11%
Thermal Stability
11%
Thermomechanical Property
11%
Three Dimensional Printing
100%