Generational biodegradable and regenerative polyphosphazene polymers and their blends with poly (lactic-co-glycolic acid)

Keyphrases

• Polyphosphazene 100%
• Poly(lactic-co-glycolic acid) 100%
• Degradable 33%
• Biomaterials 25%
• Regenerative Engineering 25%
• Phosphorus Atoms 16%
• Dipeptide 16%
• Degradation Products 16%
• Glucosyl 16%
• Small Molecules 8%
• Materials Science 8%
• Hydrolysis 8%
• Polymeric Materials 8%
• Hydrogen Bonds (H-bonds) 8%
• Regeneration 8%
• Design Strategy 8%
• Lactate 8%
• Clinical Translation 8%
• Nitrogen Atom 8%
• Miscibility 8%
• Degradation Behavior 8%
• Pore-forming 8%
• Polymer Backbone 8%
• Bioactivity 8%
• Innovative Approach 8%
• Third Generation 8%
• Fundamental Change 8%
• Imidazole 8%
• Material Engineering 8%
• Multiple Tissues 8%
• Tissue Regeneration 8%
• Design Considerations 8%
• Multidisciplinary Approach 8%
• Specific Needs 8%
• Amino Acid Ester 8%
• Blending System 8%
• Advanced Materials 8%
• Developmental Biology 8%
• Tunable Properties 8%
• Property Optimization 8%
• Product Properties 8%
• Interconnected Porous Structure 8%
• Degradable Polymers 8%
• Partially Miscible 8%
• Acidic Degradation 8%
• Forming Property 8%
• Glycolate 8%
• Stem Cell Science 8%

Material Science

• Biomaterial 100%
• Polylactide 100%
• Dipeptide 50%
• Polymer 25%
• Hydrogen Bonding 25%
• Amino Acids 25%
• Stem Cell 25%
• Advanced Material 25%
• Materials Engineering 25%
• Enzymatic Hydrolysis 25%

Engineering

• Polyphosphazenes 100%
• Engineering 25%
• Degradation Product 16%
• Substituent 8%
• Polymer Backbone 8%
• Design Consideration 8%
• Amino Acid Ester 8%
• Porous Structure 8%
• Active Side 8%
• Tissue Regeneration 8%
• Bioactivity 8%
• Nitrogen Atom 8%
• Stem Cell Engineering 8%