Optimization of Electrospun Bilayer Vascular Grafts through Assessment of the Mechanical Properties of Monolayers

Keyphrases

• Mechanical Properties 100%
• Polylactic Acid 100%
• Electrospun 100%
• Polycaprolactone 100%
• Bilayer Vascular Graft 100%
• Poly(L-lactide-co-ε-caprolactone) 80%
• Copolymer 60%
• Tensile Strength 60%
• Burst Strength 60%
• Blending Ratio 60%
• Fiber Orientation 40%
• Graft Design 40%
• Biocompatibility 20%
• Electrospinning Technique 20%
• Biological Properties 20%
• High Tensile Strength 20%
• Biodegradability 20%
• SEM Analysis 20%
• Fiber Diameter 20%
• High Strength 20%
• High Elongation 20%
• Diameter Measurement 20%
• Inner Layer 20%
• Material Selection 20%
• Physiological Condition 20%
• Randomly Distributed 20%
• Wall Thickness 20%
• Design Selection 20%
• Bilayer Scaffold 20%
• Oriented Fibers 20%
• Vascular Graft 20%
• Small-diameter Vascular Grafts 20%
• Burst Pressure 20%
• Strength Test 20%
• Compliance Level 20%
• Radial Fiber 20%
• Blend Fiber 20%
• Fiber Alignment 20%
• Elongation Value 20%
• Polycaprolactone Scaffold 20%
• Blended Approach 20%
• Approach Orientation 20%
• Blend Scaffolds 20%
• Tubular Specimen 20%
• Compliance Test 20%
• Hemodynamic Conditions 20%
• Random Fiber Distribution 20%

Engineering

• Electrospun 100%
• Ultimate Tensile Strength 100%
• Grafts 100%
• Caprolactone 100%
• Monolayers 100%
• Fiber Orientation 50%
• Electrospinning Technique 25%
• Fiber Diameter 25%
• Outer Layer 25%
• Burst Pressure 25%
• Diameter Vascular Graft 25%
• Fiber Alignment 25%
• Design Selection 25%
• Acceptance Tests 25%
• Biological Property 25%

Material Science

• Polylactide 100%
• Monolayers 100%
• Ultimate Tensile Strength 80%
• Copolymer 60%
• Fiber Reinforced Material 40%
• Scanning Electron Microscopy 20%
• Biocompatibility 20%
• Electrospinning 20%