OBJECTIVE: To develop a small-caliber vascular grafts and study its morphologies, mechanical properties and biocompatibility. METHODS: The effects of electrospinning conditions on the microstructure and porosity of the resulting scaffolds were investigated for preparation of a small-caliber (4 mm) polyurethane vascular grafts with optimum microstructures and mechanical properties. The mechanical properties and biocompatibility of the prepared grafts were evaluated. RESULTS: The polyurethane vascular grafts showed a three-dimensional reticular structure consisting of nanofibers, with an average porosity of (51.48∓4.47)% and tensile strength of 5.85 ∓ 0.62 MPa. The grafts provided a better long-term support than e-PTFE graft for endothelial cell growth and endothelialization. CONCLUSION: The polyurethane vascular prosthesis possessed favorable microstructures, excellent mechanical properties and good biocompatibility for potential clinical application.
OBJECTIVE: To develop a small-caliber vascular grafts and study its morphologies, mechanical properties and biocompatibility. METHODS: The effects of electrospinning conditions on the microstructure and porosity of the resulting scaffolds were investigated for preparation of a small-caliber (4 mm) polyurethane vascular grafts with optimum microstructures and mechanical properties. The mechanical properties and biocompatibility of the prepared grafts were evaluated. RESULTS: The polyurethane vascular grafts showed a three-dimensional reticular structure consisting of nanofibers, with an average porosity of (51.48∓4.47)% and tensile strength of 5.85 ∓ 0.62 MPa. The grafts provided a better long-term support than e-PTFE graft for endothelial cell growth and endothelialization. CONCLUSION: The polyurethane vascular prosthesis possessed favorable microstructures, excellent mechanical properties and good biocompatibility for potential clinical application.