Litcius/Paper detail

Fabrication of a low-kink-radius bilayer vascular scaffold incorporating a TPU stent fabricated via melt electrowriting and an electrospun PCL/PU/gelatin layer

Mohammad Shahverdi, Hossein Shaygani, Mohamadreza Soltani, Kayvan Dadkhah, Seyed Mohammad Hossein Rezaei Demneh, Kaivan Mohammadi, Amir Shamloo

2025Scientific Reports12 citationsDOIOpen Access PDF

Abstract

This study investigates the fabrication of a small-diameter bilayer vascular graft, which is an inner layer fabricated from melt-electrowriting (MEW) thermoplastic polyurethane (TPU) scaffold and an outer co-electrospun layer made of heparinized polycaprolactone (PCL)/polyurethane (PU)/gelatin, aimed at mimicking the extracellular matrix (ECM). The bilayer structure exhibited good flexibility, mechanical stability, and anti-thrombogenic properties, overcoming the drawbacks of vascular grafts, such as high kink radius and tendency toward thrombosis. MTT assays proved cytocompatibility, showing an increase in cell proliferation over 7 days, the optical density of the bilayer vascular graft increased from [Formula: see text] on day [Formula: see text] to [Formula: see text] on day [Formula: see text], respectively, due to its fibrous structure and hydrophilic properties. Live/dead and SEM assays confirmed cell viability, attachment, and endothelial layer formation on the scaffold, which provides long-term graft patency. The bilayer graft with integrated MEW structure provided the balanced mechanical and kink-radius properties (ultimate tensile strength [Formula: see text], Young's modulus [Formula: see text], suture retention [Formula: see text]) with a low kink radius ([Formula: see text]), surpassing the mechanical properties of coronary artery. A heparin release profile of 70% after 4 weeks was obtained, thus increasing anticoagulant effects. This combination of synthetic (TPU, PCL, PU) and natural (gelatin) polymers yields a biocompatible, structurally stable vascular graft, which efficiently supports endothelialization, and thus has good potential for clinical vascular applications.

Topics & Concepts

BilayerGelatinScaffoldFabricationMaterials scienceLayer (electronics)Composite materialRADIUSBiomedical engineeringChemistryMembraneComputer scienceMedicinePathologyComputer securityBiochemistryAlternative medicineElectrospun Nanofibers in Biomedical ApplicationsPolymer Surface Interaction StudiesSilk-based biomaterials and applications