Abstract
3D printing (3DP) technology for tissue engineering applications has been extensively studied for materials and processes. However, clinical application to the vascular system was limited owing to mechanical inconsistency and toxicity. Here, we characterized 3D templated artificial vascular grafts (3D grafts), which were fabricated by an integrative method involving 3DP, dip coating, and salt leaching method. The as-fabricated grafts were featured with micrometer-scale porosity enabling tissue-mimetic mechanical softness comparable with native blood vessels. In terms of mechanical properties and water permeability, the fabricated 3D grafts exhibited comparable or superior performances compared to the commercialized grafts. Furthermore, the in-vivo stability of the 3D graft was validated through a toxicity test, and the small-diameter 3D graft was transplanted into a rat to confirm the implant’s performance. Overall, the experimental results demonstrated the clinical feasibility of the 3D graft with retaining the mechanical biocompatibility and also revealed the possibility of patient-specific customization.
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