ABSTRACT
Tissue engineering offers a new approach for the construction of vascular substitutes in vitro with proper mechanical properties. Although success has been made in the engineering of small blood vessels (<6mm in diameter), it remains a challenge to engineer large vessels (>6mm in diameter) due to their insufficient biomechanical property. In the current study, an elastic large vessel wall (6mm in diameter) was engineered by loading a polyglycolic acid (PGA) unwoven fiber scaffold seeded with smooth muscle cells (SMCs) on a vessel reactor designed with dynamic culture conditions. SMCs were isolated from canine carotid artery and expanded before seeding on a PGA fiber mesh. The cell-seeded PGA mesh was then loaded on a vessel reactor and subjected to pulsatile stimuli. Grossly, an elastic vessel wall was formed after 8 weeks of dynamic engineering. Histological examination showed well-orientated smooth muscle cells and collagenous fibers in the group with dynamic culture. In addition, the phenotype of SMCs was confirmed by positive staining of smooth muscle alpha-actin and calponin. On the contrary, disorganized smooth muscle cells and collagenous fibers were observed in the group under static culture without stimuli. Furthermore, the engineered vessels under dynamic culture exhibited significant improvements on biomechanical property over the one from static culture. Our results indicate that the approach developed in the current work is efficient for large vessel engineering. This approach may also be suitable for the engineering of other tissues with muscular tubular structure.
