Abstract
AbstractThe 70-year quest for synthetic vascular graft (sVG) endothelialization has not led to completely healed endothelium in clinically used sVGs. In humans, healing is limited to the vicinity of anastomotic regions (pannus ingrowth) and does not reach the middle regions of sVGs. Here, we conducted proof-of-concept implantation ofimmunomodulatory porous regenerative scaffolds for in situ vascular engineering(IMPRESSIVE) as interposition grafts in sheep carotid arteries. These scaffolds are based on a new polyurethane (PU) material featuring a 40 µm precision porous structure optimized for angiogenesis. The modulus of the PU was adjusted to match that of natural arteries. The implantation study revealed rapid healing in IMPRESSIVE sVGs. In side-by-side comparison with standard polytetrafluoroethylene (PTFE) grafts, the luminal surfaces of PU grafts were almost completely covered with nucleated cells, while healing in PTFE grafts was limited to several millimeters within anastomotic regions. Endothelialization was observed in the middle regions of PU grafts and overall endothelialization increased significantly compared to PTFE grafts. Densities of mononuclear cells, foreign body giant cells (FBGCs), and endothelial cells within graft walls of PU grafts were also significantly higher than those in PTFE grafts, suggesting transmural cellular infiltration may play a key role in overall improved healing. High percentages of macrophages in pores of PU grafts show Type 1 (CCR7+) and Type 2 (mannose receptor, MR+) characteristics. We also discovered that FBGCs exist in a diverse spectrum of phenotypes. Dually activated FBGCs (CCR7+MR+, G1/2) dominate the population of FBGCs associated with pro-healing PU grafts. These observations suggest a complex, balanced pro-healing response from macrophages and FBGCs. The IMPRESSIVE approach may enable complete endothelialization in pro-healing sVGs and have wide applications in implantable devices and tissue engineering.
Publisher
Cold Spring Harbor Laboratory