Date of Award
12-2017
Document Type
Thesis
Degree Name
Master of Science (MS)
Department
Bioengineering
Committee Member
Dr. Dan Simionescu, Committee Chair
Committee Member
Dr. Agneta Simionescu
Committee Member
Dr. Christopher Wright
Abstract
Coronary artery disease is one of the number one killers in the U.S. Current treatment of using CABG surgery has limitations from availability of autologous grafts, and low patency of artificial grafts. Tissue engineered grafts would ideally provide more availability, while also replicating the mechanical properties of the native grafts. Current issues in tissue engineering arteries lie in using an effective scaffold to get correct mechanical properties, and allowing for cell infiltration to assist in integrating with native tissue once implanted. This study shows the use of a decellularized and chemically and mechanically porated porcine carotid artery in mechanical characterization and cell seeding experiments. The mechanical properties all exhibit values like that of current autologous grafts. The cell seeding studies show data determining the viability of these porated scaffolds in cell infiltration. It also examines several seeding techniques and how they impact the location of cells. This study concludes that the decellularization and poration procedures result in a scaffold with suitable mechanical properties for CABG grafts. It also concludes that several different cells seeding methods can be effective in getting cells onto the scaffold, but some work remains on developing an ideal tissue.
Recommended Citation
Smallwood, Harrison, "Improving Cell Seeding of Decellularized and Porated Porcine Arterial Scaffolds" (2017). All Theses. 2768.
https://open.clemson.edu/all_theses/2768