Stents are miniature medical devices that can be inserted into arteries and expanded during angioplasty to maintain patency and re-establish flow through the vessel. They have been the primary treatment for cardiovascular diseases. However, after stenting, potential risks associated with late stent/scaffold thrombosis may occur. This problem promises to be solved with the advent of bioresorbable vascular scaffolds which offer the possibility of transient scaffolding of the vessel to prevent acute vessel closure and recoil. In this study, finite element models were developed to investigate the mechanical behaviors of bioresorbable vascular scaffolds. In the first part of this thesis, computational simulations were performed on two scaffold design patterns assigned with two different materials in attempts to quantify individual effects of the scaffold design patterns and materials on the mechanical performance. Simulation results show that the material properties plays the most significant role in all three finite element models. In the second part, a novel scaffold design concept associated with 3D printing was introduced for the purpose of enhancing mechanical properties Struts of the scaffolds were separated into many layers and each of them was assigned with different materials in certain order. Simulation results shows that the scaffold materials at particular location may have larger impacts on certain mechanical behaviors. If used appropriately, this phenomenon can improve the mechanical performance of scaffolds. This study provides great insight for the future design optimization and physician practice to help achieve the best possible clinical outcomes.