In recent decades, cardiovascular disease is becoming the leading cause of death in developed countries only inferior to cancer. Coronary artery bypass graft surgery (for small diameter < 4 mm graft) is performed annually in the world, making it one of the most commonly performed major operations. Autogenous saphenous veins, synthetic grafts, or acellular human umbilical veins are presently used as replacement arteries in surgical procedures. However, limited availability of the graft and the limited conduit diameter troubled clinical doctors. In addition, the recurrences of obstructed blood vessels, thrombosis, and eliciting serious immune response challenged researchers as well. In order to overcome these inconvenience, tissue engineering offers the hope of delivering the replacement function in a much more cost-effective and beneficial way. The objective of this study is to fabricate an adequate blood vessel replacement with suitable mechanical property and biocompatibility for clinical applications. In this study, we are going to prepare blood vessel based on type I collagen by tissue engineering technique. Endothelial cells and smooth muscle cells harvested from endocardium, bladder, and blood vessel will be seeded on a preformed scaffold for cell proliferation and differentiation, and finally developed into a physiologically functional blood vessel. In the animal study, we found that endothelial cells could survive and smoothly cover the whole surface area of the scaffold both in non cell-seeding group and cell-seeding group. However, smooth muscle cells only showed positive reaction by immunostain in the cell-seeding group, but negative reaction in non cell-seeding group. We expect that the tissue-engineering vessel would have the properties of good biocompatibility, anti-thrombosis, resistance to infection, low immunogenicity, and might prevent from platelet aggregation and minimal tissue infiltration.