BACKGROUND: As the cardiovascular device, biomaterials applied under the blood-contact conditions should have anti-thrombotic, anti-biodegradable and anti-infective properties. OBJECTIVE: To develop novel polymer materials for implantation and intervention in cardiovascular tissue engineering and to explore the biocompatibility, blood compatibility and cytocompatibility of the surface-modified polymer biomaterials based on the coagulant and anti-coagulant coating modification. METHODS:We retrieved PubMed and WanFang databases for relevant articles publishing from 1983 to 2014. The key words were "biocompatibility, blood compatibility, biomedical materials, biomedical polymer materials" in English and Chinese, respectively. Those unrelated, outdated and repetitive papers were excluded. Literatures addressing the blood compatibility of biomedical polymer materials were summarized. RESULTS AND CONCLUSION: The blood-implant interaction and the anti-coagulant surface modification of biomaterials were analyzed. The biocompatibility, blood compatibility and cytocompatibility of the surface-modified polymer biomaterials were determined based on the coagulant and anti-coagulant coating modification. The coagulant and anti-coagulant surface modification of polymer biomaterials and the research on their biocompatibility and endothelial cel compatibility are crucial for developing novel polymer materials for implantation and intervention in cardiovascular tissue engineering. Through in-depth studies of the types and applications of polymer biomaterials, cardiovascular medical devices and implantable soft tissue substitutes, the differences between the surface and the body wil be reflected in the many layers of molecules extending from the surface to the body. Two major factors, surface energy and molecular mobility, determine the body/surface behaviors that include body/surface differences and phase separation. Considering the difference between the body/surface composition, an additional determinant is indispensable, that is the crystalization behavior of each component.