The implantable miniaturized axial blood pump works at a high rotational speed, which increases the risk of blood damage. In this article, we aimed to reduce the possibility of hemolysis and thrombosis by designing a two-stage axial blood pump. Under the operation conditions of flow rate 5 L/min and outlet pressure of 100 mm Hg, we carried out the numerical simulation on the two-stage and single-stage blood pumps to compare the hemolysis and platelet activation state. The results turned out that the hemolysis index of two-stage axial blood pump was better while the platelet activation state was worse than those of single stage design. On the index of hemolysis level and platelet activation state, the design of the two-stage pump with the low and high-head impeller combination was better than the two-stage pump with the equal heads, or the high and low-head impeller combination. In terms of reducing the risk of blood damage for implantable miniaturized axial blood pump, the research result can provide some theoretical basis and new design ideas.
An implantable axial blood pump was designed according to the circulation assist requirement of severe heart failure patients of China. The design point was chosen at 3 L/min flow rate with 100 mm Hg pressure rise when the blood pump can provide flow rates of 2-7 L/min. The blood pump with good hemolytic and anti-thrombogenic property at widely operating range was designed by developing a structure that including the spindly rotor impeller structure and the diffuser with splitter blades and cantilevered main blades. Numerical simulation and particle image velocimetry (PIV) experiment were conducted to analyze the hydraulic, flow fields and hemolytic performance of the blood pump. The results showed that the blood pump could provide flow rates of 2-7 L/min with pressure rise of 60.0-151.3 mm Hg when the blood pump rotating from 7 000 to 11 000 r/min. After adding the splitter blades, the separation flow at the suction surface of the diffuser has been reduced efficiently. The cantilever structure changed the blade gap from shroud to hub that reduced the tangential velocity from 6.2 m/s to 4.3-1.1 m/s in blade gap. Moreover, the maximum scalar shear stress of the blood pump was 897.3 Pa, and the averaged scalar shear stress was 37.7 Pa. The hemolysis index of the blood pump was 0.168% calculated with Heuser’s hemolysis model. The PIV and simulated results showed the overall agreement of flow field distribution in diffuser region. The blood damage caused by higher shear stress would be reduced by adopting the spindle rotor impeller and diffuser with splitter blades and cantilevered main blades. The blood could flow smoothly through the axial blood pump with satisfactory hydraulics performance and without separation flow.