Design of an axial blood pump of diffuser with splitter blades and cantilevered main blades_Journal of Biomedical Engineering

Authors：

LIU Guangmao ¹ , XI Jian ² , CHEN Haibo ¹ , ZHANG Yan ¹ , HOU Jianfeng ¹ , ZHOU Jianye ¹ , SUN Hansong ¹ ,  HU Shengshou ¹

1. State Key Laboratory of Cardiovascular Disease, Fuwai Hospital, National Center for Cardiovascular Diseases, Chinese Academy of Medical Sciences and Peking Union Medical College, Beijing 100037, P.R.China;
2. Zhonghang Electronic Measuring Instruments Co., Ltd, Xi'an 710000, P.R.China;

Corresponding author：

HU Shengshou, Email: huss@fuwaihospital.org

Keywords：

axial blood pump; numerical simulation; hemolysis index; cantilevered main blade; splitter blade

DOI：

10.7507/1001-5515.201801065

Video：

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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.

Citation： LIU Guangmao, XI Jian, CHEN Haibo, ZHANG Yan, HOU Jianfeng, ZHOU Jianye, SUN Hansong, HU Shengshou. Design of an axial blood pump of diffuser with splitter blades and cantilevered main blades. Journal of Biomedical Engineering, 2019, 36(3): 379-385. doi: 10.7507/1001-5515.201801065 Copy

1.	Nosé Y, Yoshikawa M, Murabayashi S, et al. Development of rotary blood pump technology: past, present, and future. Artif Organs, 2000, 24(6): 412-420.
2.	Sheriff J, Girdhar G, Chiu W C, et al. Comparative efficacy of in vitro and in vivo metabolized aspirin in the DeBakey ventricular assist device. J Thromb Thrombolysis, 2014, 37(4): 499-506.
3.	Tchantchaleishvili V, Hallinan W, Schwarz K Q, et al. Long-term total cardiac support in a Fontan-type circulation with HeartMate II left ventricular assist device. Interact Cardiovasc Thorac Surg, 2016, 22(5): 692-694.
4.	Tanoue Y, Jinzai Y, Tominaga R. Jarvik 2000 axial-flow ventricular assist device placement to a systemic morphologic right ventricle in congenitally corrected transposition of the great arteries. J Artif Organs, 2016, 19(1): 97-99.
5.	Noor M R, Ho C H, Parker K H, et al. Investigation of the characteristics of HeartWare HVAD and Thoratec HeartMate II under steady and pulsatile flow conditions. Artif Organs, 2016, 40(6): 549-560.
6.	Fraser K H, Zhang Tao, Taskin M E, et al. A quantitative comparison of mechanical blood damage parameters in rotary ventricular assist devices: shear stress, exposure time and hemolysis index. J Biomech Eng, 2012, 134(8): 081002.
7.	Untaroiu A, Wood H G, Allaire P E, et al. Computational design and experimental testing of a novel axial flow LVAD. ASAIO J, 2005, 51(6): 702-710.
8.	Zhang Yan, Zhan Zhao, Gui Xingmin, et al. Design optimization of an axial blood pump with computational fluid dynamics. ASAIO J, 2008, 54(2): 150-155.
9.	杨晓琛. 人工心脏心室辅助泵流动优化设计与实验研究. 北京: 北京航空航天大学, 2011.
10.	Liu Guangmao, Jin Donghai, Jiang Xihang, et al. Numerical and in vitro experimental investigation of the hemolytic performance at the off-design point of an axial ventricular assist pump. ASAIO J, 2016, 62(6): 657-665.
11.	Wernicke J T, Meier D, Mizuguchi K, et al. A fluid dynamic analysis using flow visualization of the Baylor/NASA implantable axial flow blood pump for design improvement. Artif Organs, 1995, 19(2): 161-177.
12.	Burgreen G W, Antaki J F, Wu Z J, et al. Computational fluid dynamics as a development tool for rotary blood pumps. Artif Organs, 2001, 25(5): 336-340.
13.	Doligalski C T, Jennings D L. Device-related thrombosis in continuous-flow left ventricular assist device support. J Pharm Pract, 2016, 29(1): 58-66.
14.	Bludszuweit C. Model for a general mechanical blood damage prediction. Artif Organs, 1995, 19(7): 583-589.
15.	Gu Lei, Smith W A. Evaluation of computational models for hemolysis estimation. ASAIO J, 2005, 51(3): 202-207.
16.	Heuser G, Opitz R. A couette viscometer for short time shearing in blood. Biorheology, 1980, 17(1/2): 17-24.
17.	Apel J, Paul R, Klaus S, et al. Assessment of hemolysis related quantities in a microaxial blood pump by computational fluid dynamics. Artif Organs, 2001, 25(5): 341-347.
18.	柳光茂, 周建业, 胡盛寿, 等. 轴流式左心辅助泵的出口管道流场PIV实验研究. 中国生物医学工程学报, 2013, 32(6): 678-684.
19.	Paul R, Apel J, Klaus S, et al. Shear stress related blood damage in laminar couette flow. Artif Organs, 2003, 27(6): 517-529.

1. Nosé Y, Yoshikawa M, Murabayashi S, et al. Development of rotary blood pump technology: past, present, and future. Artif Organs, 2000, 24(6): 412-420.
2. Sheriff J, Girdhar G, Chiu W C, et al. Comparative efficacy of in vitro and in vivo metabolized aspirin in the DeBakey ventricular assist device. J Thromb Thrombolysis, 2014, 37(4): 499-506.
3. Tchantchaleishvili V, Hallinan W, Schwarz K Q, et al. Long-term total cardiac support in a Fontan-type circulation with HeartMate II left ventricular assist device. Interact Cardiovasc Thorac Surg, 2016, 22(5): 692-694.
4. Tanoue Y, Jinzai Y, Tominaga R. Jarvik 2000 axial-flow ventricular assist device placement to a systemic morphologic right ventricle in congenitally corrected transposition of the great arteries. J Artif Organs, 2016, 19(1): 97-99.
5. Noor M R, Ho C H, Parker K H, et al. Investigation of the characteristics of HeartWare HVAD and Thoratec HeartMate II under steady and pulsatile flow conditions. Artif Organs, 2016, 40(6): 549-560.
6. Fraser K H, Zhang Tao, Taskin M E, et al. A quantitative comparison of mechanical blood damage parameters in rotary ventricular assist devices: shear stress, exposure time and hemolysis index. J Biomech Eng, 2012, 134(8): 081002.
7. Untaroiu A, Wood H G, Allaire P E, et al. Computational design and experimental testing of a novel axial flow LVAD. ASAIO J, 2005, 51(6): 702-710.
8. Zhang Yan, Zhan Zhao, Gui Xingmin, et al. Design optimization of an axial blood pump with computational fluid dynamics. ASAIO J, 2008, 54(2): 150-155.
9. 杨晓琛. 人工心脏心室辅助泵流动优化设计与实验研究. 北京: 北京航空航天大学, 2011.
10. Liu Guangmao, Jin Donghai, Jiang Xihang, et al. Numerical and in vitro experimental investigation of the hemolytic performance at the off-design point of an axial ventricular assist pump. ASAIO J, 2016, 62(6): 657-665.
11. Wernicke J T, Meier D, Mizuguchi K, et al. A fluid dynamic analysis using flow visualization of the Baylor/NASA implantable axial flow blood pump for design improvement. Artif Organs, 1995, 19(2): 161-177.
12. Burgreen G W, Antaki J F, Wu Z J, et al. Computational fluid dynamics as a development tool for rotary blood pumps. Artif Organs, 2001, 25(5): 336-340.
13. Doligalski C T, Jennings D L. Device-related thrombosis in continuous-flow left ventricular assist device support. J Pharm Pract, 2016, 29(1): 58-66.
14. Bludszuweit C. Model for a general mechanical blood damage prediction. Artif Organs, 1995, 19(7): 583-589.
15. Gu Lei, Smith W A. Evaluation of computational models for hemolysis estimation. ASAIO J, 2005, 51(3): 202-207.
16. Heuser G, Opitz R. A couette viscometer for short time shearing in blood. Biorheology, 1980, 17(1/2): 17-24.
17. Apel J, Paul R, Klaus S, et al. Assessment of hemolysis related quantities in a microaxial blood pump by computational fluid dynamics. Artif Organs, 2001, 25(5): 341-347.
18. 柳光茂, 周建业, 胡盛寿, 等. 轴流式左心辅助泵的出口管道流场PIV实验研究. 中国生物医学工程学报, 2013, 32(6): 678-684.
19. Paul R, Apel J, Klaus S, et al. Shear stress related blood damage in laminar couette flow. Artif Organs, 2003, 27(6): 517-529.

Journal of Biomedical Engineering

Design of an axial blood pump of diffuser with splitter blades and cantilevered main blades

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