Giselle C. Matlis, Thomas C. Palazzolo, Jonathan E. M. Lawley, Steven W. Day, Emily Woodland, Vakhtang Tchantchaleishvili, Randy M. Stevens, Amy L. Throckmorton
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The axial pump is embedded in the central hub region of the centrifugal pump, and both pumps rotate around a common central axis, while maintaining separate fluid domains.</p>\n </section>\n \n <section>\n \n <h3> Methods</h3>\n \n <p>In this work, we concentrated our design and development effort on the centrifugal blood pump by performing computational modeling. An iterative process was employed to improve the DH design. The pressure generation, scalar stress levels, and fluid forces exerted on the magnetically levitated impellers were computationally estimated. A shaft driven centrifugal prototype was also manufactured and tested using a hydraulic flow loop circulating a water–glycerol blood analog. Pressure and flow performance of the pump prototype was measured for a given rotational speed for comparison to computational predictions.</p>\n </section>\n \n <section>\n \n <h3> Results</h3>\n \n <p>Our design achieved the target pump pressures of 60–140 mm Hg for flow rates of 1–5 L/min, and strong agreement in pressure rise was demonstrated between the experimental data and simulation results (less than 10% deviation on average). Fluid stress levels were, however, found to exceed thresholds in the outflow region of the pump, and fluid residence times were less than 600 ms.</p>\n </section>\n \n <section>\n \n <h3> Conclusion</h3>\n \n <p>The findings of this work demonstrate that the more compact, next-gen DH's centrifugal pump design is able to achieve pressure–capacity requirements. Next steps will require a focused strategy to reduce hemolytic potential and to integrate magnetic suspension components for full rotor levitation.</p>\n </section>\n </div>","PeriodicalId":8450,"journal":{"name":"Artificial organs","volume":"49 5","pages":"790-801"},"PeriodicalIF":2.2000,"publicationDate":"2025-01-10","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Advancement of the Dragon Heart 7-Series for Pediatric Patients With Heart Failure\",\"authors\":\"Giselle C. Matlis, Thomas C. Palazzolo, Jonathan E. M. Lawley, Steven W. Day, Emily Woodland, Vakhtang Tchantchaleishvili, Randy M. Stevens, Amy L. Throckmorton\",\"doi\":\"10.1111/aor.14935\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<div>\\n \\n \\n <section>\\n \\n <h3> Background</h3>\\n \\n <p>Safe and effective pediatric blood pumps continue to lag far behind those developed for adults. 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引用次数: 0
摘要
背景:安全有效的儿童血泵仍然远远落后于成人血泵。为了解决这一日益增长的未满足的临床需求,我们正在开发一种混合的、连续流动的、磁悬浮的儿科全人工心脏(TAH)。我们的混合TAH设计,龙心(DH),集成了轴流和离心流血泵在一个单一的,紧凑的外壳。轴流泵嵌入在离心泵的中心轮毂区域,两个泵围绕一个共同的中心轴旋转,同时保持单独的流体域。方法:在这项工作中,我们通过进行计算建模,将我们的设计和开发工作集中在离心血泵上。采用迭代法改进DH设计。对施加在磁悬浮叶轮上的压力产生、标量应力水平和流体力进行了计算估计。还制造了轴驱动的离心原型机,并使用水-甘油血液模拟物循环的液压循环回路进行了测试。在给定转速下,测量了泵原型的压力和流量性能,以便与计算预测进行比较。结果:我们的设计在流量为1-5 L/min的情况下实现了60-140 mm Hg的目标泵压力,并且实验数据和模拟结果之间的压力上升非常吻合(平均偏差小于10%)。然而,在泵的流出区发现流体应力水平超过阈值,流体停留时间小于600毫秒。结论:这项工作的发现表明,更紧凑的,下一代DH的离心泵设计能够达到压力-容量的要求。接下来的步骤将需要一个集中的战略,以减少溶血潜能和集成磁悬浮组件的全转子悬浮。
Advancement of the Dragon Heart 7-Series for Pediatric Patients With Heart Failure
Background
Safe and effective pediatric blood pumps continue to lag far behind those developed for adults. To address this growing unmet clinical need, we are developing a hybrid, continuous-flow, magnetically levitated, pediatric total artificial heart (TAH). Our hybrid TAH design, the Dragon Heart (DH), integrates both an axial flow and centrifugal flow blood pump within a single, compact housing. The axial pump is embedded in the central hub region of the centrifugal pump, and both pumps rotate around a common central axis, while maintaining separate fluid domains.
Methods
In this work, we concentrated our design and development effort on the centrifugal blood pump by performing computational modeling. An iterative process was employed to improve the DH design. The pressure generation, scalar stress levels, and fluid forces exerted on the magnetically levitated impellers were computationally estimated. A shaft driven centrifugal prototype was also manufactured and tested using a hydraulic flow loop circulating a water–glycerol blood analog. Pressure and flow performance of the pump prototype was measured for a given rotational speed for comparison to computational predictions.
Results
Our design achieved the target pump pressures of 60–140 mm Hg for flow rates of 1–5 L/min, and strong agreement in pressure rise was demonstrated between the experimental data and simulation results (less than 10% deviation on average). Fluid stress levels were, however, found to exceed thresholds in the outflow region of the pump, and fluid residence times were less than 600 ms.
Conclusion
The findings of this work demonstrate that the more compact, next-gen DH's centrifugal pump design is able to achieve pressure–capacity requirements. Next steps will require a focused strategy to reduce hemolytic potential and to integrate magnetic suspension components for full rotor levitation.
期刊介绍:
Artificial Organs is the official peer reviewed journal of The International Federation for Artificial Organs (Members of the Federation are: The American Society for Artificial Internal Organs, The European Society for Artificial Organs, and The Japanese Society for Artificial Organs), The International Faculty for Artificial Organs, the International Society for Rotary Blood Pumps, The International Society for Pediatric Mechanical Cardiopulmonary Support, and the Vienna International Workshop on Functional Electrical Stimulation. Artificial Organs publishes original research articles dealing with developments in artificial organs applications and treatment modalities and their clinical applications worldwide. Membership in the Societies listed above is not a prerequisite for publication. Articles are published without charge to the author except for color figures and excess page charges as noted.
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