Tompkins Landon H, Gellman Barry N, Prina Steven R, Morello Gino F, Roussel Thomas, Kopechek Jonathan A, Williams Stuart J, Petit Priscilla C, Slaughter Mark S, Koenig Steven C, Dasse Kurt A
Department of Bioengineering, University of Louisville, Louisville, KY, 40202, USA.
Inspired Therapeutics LLC, 125 E. Merritt Island Cswy, #107-341, Merritt Island, FL, 32925, USA.
Cardiovasc Eng Technol. 2022 Aug;13(4):624-637. doi: 10.1007/s13239-021-00602-2. Epub 2022 Jan 10.
Pediatric heart failure patients remain in critical need of a dedicated mechanical circulatory support (MCS) solution as development efforts for specific pediatric devices continue to fall behind those for the adult population. The Inspired Pediatric VAD is being developed as a pediatric specific MCS solution to provide up to 30-days of circulatory or respiratory support in a compact modular package that could allow for patient ambulation during treatment.
Hydrodynamic performance (flows, pressures), impeller/rotor mechanical properties (torques, forces), and flow shear stress and residence time distributions of the latest design version, Inspired Pediatric VAD V3, were numerically predicted and investigated using computational fluid dynamics (CFD) software (SolidWorks Flow Simulator).
Hydrodynamic performance was numerically predicted, indicating no change in flow and pressure head compared to the previous device design (V2), while displaying increased impeller/rotor torques and translation forces enabled by improved geometry. Shear stress and flow residence time volumetric distributions are presented over a range of pump rotational speeds and flow rates. At the lowest pump operating point (3000 RPM, 0.50 L/min, 75 mmHg), 79% of the pump volume was in the shear stress range of 0-10 Pa with < 1% of the volume in the critical range of 150-1000 Pa for blood damage. At higher speed and flow (5000 RPM, 3.50 L/min, 176 mmHg), 65% of the volume resided in the 0-10 Pa range compared to 2.3% at 150-1000 Pa.
The initial computational characterization of the Inspired Pediatric VAD V3 is encouraging and future work will include device prototype testing in a mock circulatory loop and acute large animal model.
由于针对特定儿科设备的研发工作仍落后于成人设备,儿科心力衰竭患者仍然迫切需要专门的机械循环支持(MCS)解决方案。Inspired Pediatric VAD正在作为一种儿科专用的MCS解决方案进行开发,以紧凑的模块化封装提供长达30天的循环或呼吸支持,这可能使患者在治疗期间能够走动。
使用计算流体动力学(CFD)软件(SolidWorks Flow Simulator)对最新设计版本Inspired Pediatric VAD V3的流体动力学性能(流量、压力)、叶轮/转子机械性能(扭矩、力)以及流动剪切应力和停留时间分布进行了数值预测和研究。
对流体动力学性能进行了数值预测,结果表明与先前的设备设计(V2)相比,流量和压头没有变化,同时改进的几何形状使叶轮/转子扭矩和移动力增加。给出了一系列泵转速和流量下的剪切应力和流动停留时间体积分布。在最低泵工作点(3000转/分钟,0.50升/分钟,75毫米汞柱),79%的泵体积处于0-10帕的剪切应力范围内,而处于150-1000帕血液损伤临界范围内的体积不到1%。在更高的速度和流量(5000转/分钟,3.50升/分钟,176毫米汞柱)下,65%的体积处于0-10帕范围内,而在150-1000帕时为2.3%。
Inspired Pediatric VAD V3的初步计算特性令人鼓舞,未来的工作将包括在模拟循环回路和急性大动物模型中进行设备原型测试。
