Computational Fluid–Structure Interaction Study of a New Wave Membrane Blood Pump

Martinolli, Marco; Cornat, François; Vergara, Christian

doi:10.1007/s13239-021-00584-1

Cited by 6 publications

(4 citation statements)

References 52 publications

(69 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…[7,8] The intricate, traumatic effects of the nonphysiologic flow conditions that are prevalent in RBPs yet remain poorly understood and challenging to model, [9] and has meanwhile even called to action both research and industry to start exploring alternative pumping principles including wave membrane blood pump technologies. [10,11] Designed based on the theory of turbomachinery, RBPs convert mechanical input energy into hydraulic output in the form of pressure and volume flow generation. [12] The extent of energy that is not converted into useful hydraulic work is thereby collectively referred to as hydraulic losses.…”

Section: Introductionmentioning

confidence: 99%

“…[ 7,8 ] The intricate, traumatic effects of the non‐physiologic flow conditions that are prevalent in RBPs yet remain poorly understood and challenging to model, [ 9 ] and has meanwhile even called to action both research and industry to start exploring alternative pumping principles including wave membrane blood pump technologies. [ 10,11 ]…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Linking Hydraulic Properties to Hemolytic Performance of Rotodynamic Blood Pumps

Escher

Hubmann

Karner

et al. 2022

Advcd Theory and Sims

View full text Add to dashboard Cite

In rotodynamic blood pumps (RBPs) a substantial proportion of input energy is dissipated into the blood. This energy may propel damaging work on blood constituents. To date, the link between this hydraulic energy dissipation and respective hemolytic action in RBPs remains vastly unknown. In this study, computational fluid dynamics is applied to compute the hydraulic energy dissipation at 9 operating conditions in two RBPs (HM3: HeartMate 3; HVAD: HeartWare Ventricular Assist Device). Respective interrelations with hemolytic pump performance are elucidated by comparing these computations with in silico predicted and in vitro measured hemolysis. Despite different pump geometries, hydraulic loss magnitudes, and distributions, global hydraulic energy dissipation shows strong correlation (r > 0.95) to in vitro hemolysis with scaling factors in the same order of magnitude for both devices (𝝋 HM3 = 0.599 (mL g) (J 100L) -1 ; 𝝋 HVAD = 0.716 (mL g) (J 100L) -1 ). The analytical description of hydraulic energy dissipation reveals to be a function of shear stresses and exposure time, unmasking its analogy to the power-law formulation of hemolysis. This hydraulics-based analysis may denote a step ahead to relate turbomachinery to bioengineering and may provide mechanistic insights into the relation between RBP design, hydraulic properties, and hemolytic performance.

show abstract

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Linking Hydraulic Properties to Hemolytic Performance of Rotodynamic Blood Pumps

Escher

Hubmann

Karner

et al. 2022

Advcd Theory and Sims

View full text Add to dashboard Cite

show abstract

“…Alternately, impeller blades could be removed entirely, as exemplified by CorWave's bladeless LVAD. This device employs a wave membrane to induce blood flow with low fluid shear stress and reduced blood damage [96]. The CorWave LVAD operates using an average flow rate of 6 L/min, a gentle speed of 1.5 m/sec and an oscillation cycle of 25 ms.…”

Section: Devices In Developmentmentioning

confidence: 99%

The Evolution and Complications of Long-Term Mechanical Circulatory Support Devices

Sargent,

Ali,

Kanamarlapudi

2024

Hearts

View full text Add to dashboard Cite

Heart failure, a common clinical syndrome caused by functional and structural abnormalities of the heart, affects 64 million people worldwide. Long-term mechanical circulatory support can offer lifesaving treatment for end-stage systolic heart failure patients. However, this treatment is not without complications. This review covers the major complications associated with implantable mechanical circulatory support devices, including strokes, pump thrombosis and gastrointestinal bleeding. These complications were assessed in patients implanted with the following devices: Novacor, HeartMate XVE, CardioWest, Jarvik 2000, HeartMate II, EVAHEART, Incor, VentrAssist, HVAD and HeartMate 3. Complication rates vary among devices and remain despite the introduction of more advanced technology, highlighting the importance of device design and flow patterns. Beyond clinical implications, the cost of complications was explored, highlighting the difference in costs and the need for equitable healthcare, especially with the expected rise in the use of mechanical circulatory support. Future directions include continued improvement through advancements in design and technology to reduce blood stagnation and mitigate high levels of shear stress. Ultimately, these alterations can reduce complications and enhance cost-effectiveness, enhancing both the survival and quality of life for patients receiving mechanical circulatory support.

show abstract

“…Wave membranes blood pump are novel approaches for pulsatile flow integration in which blood is moved by wave propagation systems. Both frequency and amplitude of the waves can be monitored to mimic physiological flow (Martinolli et al, 2022). Bileaflet valves are typically subjected to high flow rates and relative changes in volume throughout the cardiac cycle.…”

Section: Macrovessel-size Devices (Diameter >1 Mm)mentioning

confidence: 99%

Design of artificial vascular devices: Hemodynamic evaluation of shear-induced thrombogenicity

Feaugas

Newman²,

Calzuola³

et al. 2023

Front. Mech. Eng.

View full text Add to dashboard Cite

Blood-circulating devices such as oxygenators have offered life-saving opportunities for advanced cardiovascular and pulmonary failures. However, such systems are limited in the mimicking of the native vascular environment (architecture, mechanical forces, operating flow rates and scaffold compositions). Complications involving thrombosis considerably reduce their implementation time and require intensive anticoagulant treatment. Variations in the hemodynamic forces and fluid-mediated interactions between the different blood components determine the risk of thrombosis and are generally not taken sufficiently into consideration in the design of new blood-circulating devices. In this Review article, we examine the tools and investigations around hemodynamics employed in the development of artificial vascular devices, and especially with advanced microfluidics techniques. Firstly, the architecture of the human vascular system will be discussed, with regards to achieving physiological functions while maintaining antithrombotic conditions for the blood. The aim is to highlight that blood circulation in native vessels is a finely controlled balance between architecture, rheology and mechanical forces, altogether providing valuable biomimetics concepts. Later, we summarize the current numerical and experimental methodologies to assess the risk of thrombogenicity of flow patterns in blood circulating devices. We show that the leveraging of both local hemodynamic analysis and nature-inspired architectures can greatly contribute to the development of predictive models of device thrombogenicity. When integrated in the early phase of the design, such evaluation would pave the way for optimised blood circulating systems with effective thromboresistance performances, long-term implantation prospects and a reduced burden for patients.

show abstract

Computational Fluid–Structure Interaction Study of a New Wave Membrane Blood Pump

Cited by 6 publications

References 52 publications

Linking Hydraulic Properties to Hemolytic Performance of Rotodynamic Blood Pumps

Linking Hydraulic Properties to Hemolytic Performance of Rotodynamic Blood Pumps

The Evolution and Complications of Long-Term Mechanical Circulatory Support Devices

Design of artificial vascular devices: Hemodynamic evaluation of shear-induced thrombogenicity

Contact Info

Product

Resources

About