An accelerated thrombosis model for computational fluid dynamics simulations in rotary blood pumps

Blum, Christopher; Groß-Hardt, Sascha; Steinseifer, Ulrich; Neidlin, Michael

doi:10.1101/2021.08.30.458209

Cited by 4 publications

(2 citation statements)

References 36 publications

(65 reference statements)

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“…Larger clearance not only reduces visocus stress inside the clearance, but also cause stronger secondary ows. Furthermore, as some recent studies showed (Olia 2023;Blum et al 2023), contemporary blood pumps are consistently used across a large operating range, and not just solely clustered around their optimal design point, with majority of off-design operation is at lower ow rates, across all patient size populations (not just pediatrics). Lower ow rates lead to longer blood exposure times in current rotary blood pumps withevidence of clinical implications.…”

Section: Discusson and Conclusionmentioning

confidence: 99%

Investigation of turbulent flow field in maglev centrifugal blood pumps of CH-VAD and Heartmate III using large-eddy simulation

Wu,

Xiang,

Zhang

et al. 2023

Preprint

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Maglev bearings can avoid serious blood damage caused by mechanical bearings, and has become the primary trend of blood pumps. Maglev blood pumps allow a relatively large clearance to improve blood washout and reduce the stress inside the clearance so that blood damage can be reduced. Nonetheless, large clearances also lead to high secondary flow and turbulence intensity, causing further blood damage. This study aims to conduct a thorough analysis of flow fields in two typical maglev blood pumps, the CH-VAD and Heartmate III which feature distinct designs of secondary flow path and impeller (semi-open versus closed impeller) using large eddy simulation (LES) with a focus on the secondary flows and their interaction with the main flows. LES was found to be superior to the Reynolds-averaged Navier-Stokes (RANS) method in predicting performance curves. At high flow rate (8L/min), the efficiency of CH-VAD remains high compared with 5 L/min, while the efficiency of Heartmate III drops considerably. The wide clearance in Heartmate III induced high secondary flow and flow loss, leading to an large incidence angle at both working conditions. The high viscous stress inside the clearances is the major cause of flow loss and potential blood damage in CH-VAD. This study shows that Maglev bearings dose not guarantee good blood compatibility, clearances should be designed based on trade-offs among high shear stress inside smaller clearance, and strong recirculations caused by larger clearances. This study provides useful reference for the design and optimization of maglev blood pumps.

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Section: Discusson and Conclusionmentioning

confidence: 99%

Investigation of turbulent flow field in maglev centrifugal blood pumps of CH-VAD and Heartmate III using large-eddy simulation

Wu,

Xiang,

Zhang

et al. 2023

Preprint

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“…Its calculation method is shown in Equation 7. An accelerated thrombus formation model is utilized to quantitatively assess the thrombus risk (27). This model includes three convection-diffusion equations (Equations 8-10), describing the generation and transport of non-activated platelets (NP), activated platelets (AP), and adenosine diphosphate (ADP).…”

Section: Thrombus Risk Assessment Modelmentioning

confidence: 99%

Study on the optimal elastic modulus of flexible blades for right heart assist device supporting patients with single-ventricle physiologies

Chen,

Cheng,

Liu

et al. 2024

Front. Cardiovasc. Med.

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BackgroundPatients with single-ventricle physiologies continue to experience insufficient circulatory power after undergoing palliative surgeries. This paper proposed a right heart assist device equipped with flexible blades to provide circulatory assistance for these patients. The optimal elastic modulus of the flexible blades was investigated through numerical simulation.MethodsA one-way fluid-structure interaction (FSI) simulation was employed to study the deformation of flexible blades during rotation and its impact on device performance. The process began with a computational fluid dynamics (CFD) simulation to calculate the blood pressure rise and the pressure on the blades’ surface. Subsequently, these pressure data were exported for finite element analysis (FEA) to compute the deformation of the blades. The fluid domain was then recreated based on the deformed blades’ shape. Iterative CFD and FEA simulations were performed until both the blood pressure rise and the blades’ shape stabilized. The blood pressure rise, hemolysis risk, and thrombosis risk corresponding to blades with different elastic moduli were exhaustively evaluated to determine the optimal elastic modulus.ResultsExcept for the case at 8,000 rpm with a blade elastic modulus of 40 MPa, the pressure rise associated with flexible blades within the studied range (rotational speeds of 4,000 rpm and 8,000 rpm, elastic modulus between 10 MPa and 200 MPa) was lower than that of rigid blades. It was observed that the pressure rise corresponding to flexible blades increased as the elastic modulus increased. Additionally, no significant difference was found in the hemolysis risk and thrombus risk between flexible blades of various elastic moduli and rigid blades.ConclusionExcept for one specific case, deformation of the flexible blades within the studied range led to a decrease in the impeller’s functionality. Notably, rotational speed had a more significant impact on hemolysis risk and thrombus risk compared to blade deformation. After a comprehensive analysis of blade compressibility, blood pressure rise, hemolysis risk, and thrombus risk, the optimal elastic modulus for the flexible blades was determined to be between 40 MPa and 50 MPa.

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Modeling Hemodynamics of Rotary Blood Pumps and Predicting the Potential Risks

Rossato¹,

Kusner²,

Nezami³

2023

Applied Complex Flow

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An accelerated thrombosis model for computational fluid dynamics simulations in rotary blood pumps

Cited by 4 publications

References 36 publications

Investigation of turbulent flow field in maglev centrifugal blood pumps of CH-VAD and Heartmate III using large-eddy simulation

Investigation of turbulent flow field in maglev centrifugal blood pumps of CH-VAD and Heartmate III using large-eddy simulation

Study on the optimal elastic modulus of flexible blades for right heart assist device supporting patients with single-ventricle physiologies

Modeling Hemodynamics of Rotary Blood Pumps and Predicting the Potential Risks

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