Vincenz Crone, Mario Hahne, Finn Knüppel, Frank-Hendrik Wurm, Benjamin Torner
{"title":"动态 VAD 模拟:对与心血管系统相互作用的心室辅助装置进行精确模拟。","authors":"Vincenz Crone, Mario Hahne, Finn Knüppel, Frank-Hendrik Wurm, Benjamin Torner","doi":"10.1177/03913988241268067","DOIUrl":null,"url":null,"abstract":"<p><p>Medical advancements, particularly in ventricular assist devices (VADs), have notably advanced heart failure (HF) treatment, improving patient outcomes. However, challenges such as adverse events (strokes, bleeding and thrombosis) persist. Computational fluid dynamics (CFD) simulations are instrumental in understanding VAD flow dynamics and the associated flow-induced adverse events resulting from non-physiological flow conditions in the VAD.This study aims to validate critical CFD simulation parameters for accurate VAD simulations interacting with the cardiovascular system, building upon the groundwork laid by Hahne et al. A bidirectional coupling technique was used to model dynamic (pulsatile) flow conditions of the VAD CFD interacting with the cardiovascular system. Mesh size, time steps and simulation method (URANS, LES) were systematically varied to evaluate their impact on the dynamic pump performance (dynamic <math><mrow><mi>H</mi><mo>-</mo><mi>Q</mi></mrow></math> curve) of the HeartMate 3, aiming to find the optimal simulation configuration for accurately reproduce the dynamic <math><mrow><mi>H</mi><mo>-</mo><mi>Q</mi></mrow></math> curve. The new Overlapping Ratio (OR) method was developed and applied to quantify dynamic <math><mrow><mi>H</mi><mo>-</mo><mi>Q</mi></mrow></math> curves.In particular, mesh and time step sizes were found to have the greatest influence on the calculated pump performance. Therefore, small time steps and large mesh sizes are recommended to obtain accurate dynamic <math><mrow><mi>H</mi><mo>-</mo><mi>Q</mi></mrow></math> curves. On the other hand, the influence of the simulation method was not significant in this study. This study contributes to advancing VAD simulations, ultimately enhancing clinical efficacy and patient outcomes.</p>","PeriodicalId":13932,"journal":{"name":"International Journal of Artificial Organs","volume":null,"pages":null},"PeriodicalIF":1.4000,"publicationDate":"2024-08-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Dynamic VAD simulations: Performing accurate simulations of ventricular assist devices in interaction with the cardiovascular system.\",\"authors\":\"Vincenz Crone, Mario Hahne, Finn Knüppel, Frank-Hendrik Wurm, Benjamin Torner\",\"doi\":\"10.1177/03913988241268067\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<p><p>Medical advancements, particularly in ventricular assist devices (VADs), have notably advanced heart failure (HF) treatment, improving patient outcomes. However, challenges such as adverse events (strokes, bleeding and thrombosis) persist. Computational fluid dynamics (CFD) simulations are instrumental in understanding VAD flow dynamics and the associated flow-induced adverse events resulting from non-physiological flow conditions in the VAD.This study aims to validate critical CFD simulation parameters for accurate VAD simulations interacting with the cardiovascular system, building upon the groundwork laid by Hahne et al. A bidirectional coupling technique was used to model dynamic (pulsatile) flow conditions of the VAD CFD interacting with the cardiovascular system. Mesh size, time steps and simulation method (URANS, LES) were systematically varied to evaluate their impact on the dynamic pump performance (dynamic <math><mrow><mi>H</mi><mo>-</mo><mi>Q</mi></mrow></math> curve) of the HeartMate 3, aiming to find the optimal simulation configuration for accurately reproduce the dynamic <math><mrow><mi>H</mi><mo>-</mo><mi>Q</mi></mrow></math> curve. The new Overlapping Ratio (OR) method was developed and applied to quantify dynamic <math><mrow><mi>H</mi><mo>-</mo><mi>Q</mi></mrow></math> curves.In particular, mesh and time step sizes were found to have the greatest influence on the calculated pump performance. Therefore, small time steps and large mesh sizes are recommended to obtain accurate dynamic <math><mrow><mi>H</mi><mo>-</mo><mi>Q</mi></mrow></math> curves. On the other hand, the influence of the simulation method was not significant in this study. 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引用次数: 0
摘要
医学的进步,尤其是心室辅助装置(VAD)的进步,显著推进了心力衰竭(HF)的治疗,改善了患者的预后。然而,不良事件(中风、出血和血栓)等挑战依然存在。计算流体动力学(CFD)模拟有助于了解 VAD 的流动动力学以及 VAD 中非生理流动条件导致的相关流动诱发不良事件。本研究旨在 Hahne 等人奠定的基础上,验证关键 CFD 模拟参数,以准确模拟与心血管系统相互作用的 VAD。系统地改变了网格大小、时间步长和模拟方法(URANS、LES),以评估它们对 HeartMate 3 动态泵性能(动态 H-Q 曲线)的影响,目的是找到精确再现动态 H-Q 曲线的最佳模拟配置。开发并应用了新的重叠率(OR)方法来量化动态 H-Q 曲线。因此,建议采用小时间步长和大网格尺寸来获得精确的动态 H-Q 曲线。另一方面,本研究中模拟方法的影响并不显著。这项研究有助于推进 VAD 模拟,最终提高临床疗效和患者预后。
Dynamic VAD simulations: Performing accurate simulations of ventricular assist devices in interaction with the cardiovascular system.
Medical advancements, particularly in ventricular assist devices (VADs), have notably advanced heart failure (HF) treatment, improving patient outcomes. However, challenges such as adverse events (strokes, bleeding and thrombosis) persist. Computational fluid dynamics (CFD) simulations are instrumental in understanding VAD flow dynamics and the associated flow-induced adverse events resulting from non-physiological flow conditions in the VAD.This study aims to validate critical CFD simulation parameters for accurate VAD simulations interacting with the cardiovascular system, building upon the groundwork laid by Hahne et al. A bidirectional coupling technique was used to model dynamic (pulsatile) flow conditions of the VAD CFD interacting with the cardiovascular system. Mesh size, time steps and simulation method (URANS, LES) were systematically varied to evaluate their impact on the dynamic pump performance (dynamic curve) of the HeartMate 3, aiming to find the optimal simulation configuration for accurately reproduce the dynamic curve. The new Overlapping Ratio (OR) method was developed and applied to quantify dynamic curves.In particular, mesh and time step sizes were found to have the greatest influence on the calculated pump performance. Therefore, small time steps and large mesh sizes are recommended to obtain accurate dynamic curves. On the other hand, the influence of the simulation method was not significant in this study. This study contributes to advancing VAD simulations, ultimately enhancing clinical efficacy and patient outcomes.
期刊介绍:
The International Journal of Artificial Organs (IJAO) publishes peer-reviewed research and clinical, experimental and theoretical, contributions to the field of artificial, bioartificial and tissue-engineered organs. The mission of the IJAO is to foster the development and optimization of artificial, bioartificial and tissue-engineered organs, for implantation or use in procedures, to treat functional deficits of all human tissues and organs.