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喷射辅助Fontan循环中夹带特性的体外和计算机模拟分析

In Vitro and In Silico Analysis of Entrainment Characterization in Injection Jet-Assisted Fontan Circulation.

作者信息

Das Arka, Prather Ray O, Damon Anthony, Farias Michael, Kassab Alain, Divo Eduardo, DeCampli William

机构信息

Department of Mechanical Engineering, Embry-Riddle Aeronautical University, Daytona Beach, FL 32114, USA.

Department of Mechanical and Aerospace Engineering, University of Central Florida, Orlando, FL 32816, USA.

出版信息

Bioengineering (Basel). 2025 May 21;12(5):555. doi: 10.3390/bioengineering12050555.

DOI:10.3390/bioengineering12050555
PMID:40428174
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC12109436/
Abstract

Fontan circulation is a fragile system in which imperfections at any of multiple levels may compromise the quality of life, produce secondary pathophysiology, and shorten life span. Increased inferior vena caval pressure itself may play a role in "Fontan failure". This study describes a mock flow loop model (MFL) designed to quantitatively estimate pulmonary flow entrainment induced by continuous and pulsed flow injections. A patient generic 3D-printed phantom model of the total cavopulmonary connection (TCPC) with average dimensions matching those of a 2-4-year-old patient was inserted in an MFL derived from a reduced lumped parameter model (LPM) representing cardiovascular circulation. The LPM comprises four 2-element Windkessel compartments (compliance and resistance), approximating the upper and lower systemic circulations and the right and left pulmonary circulations. The prescribed cardiac output is about 2.3 L/min for a body surface area of 0.675 m2. The injections originate from an external pump through a 7-9 fr catheter, following a strict protocol suggested by the clinical team, featuring a variation in injection rate (flow rate), injection volume, and injection modality (continuous or pulsed). The key measurements in this study are the flow rates sampled at the distal pulmonary arteries, as well as at the upper and lower body boundaries. These measurements were then used to calculate effective entrainment as the difference between the measured and expected flow rates, as well as jet relaxation (rise and fall time of injection). The results show that for continuous or pulsed injections, varying the total volume injected has no significant influence on the entrainment rate across all injection rates. On the other hand, for both injection modalities, increasing the injection rate results in a reduction in entrainment that is consistent across all injected volumes. This study demonstrates the effectiveness of a high-speed injection jet entraining a slow co-flow while determining the potential for fluid buildup, which could ultimately cause an increase in caval pressure. To avoid the increase in caval pressure due to mass accumulation, we added a fenestration to our proposed injection jet shunt-assisted Fontan models. It was found that for a set of well-defined parameters, the jet not only can be beneficial to the local flow, but any adverse effect can be obviated by careful tuning. These results were also cross-validated with similar in silico findings.

摘要

Fontan循环是一个脆弱的系统,其中多个层面的任何缺陷都可能影响生活质量,产生继发性病理生理学变化,并缩短寿命。下腔静脉压力升高本身可能在“Fontan循环衰竭”中起作用。本研究描述了一种模拟血流回路模型(MFL),旨在定量评估连续和脉冲流注射引起的肺血流夹带情况。将一个患者通用的3D打印的全腔肺连接(TCPC)体模模型插入到一个由简化集总参数模型(LPM)衍生而来的MFL中,该体模平均尺寸与2至4岁患者的尺寸匹配,该LPM代表心血管循环。LPM包括四个双元件风箱腔室(顺应性和阻力),分别近似上、下体循环以及左右肺循环。对于体表面积为0.675平方米的情况,规定的心输出量约为2.3升/分钟。注射通过一根7-9F的导管由外部泵进行,遵循临床团队建议的严格方案,其特点是注射速率(流速)、注射量和注射方式(连续或脉冲)有所变化。本研究的关键测量指标是在远端肺动脉以及上、下体边界处采集的流速。然后利用这些测量结果计算有效夹带量,即测量流速与预期流速之差,以及射流弛豫(注射的上升和下降时间)。结果表明,对于连续或脉冲注射,在所有注射速率下,改变注射总量对夹带率没有显著影响。另一方面,对于两种注射方式,提高注射速率都会导致夹带量减少,且在所有注射量下都是一致的。本研究证明了高速注射射流夹带缓慢并流的有效性,同时确定了液体蓄积的可能性,这最终可能导致腔静脉压力升高。为避免因质量积累导致腔静脉压力升高,我们在提出的注射射流分流辅助Fontan模型中增加了一个开窗。结果发现,对于一组明确的参数,射流不仅对局部血流有益,而且通过仔细调整可以消除任何不良影响。这些结果也与类似的计算机模拟结果进行了交叉验证。

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