Fluid Flow Analysis of Neonatal Dual-Lumen Cannulas for Venovenous Extracorporeal Membrane Oxygenation.

IF 1.7 4区 医学 Q4 BIOPHYSICS
Danielle M Sawka, Yunxing Su, Julie Monteagudo, Roberto Zenit
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引用次数: 0

Abstract

Hemolysis persists as a common and serious problem for neonatal patients on extracorporeal membrane oxygenation (ECMO). Since the cannula within the ECMO circuit is associated with hemolysis-inducing shear stresses, real-world internal fluid flow measurements are urgently needed to understand the mechanism and confirm computational estimates. This study appears to be the first experimental study of fluid flow inside commercial ECMO dual-lumen cannulas (DLCs) and first particle image velocimetry (PIV) visualization inside a complicated medical device. The internal geometries of four different opaque neonatal DLCs, both atrial and bicaval positioning geometries each sized 13 Fr and 16 Fr, were replicated by three-dimensional printing clear lumen scaled-up models, which were integrated in a circuit with appropriate ECMO flow parameters. PIV was then used to visualize two-dimensional fluid flow in a single cross section within the models. An empirical model accounting for shear stress and exposure time was used to compare the maximum expected level of hemolysis through each model. The maximum measured peak shear stress recorded was 16±2 Pa in the top arterial bicaval 13 Fr model. The atrial and 16 Fr cannula models never produced greater single-pass peak shear stress or hemolysis than the bicaval and 13 Fr models, respectively, and no difference was found in hemolysis at two different flow rates. After 5 days of flow, small DLC-induced hemolysis values for a single pass through each cannula were modeled to linearly accumulate and caused the most severe hemolysis in the bicaval 13 Fr DLC. Engineering and clinical solutions to improve cannula safety are proposed.

用于静脉体外膜氧合的新生儿双腔套管的流体流量分析。
溶血一直是体外膜肺氧合(ECMO)新生儿患者常见的严重问题。由于 ECMO 循环内的插管与溶血引起的剪切应力有关,因此急需进行实际内部流体流动测量,以了解其机理并确认计算估计值。这项研究似乎是对商用 ECMO 双腔套管(DLC)内部流体流动的首次实验研究,也是首次对复杂医疗设备内部进行粒子图像测速(PIV)可视化。通过三维打印透明腔体放大模型,复制了四种不同的不透明新生儿双腔套管的内部几何形状,包括心房和双腔定位几何形状,每种尺寸为 13 Fr 和 16 Fr,并将其集成到具有适当 ECMO 流量参数的回路中。然后使用 PIV 对模型内单个横截面的二维流体流动进行可视化。根据剪切应力和暴露时间建立的经验模型用于比较通过每个模型的最大预期溶血水平。在顶部动脉双腔 13 Fr 模型中记录到的最大测量峰值剪应力为 16±2 Pa。心房插管和 16 Fr 插管模型产生的单次峰值剪切应力或溶血量从未分别超过双腔插管和 13 Fr 插管模型,而且在两种不同流速下的溶血量也未发现差异。经过5天的流动后,每种插管单次通过时的微小DLC诱导溶血值被模拟为线性累积,并在双腔13 Fr DLC中造成最严重的溶血。提出了提高插管安全性的工程和临床解决方案。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
CiteScore
3.40
自引率
5.90%
发文量
169
审稿时长
4-8 weeks
期刊介绍: Artificial Organs and Prostheses; Bioinstrumentation and Measurements; Bioheat Transfer; Biomaterials; Biomechanics; Bioprocess Engineering; Cellular Mechanics; Design and Control of Biological Systems; Physiological Systems.
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