肺动脉的计算模拟及其在小儿肺动脉高压研究中的作用
Computational Simulation of the Pulmonary Arteries and its Role in the Study of Pediatric Pulmonary Hypertension.
作者信息
Hunter Kendall S, Feinstein Jeffrey A, Ivy D Dunbar, Shandas Robin
机构信息
Department of Bioengineering, University of Colorado at Denver Anschutz Medical Campus (UCD-AMC), Aurora, CO, USA.
出版信息
Prog Pediatr Cardiol. 2010 Dec 1;30(1-2):63-69. doi: 10.1016/j.ppedcard.2010.09.008.
Abstract
The hemodynamic state of the pulmonary arteries is challenging to routinely measure in children due to the vascular circuit's position in the lungs. The resulting relative scarcity of quantitative clinical diagnostic and prognostic information impairs management of diseases such as pulmonary hypertension, or high blood pressure of the pulmonary circuit, and invites new techniques of measurement. Here we examine recent applications of macro-scale computational mechanics methods for fluids and solids - traditionally used by engineers in the design and virtual testing of complex metal and composite structures - applied to study the pulmonary vasculature, both in healthy and diseased states. In four subject areas, we briefly outline advances in computational methodology and provide examples of clinical relevance.
摘要
由于肺动脉血管回路位于肺部,常规测量儿童肺动脉的血流动力学状态具有挑战性。由此导致的定量临床诊断和预后信息相对匮乏,影响了对诸如肺动脉高压(即肺循环高血压)等疾病的管理,并催生了新的测量技术。在此,我们研究了宏观尺度计算力学方法在流体和固体方面的最新应用——这些方法传统上由工程师用于复杂金属和复合结构的设计及虚拟测试——并将其应用于研究健康和患病状态下的肺血管系统。在四个主题领域,我们简要概述了计算方法的进展,并提供了临床相关性示例。
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