B-Lines Lung Ultrasonography Simulation Using Finite Element Method.

Diagnostics (Basel, Switzerland) Pub Date : 2022-11-10 DOI:10.3390/diagnostics12112751

Fellipe Allevato Martins da Silva, Eduardo Moreno, Wagner Coelho de Albuquerque Pereira

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引用次数: 3

Abstract

Introduction: Lung Ultrasonography (LUS) is a fast technique for the diagnosis of patients with respiratory syndromes. B-lines are seen in response to signal reverberations and amplifications into sites with peripheral lung fluid concentration or septal thickening. Mathematical models are commonly applied in biomedicine to predict biological responses to specific signal parameters.

Objective: This study proposes a Finite-Element numerical model to simulate radio frequency ultrasonic lines propagated from normal and infiltrated lung structures. For tissue medium, a randomized inhomogeneous data method was used. The simulation implemented in COMSOL^® used Acoustic Pressure and Time-Explicit models, which are based on the discontinuous Galerkin method (dG).

Results: The RF signals, processed in MATLAB^®, resulted in images of horizontal A-lines and vertical B-lines, which were reasonably similar to real images.

Discussion: The use of inhomogeneous materials in the model was good enough to simulate the scattering response, similar to others in the literature. The model is useful to study the impact of the lung infiltration characteristics on the appearance of LUS images.

Abstract Image

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有限元法肺b线超声模拟。

肺超声检查(LUS)是一种快速诊断呼吸系统综合征的技术。b线可见于周围肺液浓度或间隔增厚部位的信号混响和放大。数学模型在生物医学中常用来预测对特定信号参数的生物反应。目的:建立射频超声线在正常肺组织和浸润肺组织中传播的有限元数值模型。对于组织培养基，采用随机非均匀数据方法。在COMSOL®中实现的模拟使用了基于不连续伽辽金方法(dG)的声压和时间显式模型。结果:在MATLAB®中对射频信号进行处理，得到水平a线和垂直b线的图像，与真实图像比较接近。讨论:在模型中使用非均匀材料足以模拟散射响应，类似于文献中的其他材料。该模型有助于研究肺浸润特征对LUS图像外观的影响。

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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Diagnostics (Basel, Switzerland)

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