Easy Pulsatile Phantom for Teaching and Validation of Flow Measurements in Ultrasound.

Progress of Theoretical Physics Pub Date : 2016-09-01 Epub Date: 2016-07-13 DOI:10.1055/s-0042-106396

M B Rominger, E-M Müller-Stuler, M Pinto, A S Becker, K Martini, T Frauenfelder, V Klingmüller

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Abstract

Purpose: To build a simple model to teach and validate non-pulsatile and pulsatile flow quantification in ultrasound.

Materials and methods: The setting consists of the following connected components: (1) medical syringe pump producing an adjustable constant flow (ml/min), (2) modulator modifying constant flow to a reproducible pulsatile flow, (3) water tank containing a diagonal running silicone tube (0.5 mm inner diameter), and (4) a fixated ultrasound probe (L9 Linear Array 9 MHz, GE Logiq E9) measuring the flow inside the tube. Commercially available microbubbles suspended with physiological saline solution were used for ultrasonic visibility. Spectral Doppler of different flow profiles is performed.

Results: The syringe pump produces an adjustable, constant flow and serves as the reference standard. The filling volume of the tube system is 1.2 ml. Microbubbles are very well detected by ultrasound and can be used as an easy and clean blood mimicking substance. The modulator generates different physiological and pathological flow profiles. Velocities are similar to those found within human blood vessels. Thus, it is possible to train and validate flow measurements in ultrasound.

Conclusion: The model produces non-pulsatile and various pulsatile flow profiles and allows validation of flow measurements. The compact size permits easy and economic setup for flow measurements in research, skills lab and continuing education.

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用于超声流量测量教学和验证的简易脉动模型

目的：建立一个简单的模型，用于教授和验证超声非搏动和搏动血流定量：设置由以下连接部件组成：(1) 医用注射泵，产生可调节的恒定流量（毫升/分钟）；(2) 调制器，将恒定流量调制为可重现的脉动流量；(3) 水箱，内装一根斜向运行的硅胶管（内径 0.5 毫米）；(4) 固定式超声探头（L9 线性阵列 9 MHz，GE Logiq E9），测量管内的流量。超声波可见度使用的是悬浮在生理盐水中的市售微气泡。对不同的流量剖面进行了频谱多普勒测量：注射泵可产生可调节的恒定流量，并可作为参考标准。试管系统的填充量为 1.2 毫升。微气泡能很好地被超声波检测到，可用作简便、清洁的血液模拟物质。调制器可产生不同的生理和病理血流曲线。其流速与人体血管内的流速相似。因此，在超声波中训练和验证血流测量是可能的：结论：该模型可产生非脉冲和各种脉冲血流曲线，并可对血流测量进行验证。该模型体积小巧，便于在研究、技能实验室和继续教育中进行经济实惠的流量测量设置。

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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Progress of Theoretical Physics 物理-物理：综合

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4-8 weeks