Measurement System for Compliance in Tubular Structures

Ave Kludze, Anthony D’Amato, Yadong Wang
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Abstract

Tubular structures such as blood vessels, intestines, and the trachea are common in various life forms. This paper describes a measurement system to test the mechanical compliance of tubular structures. The novelty of the system lies in its hardware and software. Here we use vascular graft as an example to demonstrate the utility of the system. A fully synthetic vascular graft would ideally mimic the mechanical and architectural properties of a native blood vessel. Therefore, mechanical testing of the graft material under physiological pressure is crucial to characterizing its potential in vivo performance. The device operates through a low-cost Arduino-based control system that simulates and measures cyclic fluid pressure changes over time and a laser micrometer that measures diameter changes with pressure. This system is low-cost, assuming one already has access to a laser micrometer. In contrast to previous methods, this system offers a simple, low-cost, and customizable option to measure compliance and is equipped with data acquisition/analysis programs. These programs include a MATLAB application that processes and synchronizes Arduino Uno pressure signals and LabChart Pro diameter readings. Lastly, this paper explains the hardware and software of the measurement system. The system is beneficial for testing the pressure-diameter relationship of tubular structures of varying sizes and materials. KEYWORDS: Tubular Structures; Compliance; Data Acquisition System; Physiological Pressure; Diameter Change; Arduino Uno; LabChart Pro; MATLAB
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管状结构顺应性测量系统
血管、肠道和气管等管状结构在各种生命形式中都很常见。本文介绍了一种测试管状结构机械顺应性的测量系统。该系统的新颖之处在于其硬件和软件。在此,我们以血管移植为例,展示该系统的实用性。理想情况下,全合成血管移植物能模拟原生血管的机械和结构特性。因此,在生理压力下对移植物材料进行机械测试对于鉴定其潜在的体内性能至关重要。该装置通过一个基于 Arduino 的低成本控制系统运行,该系统可模拟和测量随时间变化的循环流体压力变化,而激光测微计则可测量直径随压力的变化。该系统成本低廉,假设人们已经有了激光测微计。与之前的方法相比,该系统提供了一种简单、低成本、可定制的测量顺应性的方法,并配备了数据采集/分析程序。这些程序包括一个 MATLAB 应用程序,用于处理和同步 Arduino Uno 压力信号和 LabChart Pro 直径读数。最后,本文介绍了测量系统的硬件和软件。该系统有利于测试不同尺寸和材料的管状结构的压力-直径关系。关键词: 管状结构;顺应性;数据采集系统;生理压力;直径变化;Arduino Uno;LabChart Pro;MATLAB
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