Transit time spectrum dependence upon ultrasound input wave types propagating through complex structures

Journal of Umm Al-Qura University for Medical Sciences Pub Date : 2023-05-22 DOI:10.54940/ms45313008

S. Al-Qahtani, Ali Alomary, Marwan A. M. Althomali

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Abstract

Background: Ultrasound transit time spectroscopy (UTTS) has been introduced previously to characterize the propagation of ultrasound waves through complex structures such as cancellous bone to estimate bone quality and quantity. UTTS describes the propagation of ultrasonic waves through a medium with two components of differing sound speeds (e.g., bone and marrow) as a set of parallel sonic rays. The transit time spectrum (TTS) is derived via the digital deconvolution of the input and output signals. Aim: To investigate the dependence of TTS upon the type of ultrasound input wave, including four different 1 MHz ultrasound waves (pulse, chirp, tone-burst, and continuous). Methods: The presence of ischemic lesions was detected by the MDCT, transesophageal echocardiography (TEE), and non-contrast flat detector computed tomography (FDCT). The study selected the AIS patients with hyperacute stroke for less than 6 hours from July 2021 to August 2022. The CTA of cervical arteries was performed in order to determine stroke subtypes.Ten replica 3D- acrylic step-wedge models with different structure complexity were investigated. For each model and using the four types of input waves, TTS was derived and compared with calculated TTS based on the parallel sonic ray concept. Results: The results showed coefficients of determination (R2) of 0.994, 0.999, 0.90, and 1 for pulse, chirp, tone-burst and continuous signals respectively. Furthermore, solid volume fraction (SVF) was derived via TTS (TTS-SVF) and compared with the geometrically calculated SVF data of the models, yielding coefficients of determination (R2) of 0.941, 0.968, 0.489, and 0.981 for pulse, chirp, tone-burst and continuous waves, respectively. Therefore, the continuous wave provided a more accurate prediction of TTS and SVF, followed by chirp, then pulse waves. Conclusion: This study adds to the body of research supporting the validity and reliability of UTTS, as a potentially promising technique to provide a reliable in vivo estimate of bone mineral density.

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通过复杂结构传播的超声输入波类型对传输时间谱的依赖

背景:超声传输时间光谱(UTTS)以前已经被引入来表征超声波通过复杂结构(如松质骨)的传播，以估计骨的质量和数量。UTTS描述了超声波通过具有不同声速的两种成分的介质(例如，骨头和骨髓)作为一组平行声波射线的传播。通过对输入和输出信号进行数字反卷积，得到了传输时间谱(TTS)。目的:探讨TTS与超声输入波类型的关系，包括4种不同的1 MHz超声输入波(脉冲、啁啾、音调突发和连续)。方法:采用MDCT、经食管超声心动图(TEE)和非对比平面计算机断层扫描(FDCT)检测缺血性病变的存在。本研究选取了2021年7月至2022年8月期间超过6小时的AIS超急性卒中患者。为确定脑卒中亚型，行颈动脉CTA检查。研究了10个结构复杂程度不同的三维丙烯酸台阶楔模型。针对每种模型，使用四种类型的输入波，推导了TTS，并与基于平行声线概念的计算TTS进行了比较。结果:脉冲信号、啁啾信号、突音信号和连续信号的决定系数(R2)分别为0.994、0.999、0.90和1。通过TTS (TTS-SVF)计算得到固体体积分数(SVF)，并与模型几何计算的SVF数据进行比较，脉冲波、啁啾波、音调突发波和连续波的屈服决定系数(R2)分别为0.941、0.968、0.489和0.981。因此，连续波可以更准确地预测TTS和SVF，其次是啁啾，最后是脉冲波。结论:本研究增加了支持UTTS的有效性和可靠性的研究，作为一种潜在的有前途的技术，可以提供可靠的体内骨矿物质密度估计。

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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Journal of Umm Al-Qura University for Medical Sciences

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