声衰减:多频测量与 CT 和 MR 成像的关系。
Acoustic Attenuation: Multifrequency Measurement and Relationship to CT and MR Imaging.
出版信息
IEEE Trans Ultrason Ferroelectr Freq Control. 2021 May;68(5):1532-1545. doi: 10.1109/TUFFC.2020.3039743. Epub 2021 Apr 26.
Abstract
Transcranial magnetic resonance-guided focused ultrasound (tcMRgFUS) is gaining significant acceptance as a noninvasive treatment for motion disorders and shows promise for novel applications such as blood-brain barrier opening for tumor treatment. A typical procedure relies on CT-derived acoustic property maps to simulate the transfer of ultrasound through the skull. Accurate estimates of the acoustic attenuation in the skull are essential to accurate simulations, but there is no consensus about how attenuation should be estimated from CT images and there is interest in exploring MR as a predictor of attenuation in the skull. In this study, we measure the acoustic attenuation at 0.5, 1, and 2.25 MHz in 89 samples taken from two ex vivo human skulls. CT scans acquired with a variety of X-ray energies, reconstruction kernels, and reconstruction algorithms, and MR images acquired with ultrashort and zero echo time sequences are used to estimate the average Hounsfield unit value, MR magnitude, and T2 value in each sample. The measurements are used to develop a model of attenuation as a function of frequency and each individual imaging parameter.
摘要
经颅磁共振引导聚焦超声(tcMRgFUS)作为一种非侵入性治疗运动障碍的方法,越来越受到人们的认可,并在血脑屏障开放治疗肿瘤等新应用方面显示出前景。典型的程序依赖于 CT 衍生的声学特性图来模拟超声穿过颅骨的传输。准确估计颅骨中的声衰减对于准确的模拟至关重要,但对于如何从 CT 图像估计衰减还没有共识,并且人们对探索 MR 作为颅骨衰减的预测因子很感兴趣。在这项研究中,我们测量了从两个离体人头骨中取出的 89 个样本在 0.5、1 和 2.25 MHz 下的声衰减。使用不同的 X 射线能量、重建核和重建算法获取 CT 扫描,以及使用超短和零回波时间序列获取 MR 图像,以估计每个样本中的平均亨氏单位值、MR 幅度和 T2 值。这些测量结果用于开发一个衰减模型,作为频率和每个单独成像参数的函数。
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