Computational predictions of magnetic resonance acoustic radiation force imaging for breast cancer focused ultrasound therapy.

IF 3 3区医学 Q2 ONCOLOGY

International Journal of Hyperthermia Pub Date : 2025-12-01 Epub Date: 2025-01-22 DOI:10.1080/02656736.2025.2452927

Chloe K Nelson, Michelle Kline, Allison Payne, Christopher R Dillon

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引用次数: 0

Abstract

Purpose: In magnetic resonance-guided focused ultrasound (MRgFUS) breast therapies, the focal location must be characterized to guide successful treatment. Focal characterization is difficult because heterogeneous breast tissues introduce phase aberrations that blur and shift the focus and traditional guidance methods do not work in adipose tissues. The purpose of this work is to evaluate numerical simulations of MRgFUS that predict the focal location. Those simulations are compared to clinical magnetic resonance acoustic radiation force imaging (MR-ARFI) data collected during in vivo treatment of breast tumors.

Methods: The focal location was evaluated before MRgFUS treatment with MR-ARFI in five patients. The hybrid angular spectrum method (HAS) was applied to simulate pressure fields which were converted to forces, then convolved with a 3D Green's function (with time-of-arrival weighting) to produce a simulation of the MR-ARFI tissue displacement.

Results: The focal locations found by the simulations and the MR-ARFI measurements were on average separated by 3.7 mm (SD: 0.9 mm). Characterization of the focal zone spatial distributions had a normalized root mean squared difference of 8.1% (SD: 2.5%). The displacement magnitudes of the simulations underestimated the MR-ARFI measurements by 82% (SD: 5.6%).

Conclusions: The agreement between MR-ARFI measurements and simulations demonstrates that HAS can predict the in vivo focal location in heterogeneous tissues, though accurate patient-specific properties are needed to improve predictions of tissue displacement magnitude. Tools developed in this study could be used to streamline MRgFUS treatment planning and optimization, for biomechanical property estimation, and in developing phase aberration correction techniques.

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磁共振声辐射力成像用于乳腺癌聚焦超声治疗的计算预测。

目的：在磁共振引导聚焦超声（MRgFUS）乳房治疗中，必须确定病灶位置以指导成功治疗。病灶表征是困难的，因为异质乳腺组织会引入相位像差，使焦点模糊和移动，而传统的引导方法在脂肪组织中不起作用。这项工作的目的是评估MRgFUS预测震源位置的数值模拟。这些模拟与乳腺肿瘤体内治疗期间收集的临床磁共振声辐射力成像（MR-ARFI）数据进行了比较。方法：对5例患者进行MRgFUS治疗前的病灶位置进行评估。采用混合角谱法（HAS）模拟压力场，将压力场转化为力，然后与三维格林函数（带到达时间加权）卷积，得到MR-ARFI组织位移的模拟。结果：模拟得到的焦点位置与MR-ARFI测量的平均距离为3.7 mm （SD: 0.9 mm）。焦区空间分布特征的标准化均方根差为8.1% （SD: 2.5%）。模拟的位移幅度低估了MR-ARFI测量值的82% （SD: 5.6%）。结论：MR-ARFI测量和模拟之间的一致性表明，HAS可以预测异质组织中的体内病灶位置，尽管需要准确的患者特异性特性来改进组织位移幅度的预测。本研究开发的工具可用于简化MRgFUS治疗计划和优化，用于生物力学性能估计，以及开发相位像差校正技术。

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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