应用非消融性脉冲高强度聚焦超声时从磁共振测温估计热剂量。
Estimation of thermal dose from MR thermometry during application of nonablative pulsed high intensity focused ultrasound.
机构信息
Department of Translational Imaging, The Methodist Hospital Research Institute, Houston Texas, USA.
出版信息
J Magn Reson Imaging. 2012 May;35(5):1169-78. doi: 10.1002/jmri.23526. Epub 2011 Dec 14.
Abstract
PURPOSE
To evaluate whether MR thermometry is sufficiently fast, accurate, and spatially resolved for monitoring the thermal safety of nonablative pulsed high intensity ultrasound (pHIFU) treatments.
MATERIALS AND METHODS
A combination of real MR thermometry data and modeling was used to analyze the effects of temporal and spatial averaging as well as noise on the peak temperatures and thermal doses that would be measured by MR thermometry.
RESULTS
MR thermometry systematically underestimates the temperature and thermal doses during pHIFU treatment. Small underestimates of peak temperature can lead to large underestimates of thermal dose. Spatial averaging errors are small for ratios of pixel dimension to heating zone radius less than 0.25, which may be achieved by reducing the voxel size or steering the acoustic beam. Thermal dose might also be underestimated for very short, high power pulses due to temporal averaging. A simple correction factor based on the applied power and duty cycle may be applied to determine the upper bound of this effect.
CONCLUSION
The temperature and thermal dose measured using MR thermometry during pulsed HIFU treatment is probably sufficient in most instances. Simple corrections may be used to calculate an upper bound where this is a critical factor.
摘要
目的
评估磁共振测温法在监测非消融性脉冲高强度超声(pHIFU)治疗的热安全性方面是否足够快速、准确和空间分辨率高。
材料与方法
使用真实的磁共振测温数据和建模相结合的方法,分析了时间和空间平均以及噪声对磁共振测温法测量的峰值温度和热剂量的影响。
结果
磁共振测温法在 pHIFU 治疗过程中系统地低估了温度和热剂量。小的峰值温度低估会导致热剂量的大幅低估。对于像素尺寸与加热区半径之比小于 0.25 的情况,空间平均误差较小,这可以通过减小体素尺寸或引导声束来实现。由于时间平均,对于非常短的高功率脉冲,热剂量也可能被低估。可以应用基于施加功率和占空比的简单校正因子来确定这种影响的上限。
结论
在脉冲 HIFU 治疗期间使用磁共振测温法测量的温度和热剂量在大多数情况下可能是足够的。可以使用简单的校正来计算这是一个关键因素的上限。
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