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一种用于在磁共振成像(MRI)期间独立测量平均比吸收率(SAR)的射频剂量计原型。

A prototype RF dosimeter for independent measurement of the average specific absorption rate (SAR) during MRI.

作者信息

Stralka John P, Bottomley Paul A

机构信息

Department of Electrical and Computer Engineering, Johns Hopkins University, Baltimore, Maryland 21287, USA.

出版信息

J Magn Reson Imaging. 2007 Nov;26(5):1296-302. doi: 10.1002/jmri.21141.

DOI:10.1002/jmri.21141
PMID:17969145
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2586170/
Abstract

PURPOSE

To develop a scanner-independent dosimeter for measuring the average radio frequency (RF) power deposition and specific absorption rates (SAR) for human MRI exposure.

MATERIALS AND METHODS

A prototype dosimeter has a transducer with orthogonal conducting loops surrounding a small signal-generating MRI sample. The loops contain resistors whose values are adjusted to load the scanner's MRI coils equivalent to an average head or body during MRI. The scanner adjusts its power output to normal levels during setup, using the MRI sample. Following calibration, the total power and average SAR deposited in the transducer are measured from the root-mean-square (rms) power induced in the transducer during MRI.

RESULTS

A 1.5 Tesla head transducer was adjusted to elicit the same load as the average of nine adult volunteers. Once adjusted, the transducer loads other head coils the same as the head does. The dosimeter is calibrated at up to 20 W total deposited power and 4.5 W/kg SAR in the average head, with about 5% accuracy.

CONCLUSION

This dosimeter provides a simple portable means of measuring the power deposited in a body-equivalent sample load, independent of the scanner. Further work will develop SAR dosimetry for the torso and for higher fields.

摘要

目的

开发一种与扫描仪无关的剂量计,用于测量人体磁共振成像(MRI)暴露时的平均射频(RF)功率沉积和比吸收率(SAR)。

材料与方法

一种原型剂量计有一个换能器,其周围环绕着小信号生成MRI样本的正交导电环。这些环包含电阻器,其阻值经调整后可在MRI期间使扫描仪的MRI线圈负载相当于平均头部或身体的负载。在设置过程中,扫描仪使用MRI样本将其功率输出调整到正常水平。校准后,在MRI期间从换能器中感应出的均方根(rms)功率测量沉积在换能器中的总功率和平均SAR。

结果

一个1.5特斯拉的头部换能器被调整到与九名成年志愿者的平均值相同的负载。一旦调整好,该换能器对其他头部线圈的负载与头部相同。该剂量计在平均头部中总沉积功率高达20瓦和SAR为4.5瓦/千克的情况下进行校准,精度约为5%。

结论

这种剂量计提供了一种简单便携的方法,可测量沉积在等效人体样本负载中的功率,且与扫描仪无关。进一步的工作将开发针对躯干和更高场强的SAR剂量测定法。

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