用于高场磁共振成像中射频多发射技术的超快电磁场计算

Ultra fast electromagnetic field computations for RF multi-transmit techniques in high field MRI.

作者信息

van den Bergen Bob, Stolk Christiaan C, Berg Jan Bouwe van den, Lagendijk Jan J W, Van den Berg Cornelis A T

机构信息

Department of Radiotherapy, University Medical Center Utrecht, Utrecht, The Netherlands.

出版信息

Phys Med Biol. 2009 Mar 7;54(5):1253-64. doi: 10.1088/0031-9155/54/5/010. Epub 2009 Jan 30.

DOI:10.1088/0031-9155/54/5/010

PMID:19182321

Abstract

A new, very fast, approach for calculations of the electromagnetic excitation field for MRI is presented. The calculation domain is divided in different homogeneous regions, where for each region a general solution is obtained by a summation of suitable basis functions. A unique solution for the electromagnetic field is found by enforcing the appropriate boundary conditions between the different regions. The method combines the speed of an analytical method with the versatility of full wave simulation methods and is validated in the pelvic region against FDTD simulations at 3 and 7 T and measurements at 3 T. The high speed and accurate reproduction of measurements and FDTD calculations are believed to offer large possibilities for multi-transmit applications, where it can be used for on-line control of the global and local electric field and specific absorption rate (SAR) in the patient. As an example the method was evaluated for RF shimming with the use of 7 T simulation results, where it was demonstrated that the magnetic excitation field could be homogenized, while both the local and average SAR were reduced by 38% or more.

摘要

本文提出了一种全新的、速度极快的用于磁共振成像（MRI）电磁激发场计算的方法。计算域被划分为不同的均匀区域，对于每个区域，通过合适的基函数求和得到通解。通过在不同区域之间施加适当的边界条件，找到电磁场的唯一解。该方法将解析方法的速度与全波模拟方法的通用性相结合，并在盆腔区域针对3T和7T的时域有限差分法（FDTD）模拟以及3T的测量结果进行了验证。该方法的高速性以及对测量和FDTD计算的精确再现，被认为为多发射应用提供了巨大可能性，在多发射应用中，它可用于在线控制患者体内的全局和局部电场以及比吸收率（SAR）。作为一个例子，利用7T模拟结果对该方法进行了射频匀场评估，结果表明，磁激发场可以被均匀化，同时局部和平均SAR降低了38%或更多。

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用于高场磁共振成像中射频多发射技术的超快电磁场计算

Ultra fast electromagnetic field computations for RF multi-transmit techniques in high field MRI.

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