基于核磁共振植入微线圈有限元法的脑数值模型应用对比研究

2019 IEEE International Conference on Design & Test of Integrated Micro & Nano-Systems (DTS) Pub Date : 2019-04-01 DOI:10.1109/DTSS.2019.8914833

N. Mansour, C. Dridi, N. Yaakoubi, L. Fakri-Bouchet

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引用次数: 0

摘要

本研究对四种平面微线圈模型(方形、圆形、矩形和TLMR(传输线单片谐振器))的磁性参数、质量因子、生物相容性和无害性进行了数值研究。这些平面微线圈模型作为专用于核磁共振(NMR)光谱的射频(RF)植入式接收器天线的有源部分进行了仿真。该方法的新颖之处在于，采用一种将EM(电磁)仿真与实现FEM(有限单元法)计算的RLC等效模型相结合的混合方法对这些不同形状进行比较研究。实现工作的第二部分是在数值模拟中植入最佳微线圈。然后，通过数值头部模型的预测模拟，保证了微线圈植入核磁共振研究的无害性。

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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NMR Implantable Microcoil FEM Based Comparative Study for Numerical Brain Model Application

This work investigates numerically four planar microcoil models (square, circular, rectangular and TLMR (Transmission Line Monolithic Resonator)) in terms of magnetic parameters, quality factor, biocompatibility, and harmlessness. These Planar microcoil models were simulated as the active part of a radio frequency (RF) implantable receiver antenna dedicated to the Nuclear Magnetic Resonance (NMR) Spectroscopy. The novelty provided by this approach is the comparative study of these different shapes by a hybrid method combining EM (Electromagnetic) simulation and RLC equivalent model calculated through implemented FEM (Finite Element Method). The second part of the realized work is the implantation of the best microcoils in a numerical phantom. Then, assuring the harmlessness of the implantation of such microcoils for NMR investigations by predictive simulation in numerical head model.

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来源期刊

2019 IEEE International Conference on Design & Test of Integrated Micro & Nano-Systems (DTS)

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