A Novel Sensor Design and Fabrication for Wireless Interventional MRI Through Induction Coupling

2019 IEEE SENSORS Pub Date : 2019-10-01 DOI:10.1109/SENSORS43011.2019.8956525

Omar Nassar, D. Mager, J. Korvink

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引用次数: 3

Abstract

Interventional magnetic resonance imaging (iMRI) using active MR-Catheters potentially has a great impact on the field of minimally invasive medical operations. Detector coils inside the patient act as antennas, coupled to the magnetic resonance radio frequency transmit field, thereby making the catheter visible in an MR environment. The elongated transmission conductor which is attached to the coil is coupled to the RF field as well. This coupling heats the conductor, causing dangerous tissues heating, which has hindered the clinical use of MR-catheters up to now. Transmitting the signal wirelessly through induction coupling, between the coil on the catheter’s tip and a surface coil outside the patient, is a feasible way to avoid using the conductive transmission wire. However, induction coupling still encounters problems regarding catheter orientation and frequency splitting. The purpose of this work is to present a mathematical model for the frequency splitting to facilitate the matching and tuning processes. Also, to propose a novel design of two perpendicular uncoupled coils on the catheter tip to keep coupling at all orientations. These coils were fabricated with a multilayer fabrication process for flexible electronics on the microscale.

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一种新型感应耦合无线介入MRI传感器的设计与制造

采用主动磁共振导管的介入磁共振成像技术(iMRI)在微创医学手术领域具有潜在的巨大影响。患者体内的探测器线圈充当天线，与磁共振射频传输场耦合，从而使导管在磁共振环境中可见。连接在线圈上的细长传输导体也耦合到射频场。这种耦合加热导体，造成危险的组织加热，至今阻碍了核磁共振导管的临床应用。通过导管尖端线圈与患者体外表面线圈之间的感应耦合无线传输信号，是避免使用导电导线的可行方法。然而，感应耦合仍然遇到导管定向和频率分裂的问题。本工作的目的是提出一个数学模型的频率分裂，以方便匹配和调谐过程。同时，提出了一种新颖的设计，在导管尖端的两个垂直的不耦合线圈，以保持在所有方向上的耦合。这些线圈是用微尺度柔性电子器件的多层制造工艺制造的。

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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2019 IEEE SENSORS

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