Determining EMC Test Levels for Implantable Devices in Bipolar Lead Configuration.

Q4 Medicine
S. Seidman, H. Bassen
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引用次数: 0

Abstract

Certain low-frequency magnetic fields cause interference in implantable medical devices. Electromagnetic compatibility (EMC) standards prescribe injecting voltages into a device under evaluation to simplify testing while approximating or simulating real-world exposure situations to low-frequency magnetic fields. The EMC standard ISO 14117:2012, which covers implantable pacemakers and implantable cardioverter defibrillators (ICDs), specifies test levels for the bipolar configuration of sensing leads as being one-tenth of the levels for the unipolar configuration. The committee authoring this standard questioned this testing level difference and its clinical relevance. To evaluate this issue of EMC test levels, we performed both analytical calculations and computational modeling to determine a basis for this difference. Analytical calculations based upon Faraday's law determined the magnetically induced voltage in a 37.6-cm lead. Induced voltages were studied in a bipolar lead configuration with various spacing between a distal tip electrode and a ring electrode. Voltages induced in this bipolar lead configuration were compared with voltages induced in a unipolar lead configuration. Computational modeling of various lead configurations was performed using electromagnetic field simulation software. The two leads that were insulated, except for the distal and proximal tips, were immersed in a saline-conducting media. The leads were parallel and closely spaced to each other along their length. Both analytical calculations and computational modeling support continued use of a one-tenth amplitude reduction for testing pacemakers and ICDs in bipolar mode. The most recent edition of ISO 14117 includes rationale from this study.
确定双极引线配置中可植入器件的EMC测试等级。
某些低频磁场会对植入式医疗设备造成干扰。电磁兼容性(EMC)标准规定向评估中的设备注入电压,以简化测试,同时近似或模拟低频磁场的真实暴露情况。EMC标准ISO 14117:2012涵盖植入式起搏器和植入式心律转复除颤器(ICD),规定感应导线双极配置的测试水平为单极配置水平的十分之一。制定该标准的委员会对这种测试水平差异及其临床相关性提出了质疑。为了评估EMC测试水平的问题,我们进行了分析计算和计算建模,以确定这种差异的基础。基于法拉第定律的分析计算确定了37.6厘米导线中的磁感应电压。研究了在远端电极和环形电极之间具有不同间距的双极引线配置中的感应电压。将这种双极引线配置中感应的电压与单极引线配置中的感应电压进行比较。使用电磁场模拟软件对各种导线配置进行了计算建模。除远端和近端外,绝缘的两根导线均浸入盐水传导介质中。引线是平行的,并且沿着它们的长度彼此紧密间隔。分析计算和计算建模都支持在双极模式下继续使用十分之一的振幅降低来测试起搏器和ICD。ISO 14117的最新版本包含了这项研究的基本原理。
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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来源期刊
Biomedical Instrumentation and Technology
Biomedical Instrumentation and Technology Computer Science-Computer Networks and Communications
CiteScore
1.10
自引率
0.00%
发文量
16
期刊介绍: AAMI publishes Biomedical Instrumentation & Technology (BI&T) a bi-monthly peer-reviewed journal dedicated to the developers, managers, and users of medical instrumentation and technology.
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