Transcutaneous energy and information transfer for biomedical implants

Proceedings of 1994 20th Annual Northeast Bioengineering Conference Pub Date : 1994-03-17 DOI:10.1109/NEBC.1994.305182

R. Gaumond

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引用次数: 1

Abstract

Summary form only received as follows. Systems delivering energy and information to implanted devices via magnetic induction provide an alternative to the use of percutaneous wire leads for long-term medical implants. Design tradeoffs are governed by the conflicting demands of energy transfer efficiency, communication bandwidth, insensitivity to changes in coil coupling variation, and concerns about patient quality-of-life. Systems range in size from that of the waist-encircling transformer developed for energizing ventricular assist devices, to miniature encapsulated systems intended for intramuscular implantation via hypodermic. Information transfer bandwidth may be considerable, as in the case of the cochlear prosthesis. In high-energy transfer applications, selection of operating frequency involves tradeoffs between tissue thermal and electronic switching losses which tend to increase with frequency and losses in the tuned-circuits driving a coil which are inversely related to frequency. These systems have been in regular use since at least the time of the transcutaneously recharged pacemaker, and new applications continue to be developed.<>

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生物医学植入物的经皮能量和信息传递

汇总表只收到如下内容。通过磁感应向植入设备传递能量和信息的系统为长期医疗植入提供了经皮导线的替代方案。设计权衡是由能量传递效率、通信带宽、对线圈耦合变化的不敏感以及对患者生活质量的关注等相互冲突的需求所决定的。系统的大小范围从为心室辅助装置供电而开发的围腰变压器，到通过皮下注射用于肌肉内植入的微型封装系统。信息传输带宽可能相当大，如人工耳蜗的情况。在高能传输应用中，工作频率的选择涉及到组织热和电子开关损耗之间的权衡，这些损耗往往随着频率的增加而增加，而驱动线圈的调谐电路中的损耗与频率成反比。这些系统至少从经皮充电起搏器出现以来就一直在常规使用，而且新的应用还在继续开发。

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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Proceedings of 1994 20th Annual Northeast Bioengineering Conference

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