Contactless measurement of thoracic conductivity changes by magnetic induction

Proceedings of the 19th Annual International Conference of the IEEE Engineering in Medicine and Biology Society. 'Magnificent Milestones and Emerging Opportunities in Medical Engineering' (Cat. No.97CH36136) Pub Date : 1997-10-30 DOI:10.1109/IEMBS.1997.756820

R. Guardo, G. Charron, Y. Goussard, P. Savard

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引用次数: 10

Abstract

A noninvasive technique of measuring thoracic conductivity changes caused by respiration and cardiac activity is described. Conductivity is measured with a hand-held sensor comprising a planar coil, a radio-frequency (RF) oscillator and a closed-loop control system to hold constant the amplitude of oscillations. This system automatically compensates for changes in the power dissipated by eddy-currents in the thorax by adjusting the RF current driven into the coil. This results in the control signal being proportional to the conductivity of the thorax. Simulations with a thorax model consisting of four eccentric spheres were used to determine the magnitude of changes for a range of tidal volumes and stroke volumes. The importance of tissue properties, such as lung conductivity and hematocrit was assessed. Finally, an example of signals recorded in-vivo with the sensor is presented. Use of this technique to monitor cardiac output would require a one-time measurement of geometrical data specific to the patient's thorax (e.g. the distance between the heart and the body-surface), in order to transform measured cardiosynchronous conductivity changes into stroke volume.

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通过磁感应非接触测量胸廓电导率变化

描述了一种无创测量呼吸和心脏活动引起的胸电导率变化的技术。电导率是用手持传感器测量的，该传感器包括一个平面线圈，一个射频振荡器和一个闭环控制系统，以保持振荡幅度恒定。该系统通过调节驱动到线圈中的射频电流，自动补偿胸腔中涡流耗散的功率变化。这导致控制信号与胸腔的电导率成正比。用一个由四个偏心球体组成的胸腔模型进行模拟，以确定潮汐体积和冲程体积范围的变化幅度。评估组织特性的重要性，如肺电导率和红细胞压积。最后，给出了用传感器在体内记录信号的一个例子。使用这种技术来监测心输出量需要一次性测量患者胸腔特定的几何数据(例如心脏与体表之间的距离)，以便将测量到的心同步电导率变化转化为搏量。

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 the 19th Annual International Conference of the IEEE Engineering in Medicine and Biology Society. 'Magnificent Milestones and Emerging Opportunities in Medical Engineering' (Cat. No.97CH36136)

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