Sara Benouar scite author profile

Impedance Cardiography (ICG) is a non-invasive method for monitoring cardiac dynamics using Electrical Bioimpedance (EBI) measurements. Since its appearance more than 40 years ago, ICG has been used for assessing hemodynamic parameters. This paper present a measurement system based on two System on Chip (SoC) solutions and Raspberry PI, implementing both a full 3-lead ECG recorder and an impedance cardiographer, for educational and research development purposes. Raspberry PI is a platform supporting Do-It-Yourself project and education applications across the world. The development is part of Biosignal PI, an open hardware platform focusing in quick prototyping of physiological measurement instrumentation. The SoC used for sensing cardiac biopotential is the ADAS1000, and for the EBI measurement is the AD5933. The recording were wirelessly transmitted through Bluetooth to a PC, where the waveforms were displayed, and hemodynamic parameters such as heart rate, stroke volume, ejection time and cardiac output were extracted from the ICG and ECG recordings. These results show how Raspberry PI can be used for quick prototyping using relatively widely available and affordable components, for supporting developers in research and engineering education. The design and development documents, will be available on www.BiosignalPI.com, for open access under a Non Commercial-Share A like 4.0 International License.

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Systematic variability in ICG recordings results in ICG complex subtypes – steps towards the enhancement of ICG characterization

Benouar

Hafid

Attari

et al. 2018

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The quality of an impedance cardiography (ICG) signal critically impacts the calculation of hemodynamic parameters. These calculations depend solely on the identification of ICG characteristic points on the ABEXYOZ complex. Unfortunately, contrary to the relatively constant morphology of the PQRST complex in electrocardiography, the waveform morphology of ICG data is far from stationary, which causes difficulties in the accuracy of the automated detection of characteristic ICG points. This study evaluated ICG recordings obtained from 10 volunteers. The results indicate that there are several different waveforms for the ABEXYOZ complex; there are up to five clearly distinct waveforms for the ABEXYOZ complex in addition to those that are typically reported. The differences between waveform types increased the difficulty of detecting ICG points. To accurately detect all ICG points, the ABEXYOZ complex should be analyzed according to the corresponding waveform type. Acronyms and abbreviations ICG: impedance cardiography ΔZ: impedance change signal dZ/dt: the first derivative of the impedance change signal dZ/dtmax: the maximum amplitude of the dZ/dt signal, also noted as E or C points LVET (or ET): left ventricular ejection time IVRT: isovolumic relaxation time SV: stroke volume CO: cardiac output ABEXYOZ complex: characteristic points on the dZ/dt signal that constitute one heart cycle ECG: electrocardiography PEP: pre-ejection period FT: ventricular filling time STR: systolic time ratio PQRST: complex in the ECG signal, from P over Q, R and S to T ABEX: segment of an ABEXYOZ complex from A over B and E to X YOZ: segment of an ABEXYOZ complex from Y over O to Z FEM: Finite Element Method

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Simultaneous Recording of ICG and ECG Using Z-RPI Device with Minimum Number of Electrodes

et al. 2018

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Impedance cardiography (ICG) is a noninvasive method for monitoring mechanical function of the heart with the use of electrical bioimpedance measurements. This paper presents the feasibility of recording an ICG signal simultaneously with electrocardiogram signal (ECG) using the same electrodes for both measurements, for a total of five electrodes rather than eight electrodes. The device used is the Z-RPI. The results present good performance and show waveforms presenting high similarity with the different signals reported using different electrodes for acquisition; the heart rate values were calculated and they present accurate evaluation between the ECG and ICG heart rates. The hemodynamics and cardiac parameter results present similitude with the physiological parameters for healthy people reported in the literature. The possibility of reducing number of electrodes used for ICG measurement is an encouraging step to enabling wearable and personal health monitoring solutions.

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Intelligent system for detecting cardiac arrhythmia on FPGA

Zairi

Kedir-Talha

Benouar

et al. 2014

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Sara Benouar

Full Impedance Cardiography Measurement Device Using Raspberry PI3 and System-on-Chip Biomedical Instrumentation Solutions

Systematic variability in ICG recordings results in ICG complex subtypes – steps towards the enhancement of ICG characterization

Simultaneous Recording of ICG and ECG Using Z-RPI Device with Minimum Number of Electrodes

Intelligent system for detecting cardiac arrhythmia on FPGA

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