Heart monitoring using left ventricle impedance and ventricular electrocardiography in left ventricular assist device patients
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- 作者:Keun Her ; Chi Bum Ahn ; Sung Min Park ; Seong Wook Choi
- 刊名:BioMedical Engineering OnLine
- 出版年:2015
- 出版时间:December 2015
- 年:2015
- 卷:14
- 期:1
- 全文大小:3,704 KB
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15. Choi, SW, Nam, KW, Lim, KM, Shim, EB, Won, YS, Woo, HM (2014) Effect of counter-pulsation control of a pulsatile left ventricular assist device on working load variations of the native heart. BioMedical Engineering OnLine 13: pp. 35- 刊物类别:Engineering
- 出版者:BioMed Central
- ISSN:1475-925X
文摘
Background Patients who develop critical arrhythmia during left ventricular assist device (LVAD) perfusion have a low survival rate. For diagnosis of unexpected heart abnormalities, new heart-monitoring methods are required for patients supported by LVAD perfusion. Ventricular electrocardiography using electrodes implanted in the ventricle to detect heart contractions is unsuitable if the heart is abnormal. Left ventricular impedance (LVI) is useful for monitoring heart movement but does not show abnormal action potential in the heart muscle. Objectives To detect detailed abnormal heart conditions, we obtained ventricular electrocardiograms (v-ECGs) and LVI simultaneously in porcine models connected to LVADs. Methods In the porcine models, electrodes were set on the heart apex and ascending aorta for real-time measurements of v-ECGs and LVI. As the carrier current frequency of the LVI was adjusted to 30?kHz, it was easily derived from the original v-ECG signal by using a high-pass filter (cutoff: 10?kHz). In addition, v-ECGs with a frequency band of 0.1?–-20?Hz were easily derived using a low-pass filter. Simultaneous v-ECG and LVI data were compared to detect heart volume changes during the Q-T period when the heart contracted. A new real-time algorithm for comparison of v-ECGs and LVI determined whether the porcine heartbeats were normal or abnormal. Several abnormal heartbeats were detected using the LVADs operating in asynchronous mode, most of which were premature ventricle contractions (PVCs). To evaluate the accuracy of the new method, the results obtained were compared to normal ECG data and cardiac output measured simultaneously using commercial devices. Results The new method provided more accurate detection of abnormal heart movements. This method can be used for various heart diseases, even those in which the cardiac output is heavily affected by LVAD operation.