Ultra-High-Frequency Electrocardiography

P. Jurak; P. Leinveber; F. Plesinger; K. Curila; I. Viscor; V. Vondra; M. Matejkova; L. Znojilova; R. Smisek; J. Lipoldova; F.W. Prinzen; J. Halamek

doi:10.23919/CinC53138.2021.9662795

Ultra-High-Frequency Electrocardiography

P. Jurak^*, P. Leinveber, F. Plesinger, K. Curila, I. Viscor, V. Vondra, M. Matejkova, L. Znojilova, R. Smisek, J. Lipoldova, F.W. Prinzen, J. Halamek

^*Corresponding author for this work

Research output: Chapter in Book/Report/Conference proceeding › Conference article in proceeding › Academic › peer-review

Abstract

Background: We introduce a new technology that uses the ultra-high-frequency components (150-1000 Hz) of the electrocardiogram (UHF-ECG).Method: The UHF-ECG components represent weak signals generated by the depolarization of myocardial cells. The amplitude of UHF oscillations decreases with distance from the source. This property and the different timing of depolarization in the ventricles' volume enable mapping of the ventricular activation from the chest ECG leads. Because of a low signal-to-noise ratio of UHF oscillations, averaging must be performed. Single recording thus lasts 30 seconds and more.Results: UHF-ECG defines the time-spatial distribution of myocardial electrical activity. Corresponding numerical parameters are electrical dyssynchrony (e-DYS) and the duration of local depolarization (Vd). UHF ventricular depolarization maps present details of electrical activation.Conclusion: The UHF-ECG uses a new source of information originating in ventricular volumes that is different from the standard ECG. It provides information about the volumetric electrical activation associated with mechanical contraction. Its primary clinical utilization is in cardiac resynchronization, pacing optimization, and conduction system pacing.

Original language	English
Title of host publication	2021 COMPUTING IN CARDIOLOGY (CINC)
Publisher	IEEE
Number of pages	4
DOIs	https://doi.org/10.23919/CinC53138.2021.9662795
Publication status	Published - 2021
Event	Conference on Computing in Cardiology (CinC) - Hotel Passage, Brno, Czech Republic Duration: 12 Sept 2021 → 15 Sept 2021

Publication series

Series	Computing in Cardiology Conference
ISSN	2325-8861

Conference

Conference	Conference on Computing in Cardiology (CinC)
Country/Territory	Czech Republic
City	Brno
Period	12/09/21 → 15/09/21

Keywords

DYSSYNCHRONY
BUNDLE

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10.23919/CinC53138.2021.9662795

Cite this

@inproceedings{c810173614ba43908bf1353fb2813dd9,

title = "Ultra-High-Frequency Electrocardiography",

abstract = "Background: We introduce a new technology that uses the ultra-high-frequency components (150-1000 Hz) of the electrocardiogram (UHF-ECG).Method: The UHF-ECG components represent weak signals generated by the depolarization of myocardial cells. The amplitude of UHF oscillations decreases with distance from the source. This property and the different timing of depolarization in the ventricles' volume enable mapping of the ventricular activation from the chest ECG leads. Because of a low signal-to-noise ratio of UHF oscillations, averaging must be performed. Single recording thus lasts 30 seconds and more.Results: UHF-ECG defines the time-spatial distribution of myocardial electrical activity. Corresponding numerical parameters are electrical dyssynchrony (e-DYS) and the duration of local depolarization (Vd). UHF ventricular depolarization maps present details of electrical activation.Conclusion: The UHF-ECG uses a new source of information originating in ventricular volumes that is different from the standard ECG. It provides information about the volumetric electrical activation associated with mechanical contraction. Its primary clinical utilization is in cardiac resynchronization, pacing optimization, and conduction system pacing.",

keywords = "DYSSYNCHRONY, BUNDLE",

author = "P. Jurak and P. Leinveber and F. Plesinger and K. Curila and I. Viscor and V. Vondra and M. Matejkova and L. Znojilova and R. Smisek and J. Lipoldova and F.W. Prinzen and J. Halamek",

note = "Funding Information: The research was supported by the Czech Academy of Sciences (project RVO:68081731), Czech health research council AZV NU21-02-00584, by the Czech Technological Agency grant number FW03010434, and the European Regional Development Fund-Project ENOCH No.CZ.02.1.01/0.0/0.0/16_019/0000868 Publisher Copyright: {\textcopyright} 2021 Creative Commons.; Conference on Computing in Cardiology (CinC) ; Conference date: 12-09-2021 Through 15-09-2021",

year = "2021",

doi = "10.23919/CinC53138.2021.9662795",

language = "English",

series = "Computing in Cardiology Conference",

publisher = "IEEE",

booktitle = "2021 COMPUTING IN CARDIOLOGY (CINC)",

address = "United States",

}

Jurak, P, Leinveber, P, Plesinger, F, Curila, K, Viscor, I, Vondra, V, Matejkova, M, Znojilova, L, Smisek, R, Lipoldova, J, Prinzen, FW & Halamek, J 2021, Ultra-High-Frequency Electrocardiography. in 2021 COMPUTING IN CARDIOLOGY (CINC). IEEE, Computing in Cardiology Conference, Conference on Computing in Cardiology (CinC), Brno, Czech Republic, 12/09/21. https://doi.org/10.23919/CinC53138.2021.9662795

TY - GEN

T1 - Ultra-High-Frequency Electrocardiography

AU - Jurak, P.

AU - Leinveber, P.

AU - Plesinger, F.

AU - Curila, K.

AU - Viscor, I.

AU - Vondra, V.

AU - Matejkova, M.

AU - Znojilova, L.

AU - Smisek, R.

AU - Lipoldova, J.

AU - Prinzen, F.W.

AU - Halamek, J.

N1 - Funding Information: The research was supported by the Czech Academy of Sciences (project RVO:68081731), Czech health research council AZV NU21-02-00584, by the Czech Technological Agency grant number FW03010434, and the European Regional Development Fund-Project ENOCH No.CZ.02.1.01/0.0/0.0/16_019/0000868 Publisher Copyright: © 2021 Creative Commons.

PY - 2021

Y1 - 2021

N2 - Background: We introduce a new technology that uses the ultra-high-frequency components (150-1000 Hz) of the electrocardiogram (UHF-ECG).Method: The UHF-ECG components represent weak signals generated by the depolarization of myocardial cells. The amplitude of UHF oscillations decreases with distance from the source. This property and the different timing of depolarization in the ventricles' volume enable mapping of the ventricular activation from the chest ECG leads. Because of a low signal-to-noise ratio of UHF oscillations, averaging must be performed. Single recording thus lasts 30 seconds and more.Results: UHF-ECG defines the time-spatial distribution of myocardial electrical activity. Corresponding numerical parameters are electrical dyssynchrony (e-DYS) and the duration of local depolarization (Vd). UHF ventricular depolarization maps present details of electrical activation.Conclusion: The UHF-ECG uses a new source of information originating in ventricular volumes that is different from the standard ECG. It provides information about the volumetric electrical activation associated with mechanical contraction. Its primary clinical utilization is in cardiac resynchronization, pacing optimization, and conduction system pacing.

AB - Background: We introduce a new technology that uses the ultra-high-frequency components (150-1000 Hz) of the electrocardiogram (UHF-ECG).Method: The UHF-ECG components represent weak signals generated by the depolarization of myocardial cells. The amplitude of UHF oscillations decreases with distance from the source. This property and the different timing of depolarization in the ventricles' volume enable mapping of the ventricular activation from the chest ECG leads. Because of a low signal-to-noise ratio of UHF oscillations, averaging must be performed. Single recording thus lasts 30 seconds and more.Results: UHF-ECG defines the time-spatial distribution of myocardial electrical activity. Corresponding numerical parameters are electrical dyssynchrony (e-DYS) and the duration of local depolarization (Vd). UHF ventricular depolarization maps present details of electrical activation.Conclusion: The UHF-ECG uses a new source of information originating in ventricular volumes that is different from the standard ECG. It provides information about the volumetric electrical activation associated with mechanical contraction. Its primary clinical utilization is in cardiac resynchronization, pacing optimization, and conduction system pacing.

KW - DYSSYNCHRONY

KW - BUNDLE

U2 - 10.23919/CinC53138.2021.9662795

DO - 10.23919/CinC53138.2021.9662795

M3 - Conference article in proceeding

T3 - Computing in Cardiology Conference

BT - 2021 COMPUTING IN CARDIOLOGY (CINC)

PB - IEEE

T2 - Conference on Computing in Cardiology (CinC)

Y2 - 12 September 2021 through 15 September 2021

ER -

Ultra-High-Frequency Electrocardiography

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