The relation of 12 lead ECG to the cardiac anatomy: The normal CineECG

Peter M van Dam; Machteld Boonstra; Emanuela T Locati; Peter Loh

doi:10.1016/j.jelectrocard.2021.07.014

The relation of 12 lead ECG to the cardiac anatomy: The normal CineECG

J Electrocardiol. 2021 Nov-Dec:69S:67-74. doi: 10.1016/j.jelectrocard.2021.07.014. Epub 2021 Jul 22.

Authors

Peter M van Dam¹, Machteld Boonstra², Emanuela T Locati³, Peter Loh²

Affiliations

¹ Department of Cardiology, University Medical Center Utrecht, the Netherlands; ECG Excellence BV, Nieuwerbrug aan den Rijn, Netherlands. Electronic address: peter.van.dam@peacs.nl.
² Department of Cardiology, University Medical Center Utrecht, the Netherlands.
³ Department of Arrhythmology and Electrophysiology, IRCCS Policlinico San Donato, Milano, Italy.

PMID: 34325899
DOI: 10.1016/j.jelectrocard.2021.07.014

Abstract

Background: The interpretation of the 12‑lead ECG is notoriously difficult and requires experts to distinguish normal from abnormal ECG waveforms. ECG waveforms depend on body build and electrode positions, both often different in males and females. To relate the ECG waveforms to cardiac anatomical structures is even more difficult. The novel CineECG algorithm enables a direct projection of the 12‑lead ECG to the cardiac anatomy by computing the mean location of cardiac activity over time. The aim of this study is to investigate the cardiac locations of the CineECG derived from standard 12‑lead ECGs of normal subjects.

Methods: In this study we used 6525 12‑lead ECG tracings labelled as normal obtained from the certified Physionet PTB XL Diagnostic ECG Database to construct the CineECG. All 12 lead ECGs were analyzed, and then divided by age groups (18-29,30-39,40-49,50-59,60-69,70-100 years) and by gender (male/female). For each ECG, we computed the CineECG within a generic 3D heart/torso model. Based on these CineECG's, the average normal cardiac location and direction for QRS, STpeak, and TpeakTend segments were determined.

Results: The CineECG direction for the QRS segment showed large variation towards the left free wall, whereas the STT segments were homogeneously directed towards the septal/apical region. The differences in the CineECG location for the QRS, STpeak, and TpeakTend between the age and gender groups were relatively small (maximally 10 mm at end T-wave), although between the gender groups minor differences were found in the 4 chamber direction angles (QRS 4°, STpeak 5°, and TpeakTend 8°) and LAO (QRS 1°, STpeak 13°, and TpeakTend 30°).

Conclusion: CineECG demonstrated to be a feasible and pragmatic solution for ECG waveform interpretation, relating the ECG directly to the cardiac anatomy. The variations in depolarization and repolarization CineECG were small within this group of normal healthy controls, both in cardiac location as well as in direction. CineECG may enable an easier discrimination between normal and abnormal QRS and T-wave morphologies, reducing the amount of expert training. Further studies are needed to prove whether novel CineECG can significantly contribute to the discrimination of normal versus abnormal ECG tracings.

Keywords: Cardiac anatomy; Cardiac modelling; CineECG; Normal electrocardiogram.

Publication types

Research Support, Non-U.S. Gov't

MeSH terms

Adolescent
Algorithms
Arrhythmias, Cardiac
Electrocardiography*
Electrodes
Female
Heart*
Humans
Male