The development and validation of an easy to use automatic QT-interval algorithm

Ben J. M. Hermans; Arja S. Vink; Frank C. Bennis; Luc H. Filippini; Veronique M. F. Meijborg; Arthur A. M. Wilde; Laurent Pison; Pieter G. Postema; Tammo Delhaas

doi:10.1371/journal.pone.0184352

The development and validation of an easy to use automatic QT-interval algorithm

Ben J. M. Hermans, Arja S. Vink, Frank C. Bennis, Luc H. Filippini, Veronique M. F. Meijborg, Arthur A. M. Wilde, Laurent Pison, Pieter G. Postema, Tammo Delhaas^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › Academic › peer-review

Abstract

Background

To evaluate QT-interval dynamics in patients and in drug safety analysis, beat-to-beat QT-interval measurements are increasingly used. However, interobserver differences, aberrant T-wave morphologies and changes in heart axis might hamper accurate QT-interval measurements.

Objective

To develop and validate a QT-interval algorithm robust to heart axis orientation and T-wave morphology that can be applied on a beat-to-beat basis.

Methods

Additionally to standard ECG leads, the root mean square (ECG(RMS)), standard deviation and vectorcardiogram were used. QRS-onset was defined from the ECGRMS. T-wave end was defined per individual lead and scalar ECG using an automated tangent method. A median of all T-wave ends was used as the general T-wave end per beat.

Supine-standing tests of 73 patients with Long-QT syndrome (LQTS) and 54 controls were used because they have wide ranges of RR and QT-intervals as well as changes in T-wave morphology and heart axis orientation. For each subject, automatically estimated QT-intervals in three random complexes chosen from the low, middle and high RR range, were compared with manually measured QT-intervals by three observers.

Results

After visual inspection of the randomly selected complexes, 21 complexes were excluded because of evident noise, too flat T-waves or premature ventricular beats. Bland-Altman analyses of automatically and manually determined QT-intervals showed a bias of <4ms and limits of agreement of +/- 25ms. Intra-class coefficient indicated excellent agreement (> 0.9) between the algorithm and all observers individually as well as between the algorithm and the mean QT-interval of the observers.

Conclusion

Our automated algorithm provides reliable beat-to-beat QT-interval assessment, robust to heart axis and T-wave morphology.

Original language	English
Article number	0184352
Number of pages	14
Journal	PLOS ONE
Volume	12
Issue number	9
DOIs	https://doi.org/10.1371/journal.pone.0184352
Publication status	Published - 1 Sept 2017

Keywords

LONG-QT
VARIABILITY
DISPERSION
TANGENT
SIGNALS
LEADS

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10.1371/journal.pone.0184352Licence: CC BY

Cite this

@article{caf512667b344e2ba662a9e8a151422e,

title = "The development and validation of an easy to use automatic QT-interval algorithm",

abstract = "BackgroundTo evaluate QT-interval dynamics in patients and in drug safety analysis, beat-to-beat QT-interval measurements are increasingly used. However, interobserver differences, aberrant T-wave morphologies and changes in heart axis might hamper accurate QT-interval measurements.ObjectiveTo develop and validate a QT-interval algorithm robust to heart axis orientation and T-wave morphology that can be applied on a beat-to-beat basis.MethodsAdditionally to standard ECG leads, the root mean square (ECG(RMS)), standard deviation and vectorcardiogram were used. QRS-onset was defined from the ECGRMS. T-wave end was defined per individual lead and scalar ECG using an automated tangent method. A median of all T-wave ends was used as the general T-wave end per beat.Supine-standing tests of 73 patients with Long-QT syndrome (LQTS) and 54 controls were used because they have wide ranges of RR and QT-intervals as well as changes in T-wave morphology and heart axis orientation. For each subject, automatically estimated QT-intervals in three random complexes chosen from the low, middle and high RR range, were compared with manually measured QT-intervals by three observers.ResultsAfter visual inspection of the randomly selected complexes, 21 complexes were excluded because of evident noise, too flat T-waves or premature ventricular beats. Bland-Altman analyses of automatically and manually determined QT-intervals showed a bias of <4ms and limits of agreement of +/- 25ms. Intra-class coefficient indicated excellent agreement (> 0.9) between the algorithm and all observers individually as well as between the algorithm and the mean QT-interval of the observers.ConclusionOur automated algorithm provides reliable beat-to-beat QT-interval assessment, robust to heart axis and T-wave morphology.",

keywords = "LONG-QT, VARIABILITY, DISPERSION, TANGENT, SIGNALS, LEADS",

author = "Hermans, {Ben J. M.} and Vink, {Arja S.} and Bennis, {Frank C.} and Filippini, {Luc H.} and Meijborg, {Veronique M. F.} and Wilde, {Arthur A. M.} and Laurent Pison and Postema, {Pieter G.} and Tammo Delhaas",

year = "2017",

month = sep,

day = "1",

doi = "10.1371/journal.pone.0184352",

language = "English",

volume = "12",

journal = "PLOS ONE",

issn = "1932-6203",

publisher = "Public Library of Science",

number = "9",

}

TY - JOUR

T1 - The development and validation of an easy to use automatic QT-interval algorithm

AU - Hermans, Ben J. M.

AU - Vink, Arja S.

AU - Bennis, Frank C.

AU - Filippini, Luc H.

AU - Meijborg, Veronique M. F.

AU - Wilde, Arthur A. M.

AU - Pison, Laurent

AU - Postema, Pieter G.

AU - Delhaas, Tammo

PY - 2017/9/1

Y1 - 2017/9/1

N2 - BackgroundTo evaluate QT-interval dynamics in patients and in drug safety analysis, beat-to-beat QT-interval measurements are increasingly used. However, interobserver differences, aberrant T-wave morphologies and changes in heart axis might hamper accurate QT-interval measurements.ObjectiveTo develop and validate a QT-interval algorithm robust to heart axis orientation and T-wave morphology that can be applied on a beat-to-beat basis.MethodsAdditionally to standard ECG leads, the root mean square (ECG(RMS)), standard deviation and vectorcardiogram were used. QRS-onset was defined from the ECGRMS. T-wave end was defined per individual lead and scalar ECG using an automated tangent method. A median of all T-wave ends was used as the general T-wave end per beat.Supine-standing tests of 73 patients with Long-QT syndrome (LQTS) and 54 controls were used because they have wide ranges of RR and QT-intervals as well as changes in T-wave morphology and heart axis orientation. For each subject, automatically estimated QT-intervals in three random complexes chosen from the low, middle and high RR range, were compared with manually measured QT-intervals by three observers.ResultsAfter visual inspection of the randomly selected complexes, 21 complexes were excluded because of evident noise, too flat T-waves or premature ventricular beats. Bland-Altman analyses of automatically and manually determined QT-intervals showed a bias of <4ms and limits of agreement of +/- 25ms. Intra-class coefficient indicated excellent agreement (> 0.9) between the algorithm and all observers individually as well as between the algorithm and the mean QT-interval of the observers.ConclusionOur automated algorithm provides reliable beat-to-beat QT-interval assessment, robust to heart axis and T-wave morphology.

AB - BackgroundTo evaluate QT-interval dynamics in patients and in drug safety analysis, beat-to-beat QT-interval measurements are increasingly used. However, interobserver differences, aberrant T-wave morphologies and changes in heart axis might hamper accurate QT-interval measurements.ObjectiveTo develop and validate a QT-interval algorithm robust to heart axis orientation and T-wave morphology that can be applied on a beat-to-beat basis.MethodsAdditionally to standard ECG leads, the root mean square (ECG(RMS)), standard deviation and vectorcardiogram were used. QRS-onset was defined from the ECGRMS. T-wave end was defined per individual lead and scalar ECG using an automated tangent method. A median of all T-wave ends was used as the general T-wave end per beat.Supine-standing tests of 73 patients with Long-QT syndrome (LQTS) and 54 controls were used because they have wide ranges of RR and QT-intervals as well as changes in T-wave morphology and heart axis orientation. For each subject, automatically estimated QT-intervals in three random complexes chosen from the low, middle and high RR range, were compared with manually measured QT-intervals by three observers.ResultsAfter visual inspection of the randomly selected complexes, 21 complexes were excluded because of evident noise, too flat T-waves or premature ventricular beats. Bland-Altman analyses of automatically and manually determined QT-intervals showed a bias of <4ms and limits of agreement of +/- 25ms. Intra-class coefficient indicated excellent agreement (> 0.9) between the algorithm and all observers individually as well as between the algorithm and the mean QT-interval of the observers.ConclusionOur automated algorithm provides reliable beat-to-beat QT-interval assessment, robust to heart axis and T-wave morphology.

KW - LONG-QT

KW - VARIABILITY

KW - DISPERSION

KW - TANGENT

KW - SIGNALS

KW - LEADS

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DO - 10.1371/journal.pone.0184352

M3 - Article

C2 - 28863167

SN - 1932-6203

VL - 12

JO - PLOS ONE

JF - PLOS ONE

IS - 9

M1 - 0184352

ER -