Inter-lead correlation analysis for automated detection of cable reversals in 12/16-lead ECG

Irena Jekova; Vessela Krasteva; Remo Leber; Ramun Schmid; Raphael Twerenbold; Christian Müller; Tobias Reichlin; Roger Abächerli

doi:10.1016/j.cmpb.2016.06.003

Inter-lead correlation analysis for automated detection of cable reversals in 12/16-lead ECG

Standard

Inter-lead correlation analysis for automated detection of cable reversals in 12/16-lead ECG. / Jekova, Irena; Krasteva, Vessela; Leber, Remo; Schmid, Ramun; Twerenbold, Raphael; Müller, Christian; Reichlin, Tobias; Abächerli, Roger.

in: COMPUT METH PROG BIO, Jahrgang 134, 10.2016, S. 31-41.

Publikationen: SCORING: Beitrag in Fachzeitschrift/Zeitung › SCORING: Zeitschriftenaufsatz › Forschung › Begutachtung

Harvard

Jekova, I, Krasteva, V, Leber, R, Schmid, R, Twerenbold, R, Müller, C, Reichlin, T & Abächerli, R 2016, 'Inter-lead correlation analysis for automated detection of cable reversals in 12/16-lead ECG', COMPUT METH PROG BIO, Jg. 134, S. 31-41. https://doi.org/10.1016/j.cmpb.2016.06.003

APA

Jekova, I., Krasteva, V., Leber, R., Schmid, R., Twerenbold, R., Müller, C., Reichlin, T., & Abächerli, R. (2016). Inter-lead correlation analysis for automated detection of cable reversals in 12/16-lead ECG. COMPUT METH PROG BIO, 134, 31-41. https://doi.org/10.1016/j.cmpb.2016.06.003

Vancouver

Jekova I, Krasteva V, Leber R, Schmid R, Twerenbold R, Müller C et al. Inter-lead correlation analysis for automated detection of cable reversals in 12/16-lead ECG. COMPUT METH PROG BIO. 2016 Okt;134:31-41. https://doi.org/10.1016/j.cmpb.2016.06.003

Bibtex

@article{00e70a6b79d849bda5e01b952b5a1d37,

title = "Inter-lead correlation analysis for automated detection of cable reversals in 12/16-lead ECG",

abstract = "BACKGROUND AND OBJECTIVE: A crucial factor for proper electrocardiogram (ECG) interpretation is the correct electrode placement in standard 12-lead ECG and extended 16-lead ECG for accurate diagnosis of acute myocardial infarctions. In the context of optimal patient care, we present and evaluate a new method for automated detection of reversals in peripheral and precordial (standard, right and posterior) leads, based on simple rules with inter-lead correlation dependencies.METHODS: The algorithm for analysis of cable reversals relies on scoring of inter-lead correlations estimated over 4s snapshots with time-coherent data from multiple ECG leads. Peripheral cable reversals are detected by assessment of nine correlation coefficients, comparing V6 to limb leads: (I, II, III, -I, -II, -III, -aVR, -aVL, -aVF). Precordial lead reversals are detected by analysis of the ECG pattern cross-correlation progression within lead sets (V1-V6), (V4R, V3R, V3, V4), and (V4, V5, V6, V8, V9). Disturbed progression identifies the swapped leads.RESULTS: A test-set, including 2239 ECGs from three independent sources-public 12-lead (PTB, CSE) and proprietary 16-lead (Basel University Hospital) databases-is used for algorithm validation, reporting specificity (Sp) and sensitivity (Se) as true negative and true positive detection of simulated lead swaps. Reversals of limb leads are detected with Se = 95.5-96.9% and 100% when right leg is involved in the reversal. Among all 15 possible pairwise reversals in standard precordial leads, adjacent lead reversals are detected with Se = 93.8% (V5-V6), 95.6% (V2-V3), 95.9% (V3-V4), 97.1% (V1-V2), and 97.8% (V4-V5), increasing to 97.8-99.8% for reversals of anatomically more distant electrodes. The pairwise reversals in the four extra precordial leads are detected with Se = 74.7% (right-sided V4R-V3R), 91.4% (posterior V8-V9), 93.7% (V4R-V9), and 97.7% (V4R-V8, V3R-V9, V3R-V8). Higher true negative rate is achieved with Sp > 99% (standard 12-lead ECG), 81.9% (V4R-V3R), 91.4% (V8-V9), and 100% (V4R-V9, V4R-V8, V3R-V9, V3R-V8), which is reasonable considering the low prevalence of lead swaps in clinical environment.CONCLUSIONS: Inter-lead correlation analysis is able to provide robust detection of cable reversals in standard 12-lead ECG, effectively extended to 16-lead ECG applications that have not previously been addressed.",

keywords = "Algorithms, Automation, Electrocardiography/instrumentation",

author = "Irena Jekova and Vessela Krasteva and Remo Leber and Ramun Schmid and Raphael Twerenbold and Christian M{\"u}ller and Tobias Reichlin and Roger Ab{\"a}cherli",

year = "2016",

month = oct,

doi = "10.1016/j.cmpb.2016.06.003",

language = "English",

volume = "134",

pages = "31--41",

journal = "COMPUT METH PROG BIO",

issn = "0169-2607",

publisher = "Elsevier Ireland Ltd",

}

RIS

TY - JOUR

T1 - Inter-lead correlation analysis for automated detection of cable reversals in 12/16-lead ECG

AU - Jekova, Irena

AU - Krasteva, Vessela

AU - Leber, Remo

AU - Schmid, Ramun

AU - Twerenbold, Raphael

AU - Müller, Christian

AU - Reichlin, Tobias

AU - Abächerli, Roger

PY - 2016/10

Y1 - 2016/10

N2 - BACKGROUND AND OBJECTIVE: A crucial factor for proper electrocardiogram (ECG) interpretation is the correct electrode placement in standard 12-lead ECG and extended 16-lead ECG for accurate diagnosis of acute myocardial infarctions. In the context of optimal patient care, we present and evaluate a new method for automated detection of reversals in peripheral and precordial (standard, right and posterior) leads, based on simple rules with inter-lead correlation dependencies.METHODS: The algorithm for analysis of cable reversals relies on scoring of inter-lead correlations estimated over 4s snapshots with time-coherent data from multiple ECG leads. Peripheral cable reversals are detected by assessment of nine correlation coefficients, comparing V6 to limb leads: (I, II, III, -I, -II, -III, -aVR, -aVL, -aVF). Precordial lead reversals are detected by analysis of the ECG pattern cross-correlation progression within lead sets (V1-V6), (V4R, V3R, V3, V4), and (V4, V5, V6, V8, V9). Disturbed progression identifies the swapped leads.RESULTS: A test-set, including 2239 ECGs from three independent sources-public 12-lead (PTB, CSE) and proprietary 16-lead (Basel University Hospital) databases-is used for algorithm validation, reporting specificity (Sp) and sensitivity (Se) as true negative and true positive detection of simulated lead swaps. Reversals of limb leads are detected with Se = 95.5-96.9% and 100% when right leg is involved in the reversal. Among all 15 possible pairwise reversals in standard precordial leads, adjacent lead reversals are detected with Se = 93.8% (V5-V6), 95.6% (V2-V3), 95.9% (V3-V4), 97.1% (V1-V2), and 97.8% (V4-V5), increasing to 97.8-99.8% for reversals of anatomically more distant electrodes. The pairwise reversals in the four extra precordial leads are detected with Se = 74.7% (right-sided V4R-V3R), 91.4% (posterior V8-V9), 93.7% (V4R-V9), and 97.7% (V4R-V8, V3R-V9, V3R-V8). Higher true negative rate is achieved with Sp > 99% (standard 12-lead ECG), 81.9% (V4R-V3R), 91.4% (V8-V9), and 100% (V4R-V9, V4R-V8, V3R-V9, V3R-V8), which is reasonable considering the low prevalence of lead swaps in clinical environment.CONCLUSIONS: Inter-lead correlation analysis is able to provide robust detection of cable reversals in standard 12-lead ECG, effectively extended to 16-lead ECG applications that have not previously been addressed.

AB - BACKGROUND AND OBJECTIVE: A crucial factor for proper electrocardiogram (ECG) interpretation is the correct electrode placement in standard 12-lead ECG and extended 16-lead ECG for accurate diagnosis of acute myocardial infarctions. In the context of optimal patient care, we present and evaluate a new method for automated detection of reversals in peripheral and precordial (standard, right and posterior) leads, based on simple rules with inter-lead correlation dependencies.METHODS: The algorithm for analysis of cable reversals relies on scoring of inter-lead correlations estimated over 4s snapshots with time-coherent data from multiple ECG leads. Peripheral cable reversals are detected by assessment of nine correlation coefficients, comparing V6 to limb leads: (I, II, III, -I, -II, -III, -aVR, -aVL, -aVF). Precordial lead reversals are detected by analysis of the ECG pattern cross-correlation progression within lead sets (V1-V6), (V4R, V3R, V3, V4), and (V4, V5, V6, V8, V9). Disturbed progression identifies the swapped leads.RESULTS: A test-set, including 2239 ECGs from three independent sources-public 12-lead (PTB, CSE) and proprietary 16-lead (Basel University Hospital) databases-is used for algorithm validation, reporting specificity (Sp) and sensitivity (Se) as true negative and true positive detection of simulated lead swaps. Reversals of limb leads are detected with Se = 95.5-96.9% and 100% when right leg is involved in the reversal. Among all 15 possible pairwise reversals in standard precordial leads, adjacent lead reversals are detected with Se = 93.8% (V5-V6), 95.6% (V2-V3), 95.9% (V3-V4), 97.1% (V1-V2), and 97.8% (V4-V5), increasing to 97.8-99.8% for reversals of anatomically more distant electrodes. The pairwise reversals in the four extra precordial leads are detected with Se = 74.7% (right-sided V4R-V3R), 91.4% (posterior V8-V9), 93.7% (V4R-V9), and 97.7% (V4R-V8, V3R-V9, V3R-V8). Higher true negative rate is achieved with Sp > 99% (standard 12-lead ECG), 81.9% (V4R-V3R), 91.4% (V8-V9), and 100% (V4R-V9, V4R-V8, V3R-V9, V3R-V8), which is reasonable considering the low prevalence of lead swaps in clinical environment.CONCLUSIONS: Inter-lead correlation analysis is able to provide robust detection of cable reversals in standard 12-lead ECG, effectively extended to 16-lead ECG applications that have not previously been addressed.

KW - Algorithms

KW - Automation

KW - Electrocardiography/instrumentation

U2 - 10.1016/j.cmpb.2016.06.003

DO - 10.1016/j.cmpb.2016.06.003

M3 - SCORING: Journal article

C2 - 27480730

VL - 134

SP - 31

EP - 41

JO - COMPUT METH PROG BIO

JF - COMPUT METH PROG BIO

SN - 0169-2607

ER -