Use of Artificial Intelligence and Deep Neural Networks in Evaluation of Patients With Electrocardiographically Concealed Long QT Syndrome From the Surface 12-Lead Electrocardiogram

Bos, J. Martijn; Attia, Zachi I.; Albert, David E.; Noseworthy, Peter A.; Friedman, Paul A.; Ackerman, Michael J.

doi:10.1001/jamacardio.2020.7422

Cited by 84 publications

(62 citation statements)

References 22 publications

(42 reference statements)

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“…5 In the past years, additional tools to more reliably assess LQTS on the ECG have been developed, [7][8][9] including the use of artificial intelligence in establishing the diagnosis. 10…”

Section: Diagnosismentioning

confidence: 99%

“…Based on ECGs of a large number of genotyped LQTS patients and their family members not carrying the familial variant, we designed an online calculator with information on the likelihood that LQTS is present based on the calculated QTc (https://www.qtcalculator.org). 5 In the past years, additional tools to more reliably assess LQTS on the ECG have been developed,7–9 including the use of artificial intelligence in establishing the diagnosis 10…”

Section: Introductionmentioning

confidence: 99%

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Diagnosis, management and therapeutic strategies for congenital long QT syndrome

Wilde

Amin

Postema

2021

Heart

110

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Congenital long QT syndrome (LQTS) is characterised by heart rate corrected QT interval prolongation and life-threatening arrhythmias, leading to syncope and sudden death. Variations in genes encoding for cardiac ion channels, accessory ion channel subunits or proteins modulating the function of the ion channel have been identified as disease-causing mutations in up to 75% of all LQTS cases. Based on the underlying genetic defect, LQTS has been subdivided into different subtypes. Growing insights into the genetic background and pathophysiology of LQTS has led to the identification of genotype–phenotype relationships for the most common genetic subtypes, the recognition of genetic and non-genetic modifiers of phenotype, optimisation of risk stratification algorithms and the discovery of gene-specific therapies in LQTS. Nevertheless, despite these great advancements in the LQTS field, large gaps in knowledge still exist. For example, up to 25% of LQTS cases still remain genotype elusive, which hampers proper identification of family members at risk, and it is still largely unknown what determines the large variability in disease severity, where even within one family an identical mutation causes malignant arrhythmias in some carriers, while in other carriers, the disease is clinically silent. In this review, we summarise the current evidence available on the diagnosis, clinical management and therapeutic strategies in LQTS. We also discuss new scientific developments and areas of research, which are expected to increase our understanding of the complex genetic architecture in genotype-negative patients, lead to improved risk stratification in asymptomatic mutation carriers and more targeted (gene-specific and even mutation-specific) therapies.

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“…5 In the past years, additional tools to more reliably assess LQTS on the ECG have been developed, [7][8][9] including the use of artificial intelligence in establishing the diagnosis. 10…”

Section: Diagnosismentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Diagnosis, management and therapeutic strategies for congenital long QT syndrome

Wilde

Amin

Postema

2021

Heart

110

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“…This leads to the concept of certain packages based on AI being used in a very specific group of patients. A good example of this is the ability of an AI-based system to detect concealed long QT syndrome, where conventionally this is diagnosed when the QT interval exceeds a fixed threshold such as 500 ms Now, an AI-based system can report long QT syndrome when the QT interval is less than 450 ms [68], with confirmation being achieved via appropriate genetic testing. However, this approach would appear to be suited to use in a clinic where individuals suspected of having long QT or being screened for familial long QT are involved, but if applied to the general population, might result in a very high percentage of false positive reports of concealed long QT.…”

Section: Machine Learningmentioning

confidence: 99%

Automated ECG Interpretation—A Brief History from High Expectations to Deepest Networks

Macfarlane

Kennedy

2021

Hearts

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This article traces the development of automated electrocardiography from its beginnings in Washington, DC around 1960 through to its current widespread application worldwide. Changes in the methodology of recording ECGs in analogue form using sizeable equipment through to digital recording, even in wearables, are included. Methods of analysis are considered from single lead to three leads to twelve leads. Some of the influential figures are mentioned while work undertaken locally is used to outline the progress of the technique mirrored in other centres. Applications of artificial intelligence are also considered so that the reader can find out how the field has been constantly evolving over the past 50 years.

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“…17 Techniques such as deep-learning, including convolutional neural networks (CNN), are bringing a radical change in the field of pattern recognition, improving earlier models in learning tasks such as image classification, 5 ECG analysis and natural language processing. [18][19][20] Herein, we tested if such models were able to learn the ECG footprint of sotalol, an IKr-blocker drug inducing TdP, to develop a new tool using ECG to recognize beyond QTc, exposure to IKr-blocker drugs; improve prediction of drug-induced TdP events and classification of cLQTS types particularly cLQT2.…”

Section: Introductionmentioning

confidence: 99%

Deep learning analysis of electrocardiogram for risk prediction of drug-induced arrhythmias and diagnosis of long QT syndrome

Prifti

Fall

Davogustto

et al. 2021

European Heart Journal

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Aims Congenital long-QT syndromes (cLQTS) or drug-induced long-QT syndromes (diLQTS) can cause torsade de pointes (TdP), a life-threatening ventricular arrhythmia. The current strategy for the identification of drugs at the high risk of TdP relies on measuring the QT interval corrected for heart rate (QTc) on the electrocardiogram (ECG). However, QTc has a low positive predictive value. Methods and results We used convolutional neural network (CNN) models to quantify ECG alterations induced by sotalol, an IKr blocker associated with TdP, aiming to provide new tools (CNN models) to enhance the prediction of drug-induced TdP (diTdP) and diagnosis of cLQTS. Tested CNN models used single or multiple 10-s recordings/patient using 8 leads or single leads in various cohorts: 1029 healthy subjects before and after sotalol intake (n = 14 135 ECGs); 487 cLQTS patients (n = 1083 ECGs: 560 type 1, 456 type 2, 67 type 3); and 48 patients with diTdP (n = 1105 ECGs, with 147 obtained within 48 h of a diTdP episode). CNN models outperformed models using QTc to identify exposure to sotalol [area under the receiver operating characteristic curve (ROC-AUC) = 0.98 vs. 0.72, P ≤ 0.001]. CNN models had higher ROC-AUC using multiple vs. single 10-s ECG (P ≤ 0.001). Performances were comparable for 8-lead vs. single-lead models. CNN models predicting sotalol exposure also accurately detected the presence and type of cLQTS vs. healthy controls, particularly for cLQT2 (AUC-ROC = 0.9) and were greatest shortly after a diTdP event and declining over time (P ≤ 0.001), after controlling for QTc and intake of culprit drugs. ECG segment analysis identified the J-Tpeak interval as the best discriminator of sotalol intake. Conclusion CNN models applied to ECGs outperform QTc measurements to identify exposure to drugs altering the QT interval, congenital LQTS, and are greatest shortly after a diTdP episode.

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Use of Artificial Intelligence and Deep Neural Networks in Evaluation of Patients With Electrocardiographically Concealed Long QT Syndrome From the Surface 12-Lead Electrocardiogram

Cited by 84 publications

References 22 publications

Diagnosis, management and therapeutic strategies for congenital long QT syndrome

Diagnosis, management and therapeutic strategies for congenital long QT syndrome

Automated ECG Interpretation—A Brief History from High Expectations to Deepest Networks

Deep learning analysis of electrocardiogram for risk prediction of drug-induced arrhythmias and diagnosis of long QT syndrome

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