Deep learning and hyperparameter optimization for assessing one’s eligibility for a subcutaneous implantable cardioverter-defibrillator
Deep learning and hyperparameter optimization for assessing one’s eligibility for a subcutaneous implantable cardioverter-defibrillator
It is standard cardiology practice for patients suffering from ventricular arrhythmias (the main cause of sudden cardiac death) belonging to high risk populations to be treated via the implantation of Subcutaneous Implantable cardioverter-defibrillators (S-ICDs). S-ICDs carry a risk of so-called T wave over sensing (TWOS), which can lead to inappropriate shocks that carry an inherent health risk. For this reason, according to current practice patients’ Electrocardiograms (ECGs) are manually screened by a cardiologist over 10 s to assess the T:R ratio—the ratio between the amplitudes of the T and R waves which is used as a marker for the likelihood of TWOS—with a plastic template. Unfortunately, the temporal variability of a patient’ T:R ratio can render such a screening procedure, which relies on an inevitably short ECG segment due to its manual nature, unreliable. In this paper, we propose and investigate a tool based on deep learning for the automatic prediction of the T:R ratios from multiple 10-second segments of ECG recordings capable of carrying out a 24-hour automated screening. Thanks to the significantly increased screening window, such a screening would provide far more reliable T:R ratio predictions than the currently utilized 10-second, template-based, manual screening is capable of. Our tool is the first, to the best of our knowledge, to fully automate such an otherwise manual and potentially inaccurate procedure. From a methodological perspective, we evaluate different deep learning model architectures for our tool, assess a range of stochastic-gradient-descent-based optimization methods for training their underlying deep-learning model, perform hyperparameter tuning, and create ensembles of the best performing models in order to identify which combination leads to the best performance. We find that the resulting model, which has been integrated into a prototypical tool for use by clinicians, is able to predict T:R ratios with very high accuracy. Thanks to this, our automated T:R ratio detection tool will enable clinicians to provide a completely automated assessment of whether a patient is eligible for S-ICD implantation which is more reliable than current practice thanks to adopting a significantly longer ECG screening window which better and more accurately captures the behavior of the patient’s T:R ratio than the current manual practice.
Deep learning, Machine learning, Optimization, Subcutaneous implantable cardioverter defibrillators
309-335
Dunn, Anthony J.
161d9c8e-6813-4909-95ea-6c11bbbca287
Coniglio, Stefano
03838248-2ce4-4dbc-a6f4-e010d6fdac67
Elrefai, Mohamed
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Roberts, Paul R.
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Wiles, Benedict M.
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Zemkoho, Alain B.
30c79e30-9879-48bd-8d0b-e2fbbc01269e
September 2023
Dunn, Anthony J.
161d9c8e-6813-4909-95ea-6c11bbbca287
Coniglio, Stefano
03838248-2ce4-4dbc-a6f4-e010d6fdac67
Elrefai, Mohamed
28916fea-4687-4d4b-99aa-961e73b710ab
Roberts, Paul R.
193431e8-f9d5-48d6-8f62-ed9052b2571d
Wiles, Benedict M.
a42ba978-24c3-4533-8eca-498102004477
Zemkoho, Alain B.
30c79e30-9879-48bd-8d0b-e2fbbc01269e
Dunn, Anthony J., Coniglio, Stefano, Elrefai, Mohamed, Roberts, Paul R., Wiles, Benedict M. and Zemkoho, Alain B.
(2023)
Deep learning and hyperparameter optimization for assessing one’s eligibility for a subcutaneous implantable cardioverter-defibrillator.
Annals of Operations Research, 328 (1), .
(doi:10.1007/s10479-023-05326-1).
Abstract
It is standard cardiology practice for patients suffering from ventricular arrhythmias (the main cause of sudden cardiac death) belonging to high risk populations to be treated via the implantation of Subcutaneous Implantable cardioverter-defibrillators (S-ICDs). S-ICDs carry a risk of so-called T wave over sensing (TWOS), which can lead to inappropriate shocks that carry an inherent health risk. For this reason, according to current practice patients’ Electrocardiograms (ECGs) are manually screened by a cardiologist over 10 s to assess the T:R ratio—the ratio between the amplitudes of the T and R waves which is used as a marker for the likelihood of TWOS—with a plastic template. Unfortunately, the temporal variability of a patient’ T:R ratio can render such a screening procedure, which relies on an inevitably short ECG segment due to its manual nature, unreliable. In this paper, we propose and investigate a tool based on deep learning for the automatic prediction of the T:R ratios from multiple 10-second segments of ECG recordings capable of carrying out a 24-hour automated screening. Thanks to the significantly increased screening window, such a screening would provide far more reliable T:R ratio predictions than the currently utilized 10-second, template-based, manual screening is capable of. Our tool is the first, to the best of our knowledge, to fully automate such an otherwise manual and potentially inaccurate procedure. From a methodological perspective, we evaluate different deep learning model architectures for our tool, assess a range of stochastic-gradient-descent-based optimization methods for training their underlying deep-learning model, perform hyperparameter tuning, and create ensembles of the best performing models in order to identify which combination leads to the best performance. We find that the resulting model, which has been integrated into a prototypical tool for use by clinicians, is able to predict T:R ratios with very high accuracy. Thanks to this, our automated T:R ratio detection tool will enable clinicians to provide a completely automated assessment of whether a patient is eligible for S-ICD implantation which is more reliable than current practice thanks to adopting a significantly longer ECG screening window which better and more accurately captures the behavior of the patient’s T:R ratio than the current manual practice.
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s10479-023-05326-1
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More information
Accepted/In Press date: 17 March 2023
e-pub ahead of print date: 24 May 2023
Published date: September 2023
Additional Information:
Funding Information:
Mohamed ElRefai has received unrestricted grant from Boston Scientific. Paul R. Roberts has received honoraria from Boston Scientific and Medtronic and Research funding from Boston Scientific. Benedict M. Wiles has received unrestricted research grant and consultancy fees from Boston Scientific. Anthony J. Dunn, Stefano Coniglio and Alain B. Zemkoho have no financial or proprietary interests in any material discussed in this article.
Funding Information:
Open access funding provided by Università degli studi di Bergamo within the CRUI-CARE Agreement. The work of Anthony J. Dunn is jointly funded by Decision Analysis Services Ltd andf EPSRC through the studentship with Reference EP/R513325/1. The work of Alain B. Zemkoho is supported by the EPSRC grant EP/V049038/1. The work of Stefano Coniglio and Alain B. Zemkoho is supported by The Alan Turing Institute under the EPSRC grants EP/N510129/1 and EP/W037211/1.
Publisher Copyright:
© 2023, The Author(s).
Keywords:
Deep learning, Machine learning, Optimization, Subcutaneous implantable cardioverter defibrillators
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Local EPrints ID: 477682
URI: http://eprints.soton.ac.uk/id/eprint/477682
ISSN: 0254-5330
PURE UUID: adf31550-0a5c-4232-8658-506e222b533c
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Date deposited: 12 Jun 2023 17:12
Last modified: 17 Mar 2024 03:40
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Author:
Anthony J. Dunn
Author:
Mohamed Elrefai
Author:
Paul R. Roberts
Author:
Benedict M. Wiles
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