Abstract
Atrial fibrillation (AF) is a type of cardiac arrhythmia affecting millions of people every year. This disease increases the likelihood of strokes, heart failure, and even death. While dedicated medical-grade electrocardiogram (ECG) devices can enable gold-standard analysis, these devices are expensive and require clinical settings. Recent advances in the capabilities of general-purpose smartphones and wearable technology equipped with photoplethysmography (PPG) sensors increase diagnostic accessibility for most populations. This work aims to develop a single model that can generalize AF classification across the modalities of ECG and PPG with a unified knowledge representation. This is enabled by approximating the transformation of signals obtained from low-cost wearable PPG sensors in terms of Pulse Rate Variability (PRV) to temporal Heart Rate Variability (HRV) features extracted from medical-grade ECG. This paper proposes a one-dimensional deep convolutional neural network that uses HRV-derived features for classifying 30-s heart rhythms as normal sinus rhythm or atrial fibrillation from both ECG and PPG-based sensors. The model is trained with three MIT-BIH ECG databases and is assessed on a dataset of unseen PPG signals acquired from wrist-worn wearable devices through transfer learning. The model achieved the aggregate binary classification performance measures of accuracy: 95.50%, sensitivity: 94.50%, and specificity: 96.00% across a five-fold cross-validation strategy on the ECG datasets. It also achieved 95.10% accuracy, 94.60% sensitivity, 95.20% specificity on an unseen PPG dataset. The results show considerable promise towards seamless adaptation of gold-standard ECG trained models for non-ambulatory AF detection with consumer wearable devices through HRV-based knowledge transfer.
Highlights
IntroductionCardiovascular diseases (CVD) is a group of conditions that affect the heart’s rhythm mechanical function, and electrical activity [2]
Cardiovascular diseases (CVD) are the leading cause of death worldwide, with theWorld Health Organization (WHO) in 2016 estimated 17.9 million deaths annually [1].CVD is a group of conditions that affect the heart’s rhythm mechanical function, and electrical activity [2]
To assess the implementation feasibility of the developed model, it was interfaced with a smartphone application and integrated within a health monitoring context
Summary
CVD is a group of conditions that affect the heart’s rhythm mechanical function, and electrical activity [2]. This is associated with an increased likelihood of strokes and heart failure. Cardiac arrhythmia is categorized under CVD and is characterized by the disordered electrical activity of the heart. An electrical impulse travels through the heart during each heartbeat, causing the heart muscles to pump blood. After a flat line driven by the impulse traveling to the bottom heart chambers, the right and left atria (upper heart chambers) create the first wave, called P wave. The right and left ventricles (bottom chambers) make the wave called the QRS complex, and the final T wave indicates the repolarization of the ventricles.
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