28 research outputs found
Identification of 27 abnormalities from multi-lead ECG signals: An ensembled Se-ResNet framework with Sign Loss function
Cardiovascular disease is a major threat to health and one of the primary
causes of death globally. The 12-lead ECG is a cheap and commonly accessible
tool to identify cardiac abnormalities. Early and accurate diagnosis will allow
early treatment and intervention to prevent severe complications of
cardiovascular disease. In the PhysioNet/Computing in Cardiology Challenge
2020, our objective is to develop an algorithm that automatically identifies 27
ECG abnormalities from 12-lead ECG recordings
A Deep Learning-Based ECG Delineator: Evaluation and Comparison on Standard Databases
Several algorithms have been proposed for the automatic detection of the ECG characteristic waves, namely P wave, T wave and QRS complex, with particular focus on the localization of the R peaks. This Thesis aims to leverage the standard Convolutional Neural Network (CNN) to propose a new Deep Learning-based ECG delineator for the individuation of the P, R and T peaks
Robust Algorithms for Unattended Monitoring of Cardiovascular Health
Cardiovascular disease is the leading cause of death in the United States. Tracking daily changes in one’s cardiovascular health can be critical in diagnosing and managing cardiovascular disease, such as heart failure and hypertension. A toilet seat is the ideal device for monitoring parameters relating to a subject’s cardiac health in his or her home, because it is used consistently and requires no change in daily habit. The present work demonstrates the ability to accurately capture clinically relevant ECG metrics, pulse transit time based blood pressures, and other parameters across subjects and physiological states using a toilet seat-based cardiovascular monitoring system, enabled through advanced signal processing algorithms and techniques. The algorithms described herein have been designed for use with noisy physiologic signals measured at non-standard locations. A key component of these algorithms is the classification of signal quality, which allows automatic rejection of noisy segments before feature delineation and interval extractions. The present delineation algorithms have been designed to work on poor quality signals while maintaining the highest possible temporal resolution. When validated on standard databases, the custom QRS delineation algorithm has best-in-class sensitivity and precision, while the photoplethysmogram delineation algorithm has best-in-class temporal resolution. Human subject testing on normative and heart failure subjects is used to evaluate the efficacy of the proposed monitoring system and algorithms. Results show that the accuracy of the measured heart rate and blood pressure are well within the limits of AAMI standards. For the first time, a single device is capable of monitoring long-term trends in these parameters while facilitating daily measurements that are taken at rest, prior to the consumption of food and stimulants, and at consistent times each day. This system has the potential to revolutionize in-home cardiovascular monitoring