Clinical & Experimental Cardiology
Open Access
ISSN: 2155-9880
+44 1300 500008
ISSN: 2155-9880
+44 1300 500008
Yael Yaniv and Vadim Gliner
Technion-IIT, Israel
Scientific Tracks Abstracts: J Clin Exp Cardiolog
Cardiac fibrillation is one of the leading causes of morbidity and mortality in the Western world, where atrial fibrillation
(AF) is the most common sustained arrhythmia. Because cardiac fibrillation and specifically AF can lead to stroke, early
detection of these episodes has enormous clinical impact. To date there are no real-time devices that can precisely detect the R
peaks in the ECG signal before, during and after cardiac fibrillation. Our main research objectives were to design an algorithm
that accurately detects the R peaks from ECG strips during AF and other arrhythmogenic events in the presence of noise or
movement, and to use it as the basis for an artificial intelligence algorithm that accurately identifies AF events in short single
ECG lead recordings. An algorithm which subtracts motion artifacts, electrical drift and breathing oscillations was developed.
The algorithm fixes the signal polarity, filters environmental noise, and deals with electrical spikes and premature beats by
heuristic filtering. The algorithm was tested on the MITDB Physionet database. Based on the R peak annotation, the T, P, Q
and S peaks were detected and ECG beat morphology was extracted. Machine learning techniques that include a combination
of 61 features were used for classification in to four groups. On average, our algorithm precisely detects the R peaks with 0.26%
false negative and false positive detection, for a sensitivity of 99.69% and positive prediction of 99.74%. The algorithm performs
similarly on AF and non-AF patient data. Our arrhythmia classification algorithm will classify AF ECG data in 89% of the
cases (F1). Precise real-time identification of the heart rate on a beat-to-beat basis and classification of ECG strips can serve as
a clinical tool to prescreen for cardiac diseases.
Recent Publications
1. Coast D A, Stern R M, Cano G G and Briller S A (1990) An approach to cardiac arrhythmia analysis using hidden
Markov models IEEE Transactions on Biomedical Engineering 37:826ΓΆΒ?Β?36
2. Costa M D, Peng C K and Goldberger A L (2008) Multiscale analysis of heart rate dynamics: Entropy and time
irreversibility measures. Cardiovascular Engineering 8:88ΓΆΒ?Β?93.
3. Kara S and Okandan M (2007) Atrial fibrillation classification with artificial neural networks Pattern Recognition
40:2967ΓΆΒ?Β?73.
4. Ladavich S and Ghoraani B (2015) Rate-independent detection of atrial fibrillation by statistical modeling of atrial
activity. Biomedical Signal Processing and Control 18:274ΓΆΒ?Β?81.
5. Gliner V and Yaniv Y (2017) Identification of features for machine learning analysis for automatic arrhythmogenic
event classification. Computing in Cardiology DOI: 10.22489/CinC.2017.170-101.