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Detection of electrocardiographic ‘left ventricular strain’ using neural nets

  • Biomedical Engineering
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Abstract

The use of artificial neural networks for classification of ST-T abnormalities of the electrocardiogram (ECG) was investigated. A training set of 356 lateral leads selected from 105 ECGs was visually classified as exhibiting one particular ST-T morphology (left ventricular (LV) strain) or not. Selected measurements, together with the classification, were fed as input to a three-layer software-based network during the learning process. The performance of the network was evaluated by comparing the results obtained from the network with conventional criteria, using two test sets. Set 1 comprised 63 lateral leads from 32 ECGs with ST-T changes showing atypical forms of LV strain. Set 2 consisted of 80 lateral leads from 20 ECGs containing normal and abnormal T-waves. For set 1, the network outperformed conventional criteria, having a higher sensitivity (96 per cent against 85 per cent) and specificity (67 per cent against 50 per cent). With test set 2, both network and conventional criteria were 100 per cent sensitive and 100 per cent specific. For sets 1 and 2 combined, the network had a higher overall sensitivity (97 per cent agaisst 89 per cent) and specificity (88 per cent against 82 per cent). The results suggest that neural networks may be useful in selected areas of electrocardiography, but care is required when selecting patterns for use in the training process.

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Authors and Affiliations

  1. University Department of Medical Cardiology, Royal Infirmary, G31 2ER, Glasgow, UK

    B. Devine & P. W. Macfarlane

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  1. B. Devine
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  2. P. W. Macfarlane
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Devine, B., Macfarlane, P.W. Detection of electrocardiographic ‘left ventricular strain’ using neural nets. Med. Biol. Eng. Comput. 31, 343–348 (1993). https://doi.org/10.1007/BF02446686

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  • DOI: https://doi.org/10.1007/BF02446686

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