Title :
Deconvolution of electrograms to detect infarcted myocardium
Author :
Ellis, Willard S. ; Eisenberg, Susan J. ; Auslander, David M. ; Dae, Michael W. ; Zakhor, Avideh ; Lesh, Michael D.
Author_Institution :
Cardiovascular Res. Inst., California Univ., San Francisco, CA, USA
Abstract :
Ablation to prevent cardiac arrhythmias requires interpretation of electrograms to locate the arrhythmogenic tissue. This study examined a novel signal processing technique employing deconvolution to calculate electrograms which best fit observed electrograms. We hypothesize that the power of difference between the calculated and the observed electrogram detects changes in morphology resulting from myocardial infarction. 380 electrograms were recorded from 10 dogs. Scintigraphic studies with Thallium-201 identified recording sites as normal or infarcted tissue. The power of the difference increased 65 percent for infarcted tissue as compared to normal tissue (p<0.0001). Receiver operating curves were plotted, and deconvolution detected 80% of the infarcted sites with a 20% false positive rate. Deconvolution´s performance for detection of infarcted tissue was superior to previous metrics and shows promise for improving clinical electrogram interpretation
Keywords :
biomedical measurement; deconvolution; electrocardiography; radioisotope imaging; signal detection; Tl; ablation; arrhythmogenic tissue; cardiac arrhythmias; clinical electrogram interpretation; deconvolution; dogs; electrograms; false positive rate; infarcted myocardium detection; morphology; myocardial infarction; receiver operating curves; scintigraphic studies; signal processing technique; thallium-201; Animals; Catheters; Computer science; Deconvolution; Dogs; Electrodes; Heart; Medical treatment; Morphology; Myocardium;
Conference_Titel :
Acoustics, Speech, and Signal Processing, 1996. ICASSP-96. Conference Proceedings., 1996 IEEE International Conference on
Print_ISBN :
0-7803-3192-3
DOI :
10.1109/ICASSP.1996.544209
