Spiral waves characterization: Implications for an automated cardiodynamic tissue characterization

Celal Alagoz; Andrew R Cohen; Daniel R Frisch; Birkan Tunç; Saran Phatharodom; Allon Guez

doi:10.1016/j.cmpb.2018.04.006

Spiral waves characterization: Implications for an automated cardiodynamic tissue characterization

Comput Methods Programs Biomed. 2018 Jul:161:15-24. doi: 10.1016/j.cmpb.2018.04.006. Epub 2018 Apr 11.

Authors

Celal Alagoz¹, Andrew R Cohen², Daniel R Frisch³, Birkan Tunç⁴, Saran Phatharodom², Allon Guez⁵

Affiliations

¹ ECE Department, Drexel University, Philadelphia, PA 19104, USA. Electronic address: celal.alagoz@gmail.com.
² ECE Department, Drexel University, Philadelphia, PA 19104, USA.
³ Thomas Jefferson University Hospital, Philadelphia, PA 19107, USA.
⁴ Center for Biomedical Image Computing and Analytics, Department of Radiology, University of Pennsylvania, Philadelphia, PA 19104, USA.
⁵ ECE Department, Drexel University, Philadelphia, PA 19104, USA. Electronic address: guezal@drexel.edu.

PMID: 29852958
DOI: 10.1016/j.cmpb.2018.04.006

Abstract

Background and objective: Spiral waves are phenomena observed in cardiac tissue especially during fibrillatory activities. Spiral waves are revealed through in-vivo and in-vitro studies using high density mapping that requires special experimental setup. Also, in-silico spiral wave analysis and classification is performed using membrane potentials from entire tissue. In this study, we report a characterization approach that identifies spiral wave behaviors using intracardiac electrogram (EGM) readings obtained with commonly used multipolar diagnostic catheters that perform localized but high-resolution readings. Specifically, the algorithm is designed to distinguish between stationary, meandering, and break-up rotors.

Methods: The clustering and classification algorithms are tested on simulated data produced using a phenomenological 2D model of cardiac propagation. For EGM measurements, unipolar-bipolar EGM readings from various locations on tissue using two catheter types are modeled. The distance measure between spiral behaviors are assessed using normalized compression distance (NCD), an information theoretical distance. NCD is a universal metric in the sense it is solely based on compressibility of dataset and not requiring feature extraction. We also introduce normalized FFT distance (NFFTD) where compressibility is replaced with a FFT parameter.

Results: Overall, outstanding clustering performance was achieved across varying EGM reading configurations. We found that effectiveness in distinguishing was superior in case of NCD than NFFTD. We demonstrated that distinct spiral activity identification on a behaviorally heterogeneous tissue is also possible.

Conclusions: This report demonstrates a theoretical validation of clustering and classification approaches that provide an automated mapping from EGM signals to assessment of spiral wave behaviors and hence offers a potential mapping and analysis framework for cardiac tissue wavefront propagation patterns.

Keywords: Cardiac electro-physiology simulation; Cardiac fibrillation; Classification; Clustering; Intracardiac electrograms; Normalized compression distance; Spiral waves.

MeSH terms

Action Potentials
Algorithms
Atrial Fibrillation / diagnosis
Cluster Analysis*
Computer Simulation
Data Compression
Electromagnetic Phenomena
Electronic Data Processing
Electrophysiologic Techniques, Cardiac*
Heart Atria
Humans
Medical Informatics / methods*
Models, Cardiovascular
Signal Processing, Computer-Assisted*