• DocumentCode
    1189937
  • Title

    Identification of cardiac rhythm features by mathematical analysis of vector fields

  • Author

    Fitzgerald, Tamara N. ; Brooks, Dana H. ; Triedman, John K.

  • Author_Institution
    Dept. of Biomed. Eng., Boston Univ., MA, USA
  • Volume
    52
  • Issue
    1
  • fYear
    2005
  • Firstpage
    19
  • Lastpage
    29
  • Abstract
    Automated techniques for locating cardiac arrhythmia features are limited, and cardiologists generally rely on isochronal maps to infer patterns in the cardiac activation sequence during an ablation procedure. Velocity vector mapping has been proposed as an alternative method to study cardiac activation in both clinical and research environments. In addition to the visual cues that vector maps can provide, vector fields can be analyzed using mathematical operators such as the divergence and curl. In the current study, conduction features were extracted from velocity vector fields computed from cardiac mapping data. The divergence was used to locate ectopic foci and wavefront collisions, and the curl to identify central obstacles in reentrant circuits. Both operators were applied to simulated rhythms created from a two-dimensional cellular automaton model, to measured data from an in situ experimental canine model, and to complex three-dimensional human cardiac mapping data sets. Analysis of simulated vector fields indicated that the divergence is useful in identifying ectopic foci, with a relatively small number of vectors and with errors of up to 30° in the angle measurements. The curl was useful for identifying central obstacles in reentrant circuits, and the number of velocity vectors needed increased as the rhythm became more complex. The divergence was able to accurately identify canine in situ pacing sites, areas of breakthrough activation, and wavefront collisions. In data from human arrhythmias, the divergence reliably estimated origins of electrical activity and wavefront collisions, but the curl was less reliable at locating central obstacles in reentrant circuits, possibly due to the retrospective nature of data collection. The results indicate that the curl and divergence operators applied to velocity vector maps have the potential to add valuable information in cardiac mapping and can be used to supplement human pattern recognition.
  • Keywords
    bioelectric phenomena; cardiology; cellular automata; feature extraction; medical signal processing; physiological models; ablation; canine in situ pacing sites; cardiac activation sequence; cardiac rhythm features; complex three-dimensional human cardiac mapping; conduction features; ectopic foci; electrical activity; feature extraction; human pattern recognition; in situ experimental canine model; isochronal maps; mathematical analysis; reentrant circuits; two-dimensional cellular automaton model; vector fields; velocity vector mapping; wavefront collisions; Analytical models; Automata; Cardiology; Circuit simulation; Computational modeling; Data mining; Feature extraction; Humans; Mathematical analysis; Rhythm; Ablation; arrhythmia; cardiac mapping; reentrant tachycardia; Algorithms; Animals; Arrhythmias, Cardiac; Computer Simulation; Diagnosis, Computer-Assisted; Dogs; Heart Conduction System; Humans; Models, Cardiovascular; Reproducibility of Results; Retrospective Studies; Sensitivity and Specificity; Vectorcardiography;
  • fLanguage
    English
  • Journal_Title
    Biomedical Engineering, IEEE Transactions on
  • Publisher
    ieee
  • ISSN
    0018-9294
  • Type

    jour

  • DOI
    10.1109/TBME.2004.839636
  • Filename
    1369585