• DocumentCode
    1463171
  • Title

    Deconvolution and wavelet-based methods for membrane current estimation from simulated fractionated electrograms

  • Author

    Chouvarda, Ioanna ; Maglaveras, Nicos ; De Bakker, Jaques M T ; Van Capelle, Frans J L ; Pappas, Costas

  • Author_Institution
    Lab. of Med. Inf., Aristotelian Univ. of Thessaloniki, Greece
  • Volume
    48
  • Issue
    3
  • fYear
    2001
  • fDate
    3/1/2001 12:00:00 AM
  • Firstpage
    294
  • Lastpage
    301
  • Abstract
    In infarcted myocardium, extracellular recordings exhibit multiple deflections due to irregular pathway of the electric impulse. In this work the problem of distinguishing local from distant deflections is tackled. In order to evaluate the proposed methods in a controlled setting, simulated data are used, following both Reeler-Reuter and Luo-Rudy kinetics. The input is an array of electrograms positioned on grid-points of a rectangular grid and the output is an array of estimates of the membrane current. First, deconvolution techniques are used in the form of spatial filtering for membrane current estimation from the extracellular recordings. Second, the extracellular recordings undergo wavelet based transformation, followed by a spatial filter which enhances local activity deflections and suppresses distant activity deflections. It is shown that wavelet filtering of the extracellular recordings acts as an evaluator of the efficiency of the deconvolution techniques for the membrane current estimation. Subsequently, activation times based on the results from the two methods are used for the reconstruction of the propagation pattern in a zig-zag case in two-dimensional grids. It is shown that the wavelet-based method is more robust, and can work well even in cases where the grid interval in the y direction is four times larger than the single cell size.
  • Keywords
    bioelectric phenomena; biomembrane transport; cardiology; deconvolution; medical signal processing; muscle; wavelet transforms; cardiac electrophysiology; deconvolution-based methods; electric impulse irregular pathway; extracellular recordings; infarcted myocardium; local activation; membrane current estimation; simulated fractionated electrograms; wavelet-based methods; Biomembranes; Deconvolution; Extracellular; Filtering; Fractionation; Kinetic theory; Local activities; Myocardium; Robustness; Spatial filters; Algorithms; Animals; Computer Simulation; Electric Impedance; Electrocardiography; Heart; Humans; Models, Cardiovascular; Myocardial Infarction; Signal Processing, Computer-Assisted;
  • fLanguage
    English
  • Journal_Title
    Biomedical Engineering, IEEE Transactions on
  • Publisher
    ieee
  • ISSN
    0018-9294
  • Type

    jour

  • DOI
    10.1109/10.914792
  • Filename
    914792