• DocumentCode
    2723533
  • Title

    Importance of the tissue conductivity values in modelling the thorax as a volume conductor

  • Author

    Hyttinen, Jari ; Kauppinen, Pasi ; Kööbi, Tiit ; Malmivuo, Jaakko

  • Author_Institution
    Ragnar Granit Inst., Tampere Univ. of Technol., Finland
  • Volume
    5
  • fYear
    1997
  • fDate
    1997
  • Firstpage
    2082
  • Abstract
    Various thoracic inhomogeneities affect the measured surface ECG signal. Similarly when the conductivities of these inhomogeneities change the ECG may change as well. Conductivity of tissue may change due to variation in body water and electrolyte balance e.g. due to many diseases. Furthermore, there exits uncertainty regarding the correct values of tissue conductivities and their inter- and intrapatient alterations. Thus the effects of these changes on the ECG signal parameters and on the forward and inverse ECG problem may be of importance. An accurate thorax model based on finite difference method featuring the anatomy of the Visible Human Man was developed. The effects of conductivity changes were determined by increasing the conductivity by 10%-a change that can be of physiological origin. X, Y and Z components of a current dipole source located at the center of the heart were energized and corresponding ECG signals were determined. Results indicated that physiological changes of tissue conductivity produced marked changes in ECG signal, which should be considered in modelling and in ECG analysis. The results manifested the importance of the correct conductivity values. When constructing accurate models of human thorax as a volume conductor the correct tissue conductivities may be more important than the accuracy of anatomical features
  • Keywords
    bioelectric phenomena; biological tissues; electrocardiography; finite difference methods; inverse problems; physiological models; Visible Human Man anatomy; body water variation; computer model; current dipole source; electrolyte balance; finite difference method; forward ECG problem; inverse ECG problem; physiological changes; segmented voxels; surface ECG signal; thoracic inhomogeneities; thorax modelling; tissue conductivity; volume conductor; Anatomy; Conductivity; Conductors; Diseases; Electrocardiography; Finite difference methods; Heart; Humans; Signal analysis; Thorax;
  • fLanguage
    English
  • Publisher
    ieee
  • Conference_Titel
    Engineering in Medicine and Biology Society, 1997. Proceedings of the 19th Annual International Conference of the IEEE
  • Conference_Location
    Chicago, IL
  • ISSN
    1094-687X
  • Print_ISBN
    0-7803-4262-3
  • Type

    conf

  • DOI
    10.1109/IEMBS.1997.758760
  • Filename
    758760