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Applicability of the single equivalent point dipole model to represent a spatially distributed bio-electrical source

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Abstract

Although the single equivalent point dipole model has been used to represent well-localised bio-electrical sources, in realistic situations the source is distributed. Consequently, position estimates of point dipoles determined by inverse algorithms suffer from systematic error due to the non-exact applicability of the inverse model. In realistic situations, this systematic error cannot be avoided, a limitation that is independent of the complexity of the torso model used. This study quantitatively investigates the intrinsic limitations in the assignment of a location to the equivalent dipole due to distributed electrical source. To simulate arrhythmic activity in the heart, a model of a wave of depolarisation spreading from a focal source over the surface of a spherical shell is used. The activity is represented by a sequence of concentric belt sources (obtained by slicing the shell with a sequence of parallel plane pairs), with constant dipole moment per unit length (circumferentially) directed parallel to the propagation direction. The distributed source is represented by N dipoles at equal arc lengths along the belt. The sum of the dipole potentials is calculated at predefined electrode locations. The inverse problem involves finding a single equivalent point dipole that best reproduces the electrode potentials due to the distributed source. The inverse problem is implemented by minimising the χ2 per degree of freedom. It is found that the trajectory traced by the equivalent dipole is sensitive to the location of the spherical shell relative to the fixed electrodes. It is shown that this trajectory does not coincide with the sequence of geometrical centres of the consecutive belt sources. For distributed sources within a bounded spherical medium, displaced from the sphere's centre by 40% of the sphere's radius, it is found that the error in the equivalent dipole location varies from 3 to 20% for sources with size between 5 and 50% of the sphere's radius. Finally, a method is devised to obtain the size of the distributed source during the cardiac cycle.

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References

  • Armoundas, A. A., Feldman, A. B., Mukkamala, R., andCohen, R. J. ‘A single equivalent moving dipole model. An efficient approach for localization of sites of origin of ventricular electrical activation’, Submitted for publication.

  • Cuffin, B. N. (1995): ‘A method for localizing EEG sources in realistic head models’,IEEE Trans. Biomed. Eng. 42, pp. 68–71

    Article  Google Scholar 

  • Cuffin, B. N., andCohen, D. (1979): ‘Comparison of the magnetoencephalogram and electroencephalogram’,Electroencephalogr. Clin. Neurophysiol.,47, pp. 132–146

    Google Scholar 

  • De Munck, J. C., andPeters, M. J. (1993): ‘A fast method to compute the potential in the multisphere model’,IEEE Trans. Biomed. Eng.,40, pp. 1166–1174

    Google Scholar 

  • Durrer, D., Van Dam R. T., Freud, G. E., Janse, M. J., Meijler, F. L., andArzbaecher, R. C., (1970): ‘Total excitation of the isolated human heart’Circulation,41, pp. 899–912

    Google Scholar 

  • Einthoven, W. (1912): ‘The different forms of the human electrocardiogram and their signification’,Lancet, pp. 853–861

  • Frank, E. (1952): ‘Electric potential produced by two point current sources in a homogeneous conducting sphere’,J. Appl. Phys.,23, pp. 1225–1228

    Article  MATH  MathSciNet  Google Scholar 

  • Gabor, D., andNelson, C. V. (1954): ‘Determination of the resultant dipole of the heart from measurements on the body surface’,J. Appl. Phys.,25, pp. 413–416

    Article  Google Scholar 

  • Gulrajani, R. M., Pham-Huy, H., Nadem, R. A.,et al. (1984): ‘Application of the single moving dipole inverse solutions to the study of the WPW syndrome in man’,J. Electrocardiol.,17, pp. 271–288

    Google Scholar 

  • He, B., Musha, T., Okamoto, Y., Homma, S., Nakajima, Y., andSato, T. (1987): ‘Electric dipole tracing in the brain by means of the boundary element method and its accuracy’,IEEE Trans. Biomed. Eng.,34, pp. 406–414

    Google Scholar 

  • Hellstrand, E. (1991): ‘Magnetoencephalograms: karolinska Hospital Technology and Equipment Review’,J. Clin. Neurophysiol.,8, pp. 239–240

    Google Scholar 

  • Hellstrand, E., Abraham-Fuchs, K., Jernberg, B., Kihlstrom, L., Knutson, E., Lindquist, C., Schneider, S., andWirth, A. (1993): ‘MEG localization of interic epileptic activity and concomitant stereotactic radiosurgery. A non-invasive approach for patients with focal epilepsy’,Physiol. Meas.,14, pp. 131–136

    Article  Google Scholar 

  • Holt, J. H. Jr., Barnard, A. C., andLynn, M. S. (1969): ‘A study of the human heart as a multiple dipole electrical source. II. Diagnosis and quantification of left ventricular hypertrophy’,Circulation,40, pp. 697–710

    Google Scholar 

  • Ioanntdes, A. A., Bolton, J. P. R., Hasson, R., andClarke, C. J. S. (1989): ‘Localised and distributed source solutions for the biomagnetic inverse problem II’ inWilliamson, S. J., Hoke M., Stroink, G., andKotani, M. (Eds.): ‘Advances in biomagnetism’ (Plenum, New York), pp. 591–594

    Google Scholar 

  • Ioannides, A. A., Bolton, J. P. R., andClarke, C. J. S. (1990): ‘Continuous probabilistic solutions to the biomagnetic inverse problem’,Inverse Probl.,6, pp. 523–542

    Article  Google Scholar 

  • Miller, W., andGeselowitz, D. B. (1978): ‘Simulation studies of the electrocardiogram I. The normal heart’,Circ. Res.,43, pp. 301–315

    Google Scholar 

  • Mirvis, D. M., andHollrook, M. A. (1981): ‘Body surface distributions of repolarization potentials after acute myocardial infarction. III. Dipole ranging in normal subjects and in patients with acute myocardial infarction’,J. Electrocardiol.,14, pp. 387–398

    Google Scholar 

  • Mosher, J. C., Lewis, P. S., andLeahy, R. M. (1992): ‘Multiple dipole modeling and localization from spatio-temporal MEG data’,IEEE Trans. Biomed. Eng.,39, pp. 541–557

    Article  Google Scholar 

  • Nelder, J. A., andMead, R. (1965): ‘A Simplex method for function minimization’,Comput. J.,7, pp. 308–313

    Google Scholar 

  • Oostendorp, T., andVan Oosterom, A. (1993) ‘Decoupling linear and non-linear parameters in bioelectric source estimation’. Proc. Ann. Int. Conf IEEE EMBS, pp. 803–804

  • Plonsey, R., andFleming, D. G. (1969): ‘Bioelectric phenomena’ (McGraw-Hill, New York)

    Google Scholar 

  • Rogers, C. L., andPilkington, T. C. (1968): ‘Free-moment current dipoles in inverse electrocardiography’,IEEE Trans. Biomed. Eng.,15, pp. 312–323

    Google Scholar 

  • Scherg, M., Vajsar, J., andPicton, T. W. (1989): ‘A source analysis of the late human auditory evoked potentials’,J. Cogn. Neurosci.,1, pp. 336–355

    Google Scholar 

  • Taccardi, B. (1966): ‘Body surface distribution of equipotential lines during atrial depolarization and ventricular repolarization’,Circ. Res.,19, pp. 865–878

    Google Scholar 

  • Tsunakawa, H., Nishiyama, G., Kanesaka, S., andHarumi, K. (1987): ‘Application of dipole analysis for the diagnosis of myocardial infarction in the presence of left bundle branch block’,J. Am. Coll. Cardiol.,10, pp 1015–1021

    Google Scholar 

  • Vieth, J., Sack, G., Kober, H., Grummich, P., Schneider, S., Abraham-Fuchs, K., Harer, W., Friedrich, S., andMoger, A. (1991): ‘The efficacy of the dipole-density-plot (DDP) compared to the dipole pathway technique in multichannel MEG’. Abstr 8th Int. Conf. Biomagnetism, Muenster, pp. 249–250

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Authors and Affiliations

  1. Division of Health Sciences & Technology, Harvard University-Massachusetts Institute of Technology, Cambridge, USA

    A. A. Armoundas, A. B. Feldman & R. J. Cohen

  2. Cornell College, Mount Vernon, Indiana, USA

    D. A. Sherman

Authors
  1. A. A. Armoundas
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  2. A. B. Feldman
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  3. D. A. Sherman
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  4. R. J. Cohen
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Correspondence to A. A. Armoundas.

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Armoundas, A.A., Feldman, A.B., Sherman, D.A. et al. Applicability of the single equivalent point dipole model to represent a spatially distributed bio-electrical source. Med. Biol. Eng. Comput. 39, 562–570 (2001). https://doi.org/10.1007/BF02345147

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  • DOI: https://doi.org/10.1007/BF02345147

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