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Open Access 01-01-2016 | Original Paper

A priori model independent inverse potential mapping: the impact of electrode positioning

Published in: Clinical Research in Cardiology | Issue 1/2016

Abstract

Introduction

In inverse potential mapping, local epicardial potentials are computed from recorded body surface potentials (BSP). When BSP are recorded with only a limited number of electrodes, in general biophysical a priori models are applied to facilitate the inverse computation. This study investigated the possibility of deriving epicardial potential information using only 62 torso electrodes in the absence of an a priori model.

Methods

Computer simulations were used to determine the optimal in vivo positioning of 62 torso electrodes. Subsequently, three different electrode configurations, i.e., surrounding the thorax, concentrated precordial (30 mm inter-electrode distance) and super-concentrated precordial (20 mm inter-electrode distance) were used to record BSP from three healthy volunteers. Magnetic resonance imaging (MRI) was performed to register the electrode positions with respect to the anatomy of the patient. Epicardial potentials were inversely computed from the recorded BSP. In order to determine the reconstruction quality, the super-concentrated electrode configuration was applied in four patients with an implanted MRI-conditional pacemaker system. The distance between the position of the ventricular lead tip on MRI and the inversely reconstructed pacing site was determined.

Results

The epicardial potential distribution reconstructed using the super-concentrated electrode configuration demonstrated the highest correlation (R = 0.98; p < 0.01) with the original epicardial source model. A mean localization error of 5.3 mm was found in the pacemaker patients.

Conclusion

This study demonstrated the feasibility of deriving detailed anterior epicardial potential information using only 62 torso electrodes without the use of an a priori model.

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Jamil-Copley S, Bokan R, Kojodjojo P, Qureshi N, Koa-Wing M, Hayat S, Kyriacou A, Sandler B, Sohaib B, Wright I, Davies DW, Whinnett Z, Peters NS, Kanagaratnam P, Lim PB (2014) Noninvasive electrocardiographic mapping to guide ablation of outflow tract ventricular arrhythmias. Heart Rhythm 11(4):587–594PubMedPubMedCentralCrossRef

Sapp JL, Dawoud F, Clements JC, Horácek BM (2012) Inverse solution mapping of epicardial potentials: quantitative comparison with epicardial contact mapping. Circ Arrhythm Electrophysiol. 5(5):1001–1009PubMedCrossRef

Gulrajani RM (1998) The forward and inverse problems of electrocardiography. IEEE Eng Med Biol Mag 17(5):84–101PubMedCrossRef

Ramanathan C, Ghanem RN, Jia P, Ryu K, Rudy Y (2004) Noninvasive electrocardiographic imaging for cardiac electrophysiology and arrhythmia. Nat Med 10(4):422–428PubMedPubMedCentralCrossRef

Rudy Y (2013) Noninvasive electrocardiographic imaging of arrhythmogenic substrates in humans. Circ Res 112(5):863–874PubMedPubMedCentralCrossRef

Lux RL, Evans AK, Burgess MJ, Wyatt RF, Abildskov JA (1981) Redundancy reduction for improved display and analysis of body surface potential maps. I. Spatial compression. Circ Res 49(1):186–196PubMedCrossRef

Hoekema R, Uijen GJ, van Oosterom A (1999) On selecting a body surface mapping procedure. J Electrocardiol 32(2):93–101PubMedCrossRef

Lux RL, Smith RF, Abildskov JA (1978) Limited lead selection for estimating body surface potentials in electrocardiography. IEEE Biomed Eng. 25:270–276CrossRef

Finlay DD, Nugent CD, Donnelly MP, Black ND (2008) Selection of optimal recording sites for limited lead body surface potential mapping in myocardial infarction and left ventricular hypertrophy. J Electrocardiol 41(3):264–271PubMedCrossRef

10.

Messinger-Rapport BJ, Rudy Y (1990) Noninvasive recovery of epicardial potentials in a realistic heart-torso geometry. Normal sinus rhythm. Circ Res 66(4):1023–1039PubMedCrossRef

11.

van Oosterom A (2003) The dominant T wave and its significance. J Cardiovasc Electrophysiol 14(10 Suppl):S180–S187PubMedCrossRef

12.

Oostendorp T, Nenonen J, Korhonen P (2002) Noninvasive determination of the activation sequence of the heart: application to patients with previous myocardial infarctions. J Electrocardiol 35(Suppl):75–80PubMedCrossRef

13.

Marchandise E, Geuzaine C, Remacle JF (2013) Cardiovascular and lung mesh generation based on centerlines. Int J Numer Method Biomed Eng 29(6):665–682PubMedCrossRef

14.

van der Graaf AW, Bhagirath P, van Driel VJ, Ramanna H, de Hooge J, de Groot NM, Götte MJ (2014) Computing volume potentials for noninvasive imaging of cardiac excitation. Ann Noninvasive Electrocardiol

15.

Möller T, Trumbore B (1997) Fast, minimum storage ray/triangle intersection. J Graph Tools 2(1):21–28CrossRef

16.

Floyd RW (1962) Algorithm 97: shortest path. Commun ACM 5(6):345

17.

Wollmann CG, Thudt K, Kaiser B, Salomonowitz E, Mayr H, Globits S (2014) Safe performance of magnetic resonance of the heart in patients with magnetic resonance conditional pacemaker systems: the safety issue of the ESTIMATE study. J Cardiovasc Magn Reson 30:1–8

18.

Taccardi B (1963) Distribution of heart potentials on the thoracic surface of normal human subjects. Circ Res 12:341–352PubMedCrossRef

19.

Okamoto Y, Musha T, Harumi K (1990) Reduction of the number of electrodes in the measurement of body surface potential distribution. Front Med Biol Eng 2(4):283–292PubMed

20.

van Dam PM, Tung R, Shivkumar K, Laks M (2013) Quantitative localization of premature ventricular contractions using myocardial activation ECGI from the standard 12-lead electrocardiogram. J Electrocardiol 46(6):574–579PubMedCrossRef

21.

Seger M, Hanser F, Dichtl W, Stuehlinger M, Hintringer F, Trieb T, Pfeifer B, Berger T (2014) Non-invasive imaging of cardiac electrophysiology in a cardiac resynchronization therapy defibrillator patient with a quadripolar left ventricular lead. Europace 16(5):743–749PubMedCrossRef

22.

Bokeriia LA, Revishvili ASh, Kalinin AV, Kalinin VV, Liadzhina OA, Fetisova EA (2008) Hardware-software system for noninvasive electrocardiographic examination of heart based on inverse problem of electrocardiography. Med Tekh 6:1–7PubMed

23.

Abbasi SA, Ertel A, Shah RV, Dandekar V, Chung J, Bhat G, Desai AA, Kwong RY, Farzaneh-Far A (2013) Impact of cardiovascular magnetic resonance on management and clinical decision-making in heart failure patients. J Cardiovasc Magn Reson 1(15):89CrossRef

24.

Petrov G, Kelle S, Fleck E, Wellnhofer E (2015) Incremental cost-effectiveness of dobutamine stress cardiac magnetic resonance imaging in patients at intermediate risk for coronary artery disease. Clin Res Cardiol 104(5):401–409PubMedPubMedCentralCrossRef

25.

Schuster A, Ishida M, Morton G, Bigalke B, Moonim MT, Nagel E (2012) Value of cardiovascular magnetic resonance imaging in myocardial hypertrophy. Clin Res Cardiol 101(3):237–238PubMedCrossRef

26.

Schumm J, Greulich S, Sechtem U, Mahrholdt H (2014) T1 mapping as new diagnostic technique in a case of acute onset of biopsy-proven viral myocarditis. Clin Res Cardiol 103(5):405–408PubMedCrossRef

27.

Nazarian S, Hansford R, Roguin A, Goldsher D, Zviman MM, Lardo AC, Caffo BS, Frick KD, Kraut MA, Kamel IR, Calkins H, Berger RD, Bluemke DA, Halperin HR (2011) A prospective evaluation of a protocol for magnetic resonance imaging of patients with implanted cardiac devices. Ann Intern Med 155:415–424PubMedPubMedCentralCrossRef

28.

Jilek C, Lennerz C, Stracke B, Badran H, Semmler V, Reents T, Ammar S, Fichtner S, Haller B, Hessling G, Deisenhofer I, Kolb C (2013) Forces on cardiac implantable electronic devices during remote magnetic navigation. Clin Res Cardiol 102(3):185–192PubMedCrossRef

29.

Boilson BA, Wokhlu A, Acker NG, Felmlee JP, Watson RE Jr, Julsrud PR, Friedman PA, Cha YM, Rea RF, Hayes DL, Shen WK (2012) Safety of magnetic resonance imaging in patients with permanent pacemakers: a collaborative clinical approach. J Interv Card Electrophysiol 33:59–67PubMedCrossRef

30.

Ferreira AM, Costa F, Tralhão A, Marques H, Cardim N, Adragão P (2014) MRI-conditional pacemakers: current perspectives. Med Devices (Auckl) 7(7):115–124CrossRef

Title: A priori model independent inverse potential mapping: the impact of electrode positioning
Publication date: 01-01-2016
Published in: Clinical Research in Cardiology / Issue 1/2016
Print ISSN: 1861-0684
Electronic ISSN: 1861-0692
DOI: https://doi.org/10.1007/s00392-015-0891-7

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