BACKGROUND: The anisotropy of cardiac tissue is a key determinant of 3D electric propagation and the stability of activation wave fronts in the heart. The electric properties of ventricular myocardium are widely assumed to be axially anisotropic, with activation propagating most rapidly in the myofiber direction and at uniform velocity transverse to this. We present new experimental evidence that contradicts this view. METHODS AND RESULTS: For the first time, high-density intramural electric mapping (325 electrodes at approximately 4x4x1-mm spacing) from pig left ventricular tissue was used to reconstruct 3D paced activation surfaces projected directly onto 3D tissue structure imaged throughout the same left ventricular volume. These data from 5 hearts demonstrate that ventricular tissue is electrically orthotropic with 3 distinct propagation directions that coincide with local microstructural axes defined by the laminar arrangement of ventricular myocytes. The maximum conduction velocity of 0.67+/-0.019 ms(-1) was aligned with the myofiber axis. However, transverse to this, the maximum conduction velocity was 0.30+/-0.010 ms(-1), parallel to the myocyte layers and 0.17+/-0.004 ms(-1) normal to them. These orthotropic conduction velocities give rise to preferential activation pathways across the left ventricular free wall that are not captured by structurally detailed computer models, which incorporate axially anisotropic electric properties. CONCLUSIONS: Our findings suggest that current views on uniform side-to-side electric coupling in the heart need to be revised. In particular, nonuniform laminar myocardial architecture and associated electric orthotropy should be included in future models of initiation and maintenance of ventricular arrhythmia.
BACKGROUND: The anisotropy of cardiac tissue is a key determinant of 3D electric propagation and the stability of activation wave fronts in the heart. The electric properties of ventricular myocardium are widely assumed to be axially anisotropic, with activation propagating most rapidly in the myofiber direction and at uniform velocity transverse to this. We present new experimental evidence that contradicts this view. METHODS AND RESULTS: For the first time, high-density intramural electric mapping (325 electrodes at approximately 4x4x1-mm spacing) from pig left ventricular tissue was used to reconstruct 3D paced activation surfaces projected directly onto 3D tissue structure imaged throughout the same left ventricular volume. These data from 5 hearts demonstrate that ventricular tissue is electrically orthotropic with 3 distinct propagation directions that coincide with local microstructural axes defined by the laminar arrangement of ventricular myocytes. The maximum conduction velocity of 0.67+/-0.019 ms(-1) was aligned with the myofiber axis. However, transverse to this, the maximum conduction velocity was 0.30+/-0.010 ms(-1), parallel to the myocyte layers and 0.17+/-0.004 ms(-1) normal to them. These orthotropic conduction velocities give rise to preferential activation pathways across the left ventricular free wall that are not captured by structurally detailed computer models, which incorporate axially anisotropic electric properties. CONCLUSIONS: Our findings suggest that current views on uniform side-to-side electric coupling in the heart need to be revised. In particular, nonuniform laminar myocardial architecture and associated electric orthotropy should be included in future models of initiation and maintenance of ventricular arrhythmia.
Authors: Richard D Walton; Rebecca M Smith; Bogdan G Mitrea; Edward White; Olivier Bernus; Arkady M Pertsov Journal: Biophys J Date: 2012-01-03 Impact factor: 4.033
Authors: Stephen H Gilbert; David Benoist; Alan P Benson; Ed White; Steven F Tanner; Arun V Holden; Halina Dobrzynski; Olivier Bernus; Aleksandra Radjenovic Journal: Am J Physiol Heart Circ Physiol Date: 2011-10-21 Impact factor: 4.733
Authors: Alan P Benson; Olivier Bernus; Hans Dierckx; Stephen H Gilbert; John P Greenwood; Arun V Holden; Kevin Mohee; Sven Plein; Aleksandra Radjenovic; Michael E Ries; Godfrey L Smith; Steven Sourbron; Richard D Walton Journal: Interface Focus Date: 2010-12-03 Impact factor: 3.906
Authors: Richard H Clayton; Yasser Aboelkassem; Chris D Cantwell; Cesare Corrado; Tammo Delhaas; Wouter Huberts; Chon Lok Lei; Haibo Ni; Alexander V Panfilov; Caroline Roney; Rodrigo Weber Dos Santos Journal: Philos Trans A Math Phys Eng Sci Date: 2020-05-25 Impact factor: 4.226