Slow Conduction in Cardiac Tissue, II : Effects of Branching Tissue Geometry

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Circulation Research. 1998;83:795-805

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(Circulation Research. 1998;83:795-805.)
© 1998 American Heart Association, Inc.

Original Contributions

Slow Conduction in Cardiac Tissue, II

Effects of Branching Tissue Geometry

Jan P. Kucera, André G. Kléber, , Stephan Rohr

From the Department of Physiology, University of Bern, Switzerland.

Correspondence to Stephan Rohr, MD, Department of Physiology, University of Bern, Bühlplatz 5, CH-3012 Bern, Switzerland. E-mail rohr{at}pyl.unibe.ch

Abstract—In cardiac tissue, functional or structural current-to-loadmismatches can induce local slow conduction or conduction block,which are important determinants of reentrant arrhythmias. Thisstudy tested whether spatially repetitive mismatches resultin a steady-state slowing of conduction. Patterned growth ofneonatal rat heart cells in culture was used to design unbranchedcell strands or strands releasing branches from either a singlepoint or multiple points at periodic intervals. Electrical activationwas followed optically using voltage-sensitive dyes under controlconditions and in elevated [K⁺]_o (5.8 and 14.8 mmol/L, respectively;in the latter case, propagation was carried by the L-type Ca²⁺current). Preparations with multiple branch points exhibiteddiscontinuous and slow conduction that became slower with increasingbranch length and/or decreasing inter-branch distance. Comparedwith unbranched strands, conduction was maximally slowed by 63%under control conditions (from 44.9±3.4 to 16.7±1.0cm/s) and by 93% in elevated [K⁺]_o (from 15.7±2.3 to 1.1±0.2cm/s). Local activation delays induced at a single branch pointwere significantly larger than the delays per branch point in multiplebranching structures. Also, selective inactivation of inward currentsin the branches induced conduction blocks. These 2 observationspointed to a dual role of the branches in propagation: whereasthey acted as current sinks for the approaching activation thus slowingconduction ("pull" effect), they supplied, once excited, depolarizingcurrent supporting downstream activation ("push" effect). This"pull and push" action resulted in a slowing of conduction inwhich the safety was largely preserved by the "push" effect.Thus, branching microarchitectures might contribute to slow conductionin tissue with discontinuous geometry, such as infarct scars andthe atrioventricular node.

Key Words: discontinuous conduction • impedance mismatch • voltage-sensitive dye • atrioventricular node • myocardial infarction

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