期刊
BIOPHYSICAL JOURNAL
卷 87, 期 4, 页码 2271-2282出版社
CELL PRESS
DOI: 10.1529/biophysj.104.043091
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资金
- NHLBI NIH HHS [HL067322, HL063195, R01 HL067322, R01 HL063195] Funding Source: Medline
Models of myocardial membrane dynamics have not been able to reproduce the experimentally observed negative bias in the asymmetry of transmembrane potential changes (DeltaV(m)) induced by strong electric shocks delivered during the action potential plateau. The goal of this study is to determine what membrane model modi. cations can bridge this gap between simulation and experiment. We conducted simulations of shocks in bidomain fibers and sheets with membrane dynamics represented by the LRd' 2000 model. We found that in the fiber, the negative bias in DeltaV(m) asymmetry could not be reproduced by addition of electroporation only, but by further addition of hypothetical outward current, I-a, activated upon strong shock-induced depolarization. Furthermore, the experimentally observed rectangularly shaped positive DeltaV(m), negative-to-positive DeltaV(m) ratio ( asymmetry ratio) = similar to2, electroporation occurring at the anode only, and the increase in positive DeltaV(m) caused by L-type Ca2+-channel blockade were reproduced in the strand only if I-a was assumed to be a part of K+ flow through the L-type Ca2+-channel. In the sheet, I-a not only contributed to the negative bias in DeltaV(m) asymmetry at sites polarized by physical and virtual electrodes, but also restricted positive DeltaV(m). Inclusion of I-a and electroporation is thus the bridge between experiment and simulation.
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