Reentrant spiral waves can become pinned to small anatomical obstacles in the heart and lead to monomorphic ventricular tachycardia that can degenerate into polymorphic tachycardia and ventricular fibrillation. Electric field-induced secondary source stimulation can excite directly at the obstacle, and may provide a means to terminate the pinned wave or inhibit the transition to more complex arrhythmia. We used confluent monolayers of neonatal rat ventricular myocytes to investigate the use of low intensity electric field stimulation to perturb the spiral wave. A hole 2–4 mm in diameter was created in the center to pin the spiral wave. Monolayers were stained with voltage-sensitive dye di-4-ANEPPS and mapped at 253 sites. Spiral waves were initiated that attached to the hole (n = 10 monolayers). Electric field pulses 1-s in duration were delivered with increasing strength (0.5–5 V/cm) until the wave terminated after detaching from the hole. At subdetachment intensities, cycle length increased with field strength, was sustained for the duration of the pulse, and returned to its original value after termination of the pulse. Mechanistically, conduction velocity near the wave tip decreased with field strength in the region of depolarization at the obstacle. In summary, electric fields cause strength-dependent slowing or detachment of pinned spiral waves. Our results suggest a means to decelerate tachycardia that may help to prevent wave degeneration.
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机译:折返性螺旋波可能会固定在心脏上的小解剖障碍上,并导致单形性室性心动过速,后者可退化为多形性心动过速和心室纤颤。电场引起的次级源刺激可以直接在障碍物处激发,并且可以提供一种手段来终止固定波或抑制向更复杂的心律失常的转变。我们使用新生大鼠心室肌细胞的汇合单层来研究使用低强度电场刺激来扰动螺旋波。在中心开了一个直径为2-4毫米的孔以固定螺旋波。单层用电压敏感染料di-4-ANEPPS染色并定位在253个位点。产生了附着在孔上的螺旋波(n = 10个单层)。持续时间为1-s的电场脉冲以增加的强度(0.5-5 V / cm)传递,直到从孔脱离后波终止。在子分离强度下,循环长度随场强而增加,在脉冲持续时间内保持不变,并在脉冲终止后恢复到其原始值。从机械上讲,在障碍物的去极化区域中,波尖附近的传导速度随着场强而降低。总之,电场会导致固定螺旋波的强度依赖性减慢或脱离。我们的研究结果提示了一种减速心动过速的方法,可以帮助预防波变性。
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