豚鼠心肌细胞动作电位期间不同时刻外部钠离子浓度快速变化的影响。
Effects of rapid changes of external Na+ concentration at different moments during the action potential in guinea-pig myocytes.
作者信息
Le Guennec J V, Noble D
机构信息
University Laboratory of Physiology, University of Oxford.
出版信息
J Physiol. 1994 Aug 1;478 Pt 3(Pt 3):493-504. doi: 10.1113/jphysiol.1994.sp020268.
Abstract
- A rapid solution-changing system using a solenoid was set up. The half-time for changing the external solution surrounding a ventricular cardiac cell was 7.2 +/- 1.4 ms, whereas the time needed to change 90% of this solution was 48.5 +/- 7.9 ms. This rapid switching system was used to reduce the external sodium concentration at different moments during the action potential (recorded using the whole-cell method) to 50% of its original value. This was performed in order to investigate the effect on the shape and duration of the action potential of modifying the activity of the sodium-calcium exchanger. 2. A diminution of the action potential duration was seen irrespective of the substitute used for reducing the NaCl concentration from 140 to 70 mM. The magnitude of this diminution depended on the presence or absence of EGTA (5 mM) in the pipette solution and also on the moment during the action potential at which the NaCl substitution occurred. 3. Some differences were observed depending on whether the NaCl substitute used was lithium chloride or choline chloride. When choline chloride or N-methyl-D-glucamine was used as the NaCl substitute, the amplitude of the action potential was slightly reduced (by 2-5 mV) when the solution was changed 40 ms before the action potential was triggered. This reduction was never observed when LiCl was used as the NaCl substitute. 4. The effects on the shape of the action potential of changing from a solution containing 140 mM NaCl to one containing 70 mM NaCl and 70 mM LiCl were much more rapid when these changes occurred at a later stage during the action potential. The rate of repolarization was more than doubled when the change occurred at a late stage of the action potential but was hardly changed at the beginning of the plateau. 5. These experiments confirm the role of the sodium-calcium exchange current in determining the duration of the mammalian ventricular action potential. However, it is also possible that the sodium background current plays a significant role in determining the shape of the action potential.
摘要
- 建立了一种使用螺线管的快速溶液更换系统。更换心室心肌细胞周围外部溶液的半衰期为7.2±1.4毫秒,而更换90%该溶液所需时间为48.5±7.9毫秒。此快速切换系统用于在动作电位期间(采用全细胞法记录)的不同时刻将外部钠浓度降低至其原始值的50%。这样做是为了研究改变钠钙交换体活性对动作电位形状和持续时间的影响。2. 无论使用何种替代物将氯化钠浓度从140毫摩尔降至70毫摩尔,动作电位持续时间都会缩短。这种缩短的幅度取决于移液管溶液中是否存在EGTA(5毫摩尔),还取决于动作电位期间氯化钠替代发生的时刻。3. 根据使用的氯化钠替代物是氯化锂还是氯化胆碱,观察到了一些差异。当在动作电位触发前40毫秒更换溶液时,使用氯化胆碱或N - 甲基 - D - 葡糖胺作为氯化钠替代物,动作电位幅度会略有降低(降低2 - 5毫伏)。当使用氯化锂作为氯化钠替代物时,从未观察到这种降低。4. 当这些变化在动作电位后期发生时,从含140毫摩尔氯化钠的溶液变为含70毫摩尔氯化钠和70毫摩尔氯化锂的溶液对动作电位形状的影响要快得多。当变化发生在动作电位后期时,复极化速率增加了一倍多,但在平台期开始时几乎没有变化。5. 这些实验证实了钠钙交换电流在决定哺乳动物心室动作电位持续时间方面的作用。然而,钠背景电流在决定动作电位形状方面也可能起重要作用。
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