单个大鼠心肌细胞中的钠电流。
Sodium current in single rat heart muscle cells.
作者信息
Brown A M, Lee K S, Powell T
出版信息
J Physiol. 1981 Sep;318:479-500. doi: 10.1113/jphysiol.1981.sp013879.
Abstract
- Rapid inward Na current (INa) was studied in isolated cells from rat ventricular myocardium by a double-suction-pipette voltage clamp technique. All experiments were carried out at 20-22 degrees C. 2. INa elicited by single depolarizing voltage steps from a holding potential, VH, of -80 mV had a threshold between -70 and -60 mV and was maximal at -30 to -20 mV. Peak currents in Krebs-Ringer solution containing 145 mM Na were of the order 0.9-1.8 mA cm-2, assuming an average cell surface area of 8000 square micrometers. 3. The reversal potential for INa was predicted by the Nernst equation for external Na in the range 1.45-145 mM with 16 mM-Na solution perfusing the interior of the cell. 4. Instantaneous I-V plots were linear for potentials of -100 to + 10 mV. Maximum Na conductance (-gNa) was calculated to be 25 mS cm-2 in 145 mM-Na solutions and gNa was constant for potentials positive to -10 mV. 5. INa activated with a time constant of 0.7 msec at -55 mV, decreasing to 100 microsec on depolarizations positive to + 10 mV. 6. Two time constants (tau h1, tau h2) were required to describe INa inactivation during a maintained depolarization, with tau h2 three to four times as long as tau h1. tau h1 was about 2 msec at -50 mV, decreasing to 0.9 msec at -10 mV. 7. The time course for recovery of INa from inactivation also exhibited two time constants (tau r1, tau r2), with the longer tau r2 having a maximum value of the order 100 msec in the potential range -60 to -80 mV. 8. INa in isolated rat cardiac cells has a low sensitivity to tetrodotoxin, requiring a concentration of 30 micrometers for complete blockade.
摘要
- 采用双吸式微电极电压钳技术,在大鼠心室肌分离细胞中研究快速内向钠电流(INa)。所有实验均在20 - 22摄氏度下进行。2. 从 - 80 mV的钳制电位(VH)施加单个去极化电压阶跃所诱发的INa,其阈值在 - 70至 - 60 mV之间,在 - 30至 - 20 mV时达到最大值。假设细胞平均表面积为8000平方微米,在含有145 mM钠的 Krebs - Ringer溶液中,峰值电流约为0.9 - 1.8 mA/cm²。3. 对于细胞内灌注16 mM - Na溶液,外部钠浓度在1.45 - 145 mM范围内时,INa的反转电位由能斯特方程预测。4. 对于 - 100至 + 10 mV的电位,瞬时I-V曲线呈线性。在145 mM - Na溶液中,最大钠电导(-gNa)计算为25 mS/cm²,对于高于 - 10 mV的电位,gNa保持恒定。5. 在 - 55 mV时,INa以0.7毫秒的时间常数激活,在高于 + 10 mV的去极化时降至100微秒。6. 在持续去极化过程中,需要两个时间常数(tau h1,tau h2)来描述INa失活,其中tau h2是tau h1的三到四倍。在 - 50 mV时,tau h1约为2毫秒,在 - 10 mV时降至0.9毫秒。7. INa从失活状态恢复的时间进程也表现出两个时间常数(tau r1,tau r2),在 - 60至 - 80 mV电位范围内,较长的tau r2最大值约为100毫秒。8. 分离的大鼠心肌细胞中的INa对河豚毒素敏感性较低,完全阻断需要30微摩尔浓度。
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