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1
Potassium efflux in heart muscle during activity: extracellular accumulation and its implications.活动期间心肌中的钾外流:细胞外积聚及其影响。
J Physiol. 1978 Jul;280:537-58. doi: 10.1113/jphysiol.1978.sp012400.
2
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4
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6
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10
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本文引用的文献

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[Duration of ventricular action potential of the frog in relation to frequency; effects of ionic variations of potassium & sodium].[青蛙心室动作电位持续时间与频率的关系;钾离子和钠离子离子变化的影响]
Arch Int Physiol Biochim. 1958 Feb;66(1):1-21. doi: 10.3109/13813455809085118.
2
Shortening of the cardiac action potential due to a brief injection of KCl following the onset of activity.活动开始后,由于短暂注射氯化钾导致心脏动作电位缩短。
J Physiol. 1956 Apr 27;132(1):157-63. doi: 10.1113/jphysiol.1956.sp005510.
3
The after-effects of impulses in the giant nerve fibres of Loligo.枪乌贼巨大神经纤维冲动的后效应
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Electrical phenomena associated with the transport of ions and ion pairs in liquid ion-exchange membranes. II. Nonzero current properties.
J Phys Chem. 1967 Nov;71(12):3871-8. doi: 10.1021/j100871a023.
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Electrical phenomena associated with the transport of ions and ion pairs in liquid ion-exchange membranes. I. Zero current properties.与液体离子交换膜中离子和离子对传输相关的电现象。I. 零电流特性。
J Phys Chem. 1967 Nov;71(12):3862-70. doi: 10.1021/j100871a022.
6
The time and voltage dependence of the slow outward current in cardiac Purkinje fibres.心脏浦肯野纤维中缓慢外向电流的时间和电压依赖性。
J Physiol. 1966 Oct;186(3):632-62. doi: 10.1113/jphysiol.1966.sp008060.
7
Effect of nerve impulses on the membrane potential of glial cells in the central nervous system of amphibia.神经冲动对两栖动物中枢神经系统中神经胶质细胞膜电位的影响。
J Neurophysiol. 1966 Jul;29(4):788-806. doi: 10.1152/jn.1966.29.4.788.
8
The dual effect of calcium on the action potential of the frog's heart.钙对蛙心动作电位的双重作用。
J Physiol. 1966 May;184(2):291-311. doi: 10.1113/jphysiol.1966.sp007916.
9
The ultrastructure of frog ventricular cardiac muscle and its relationship to mechanism of excitation-contraction coupling.青蛙心室心肌的超微结构及其与兴奋-收缩偶联机制的关系。
J Cell Biol. 1968 Jul;38(1):99-114. doi: 10.1083/jcb.38.1.99.
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[Electrophysiological study of the effects of nickel ions on the myocardium].
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活动期间心肌中的钾外流:细胞外积聚及其影响。

Potassium efflux in heart muscle during activity: extracellular accumulation and its implications.

作者信息

Kline R P, Morad M

出版信息

J Physiol. 1978 Jul;280:537-58. doi: 10.1113/jphysiol.1978.sp012400.

DOI:10.1113/jphysiol.1978.sp012400
PMID:308540
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1282675/
Abstract
  1. Extracellular K+ activity and transmembrane potential were simultaneously monitored with a K+-selective micro-electrode placed in the extracellular space and a standard KCl-filled micro-electrode in the intracellular space of the frog ventricular muscle. 2. K+ was found to accumulate during activity and had the approximate magnitude and time course to account for the measured membrane depolarization. 3. The magnitude of the K+ accumulation depended on the frequency of stimulation, diameter of the muscle and temperature of the bathing solution. 4. The time constants of accumulation and decay were dependent only on the diameter and the temperature of the strip. A Q10 of 2 was measured for the decay of accumulated K+. 5. Double barrelled K+-electrodes were used to monitor the change in K+ activity accompanying a single action potential, since the reference barrel allowed for rapid compensation of the electrical potential fluctuations encountered in the subendothelial space. 6. K+ accumulated continuously during the plateau to a level which increased external K concentration by about 1 mM. This increase in the subendothelial space corresponds to about 1-3 muA/cm2 or 10-30 pmole/cm2-sec-1 of net K+ efflux. These values are at least an order of magnitude larger than required to discharge the membrane capacitance. 7. There is no direct relation between action potential duration and rate of development or magnitude of K+ accumulation during that action potential. 8. Increase in the external K concentration, while shortening the action potential and depolarizing the membrane, does not lead to an increased rate of accumulation of K+. The presence of Ni2+, on the other hand, prolongs the action potential and decreases the rate of K+ accumulation. 9. The results suggest that there is a substantial and continuous efflux of K+ during the action potential, which sums during rapid beating, resulting in membrane depolarization and alteration of action potential duration. The change in action potential duration in response to rate may be caused by alteration of EK in the local micro-environments.
摘要
  1. 使用置于蛙心室肌细胞外间隙的钾离子选择性微电极和置于细胞内间隙的标准氯化钾填充微电极,同时监测细胞外钾离子活性和跨膜电位。2. 发现钾离子在活动期间积累,其积累的幅度和时间进程大致可解释所测得的膜去极化现象。3. 钾离子积累的幅度取决于刺激频率、肌肉直径和浴液温度。4. 积累和衰减的时间常数仅取决于肌条的直径和温度。测得积累钾离子衰减的Q10为2。5. 使用双管钾离子电极监测单个动作电位期间伴随的钾离子活性变化,因为参考管可快速补偿在内皮细胞下间隙遇到的电位波动。6. 在平台期钾离子持续积累至使细胞外钾浓度增加约1 mM的水平。在内皮细胞下间隙的这种增加相当于约1 - 3 μA/cm²或10 - 30 pmole/cm² - sec⁻¹的净钾离子外流。这些值比使膜电容放电所需的值至少大一个数量级。7. 动作电位持续时间与该动作电位期间钾离子积累的发展速率或幅度之间没有直接关系。8. 细胞外钾浓度增加,虽然缩短动作电位并使膜去极化,但不会导致钾离子积累速率增加。另一方面,镍离子的存在会延长动作电位并降低钾离子积累速率。9. 结果表明,在动作电位期间存在大量且持续的钾离子外流,在快速跳动期间这些外流总和,导致膜去极化和动作电位持续时间改变。动作电位持续时间对心率的响应变化可能是由局部微环境中钾离子平衡电位(EK)的改变引起的。