质子和钙离子对心肌中激活剂阈值的影响。
Displacement of activator thresholds in cardiac muscle by protons and calcium ions.
作者信息
Brown R H, Noble D
出版信息
J Physiol. 1978 Sep;282:333-43. doi: 10.1113/jphysiol.1978.sp012466.
Abstract
- The Na current threshold in sheep cardiac Purkinje fibres and in frog atrium is shifted in a positive direction by protons and Ca2+ ions. The titration curves for Purkinje fibres are consistent with a surface potential of -18 mV at pH 7.4 and 1.8 mM-Ca. 2. In Purkinje fibres, the pacemaker K current activation curve, s infinity, is shifted in a positive direction by Ca2+ ions. The results are consistent with a surface potential of -16 mV in normal physiological solutions. 3. The results on s inifinity during pH changes are unexpected. As also shown by Van Bogaert, Vereecke & Carmeliet (1975) the voltage shifts are usually in the opposite direction to that expected from titration of external surface negative charges. 4. Acid solutions reduce the magnitude of iK2 when fully activated. Alkalinity has little effect on iK2. 5. Acidification and alkalinization are both capable of arresting spontaneous activity in Purkinje fibres. The effects of acidity are usually irreversible. The effects of alkalinity are reversible.
摘要
- 质子和Ca2+离子使绵羊心脏浦肯野纤维和青蛙心房中的钠电流阈值向正向移动。浦肯野纤维的滴定曲线与pH 7.4和1.8 mM - Ca时的表面电位-18 mV一致。2. 在浦肯野纤维中,起搏钾电流激活曲线s无穷大因Ca2+离子而向正向移动。结果与正常生理溶液中的表面电位-16 mV一致。3. pH变化期间s无穷大的结果出乎意料。正如Van Bogaert、Vereecke和Carmeliet(1975)也表明的那样,电压变化通常与外表面负电荷滴定预期的方向相反。4. 酸性溶液在完全激活时会降低iK2的幅度。碱性对iK2影响很小。5. 酸化和碱化都能够使浦肯野纤维的自发活动停止。酸性的影响通常是不可逆的。碱性的影响是可逆的。
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