Electrogenic Sodium Extrusion Can Stop Triggered Activity in the Canine Coronary Sinus

• Published in: Circulation research Vol. 49; no. 4; pp. 1029 - 1042
• Main Authors: WIT, ANDREW L, CRANEFIELD, PAUL F, GADSBY, DAVID C
• Format: Journal Article
• Language: English
• Published: United States American Heart Association, Inc 01.10.1981
• Subjects: Animals; Coronary Vessels - physiopathology; Dogs; Electric Stimulation; heart; Norepinephrine - pharmacology; Perfusion; Potassium Deficiency; sodium; Sodium - antagonists & inhibitors; Sodium - metabolism; Strophanthidin - analogs & derivatives; Strophanthidin - pharmacology; Time Factors
• ISSN: 0009-7330; 1524-4571
• DOI: 10.1161/01.RES.49.4.1029

Soon after a burst of triggered activity in the canine coronary sinus begins, an initial fall in maximum diastolic potential and increase in rate gives way to an increase in maximum diaatolic potential, reduction in rate, and eventual quiescence. This hyperpolarization, slowing, and subsequent quiescence might result from enhanced electrogenic sodium/potassium extrusion caused by the rise in intracellular sodium concentration ([Na]) associated with the high rate of firing. Triggered bursts can be terminated prematurely by a sudden increase in the rate of sodium extrusion. Brief exposure to K- free fluid is known to cause [Na] to rise; reactivating the pump by switching back to K-containing fluid causes immediate hyperpolarization, and within a few seconds, quiescence. Brief periods of overdrive, also thought to increase [Na], are followed by hyperpolarization, slowing and, often, by premature termination of the burst. Inhibiting the sodium/potassium pump by exposure to 2 pM acetylstrophanthidin or to K-free fluid (1) prevents or delays the hyperpolarization, (2) increases the rate of triggered activity and (S) prolongs bursts of activity when bursts last less than 2.5 minutes under control conditions. In the presence of 2 μM acetylstrophanthidin, neither brief exposures to K- free fluid nor overdrive causes sudden, premature termination of triggered bursts. Bursts do eventually stop in the presence of pump inhibitors; however, that termination is associated with an increase in rate and a decline in maximum diaatolic potential and in action potential amplitude. We conclude that electrogenic Na extrusion plays an important role in the spontaneous termination of triggered activity.