Abstract
Introduction: Electrical remodeling describes atrial electrophysiologic changes that occur following atrial fibrillation. The mechanism(s) responsible for this phenomenon is not well understood. The purpose of this study was to examine the effects of rapid atrial pacing on atrial action potential duration, conduction time and refractoriness in the isolated rabbit heart. The effects of Ca++ and K+ blockade in this model were also studied.
Methods and Results: Monophasic action potential recordings were made from 12 epicardial atrial sites in 50 isolated perfused rabbit heart preparations. These recordings were analyzed for activation time (AT), 90% action potential duration (APD) and conduction times (CT) measured at a 250 msec cycle length. Atrial effective refractory periods (ERP) were determined at a 200 msec cycle length. All measurements were made at baseline and repeated after 2 hours of biatrial pacing at 250 msec (control group, n = 10) or 2 hours of rapid biatrial pacing (≊80 msec) in 4 groups: rapid pacing alone (rapid pacing group); rapid pacing in the presence of 0.1mM verapamil (verapamil group) for L-type Ca++ channel blockade; rapid pacing with 1 mM 4-aminopyridine (4-AP group) for K+ channel blockade; and rapid pacing with 50 μM nickel chloride (Ni++ group) for T-type Ca++ channel blockade (n = 10 each group). All baseline and post pacing measurements were taken in the presence of Ca++ or K+ blockers for the respective groups.
After rapid atrial pacing alone the average APD shortened by 8.2±10.4 msec compared to 3.6±12.5 msec shortening for control group (p = 0.002). The shortening of APD was uniform at all recording sites. For the rapid pacing group, CT was unchanged for right to left atrial conduction but shortened significantly for left to right atrial conduction (26.8±1.9 msec at baseline to 22.3±4.1 msec post pacing, p = 0.005). Conduction times were unchanged in the control group. The dispersion of repolarization was unchanged by rapid pacing alone. The decrease in APD from baseline to post rapid pacing was similar to the control group for those hearts treated with verapamil and 4-AP (1.5±12.3 and 4.7±10.4 msec, respectively, both p ≤ 0.18 vs control group). The decrease in APD was significantly greater for the Ni++ group (11.8± 14.3 msec) than for either the control group or rapid pacing group (both p ≤ 0.023). The dispersion of repolarization was increased only in the 4-AP group post rapid pacing (41.7±6.2 msec at baseline to 53.5±9.6 msec post pacing, p = 0.01). ERPs were unchanged in any of the 5 groups except for a decrease in left atrial ERP in the Ni++ group after rapid pacing (98±14 msec at baseline to 88±8 msec post rapid pacing, p = 0.005).
Conclusions: In the isolated rabbit heart model: 1) atrial APD is shortened after rapid pacing; 2) the shortening of APD is attenuated by verapamil and 4-AP but exaggerated by Ni++ 3) atrial conduction times are shortened in a direction specific manner after rapid pacing; and 4) shortening of ERP in this model is measured only in the presence of Ni++. These findings suggest that both L-type Ca++ and 4-AP sensitive channels may participate in atrial electrical remodeling.
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References
Wijffels MCEF, Kirchhof CJHJ, Dorland R, et al. Atrial fibrillation begets atrial fibrillation: a study in awake chronically instrumented goats. Circulation 1995;92:1954-1968.
Goette A, Honeycutt C, Langberg JJ. Electrical remodeling in atrial fibrillation: time course and mechanisms. Circulation 1996;194:2968-2974.
Elvan A, Wylie K, Zipes DP. Pacing-induced chronic atrial fibrillation impairs sinus node function in dogs: electrophysiological remodeling. Circulation 1996;94:2953-2960.
Daoud EG, Bogun F, Goyal R, et al. Effect of atrial fibrillation on atrial refractoriness in humans. Circulation 1996;94: 1600-1606.
Van der Zee L, Wijffels MC, Dorland R, et al. Atrial fibrillation induced shortening of the monophasic action potential in the goat. Circulation 1996;94:I–556(Abstr).
Olgin JE, Kallman JM, Chin M, et al. Role of autonomic tone and atrial size on electrical remodeling in a canine model of atrial fibrillation. Circulation 1996;94:I–352 (Abstr).
Tieleman RG, De Langen CDJ, Grandjian JG, et al. Regional differences in pacing induced electrical remodeling of the atrium and recovery from electrical remodeling induces increased dispersion of refractoriness. Circulation 1996;94:I–352 (Abstr).
Loh P, Hocini M, de Bakker JMT, et al. Anisotropic conduction in the triangle of Koch: electrophysiologic and anatomic correlation. Circulation 1996;94:I–716 (Abstr).
Kirian M, Lamorgese M, Cosgrove DM, et al. Outward K1 currents are reduced in chronic human atrial fibrillation. PACE 1996;19:569 (Abstr).
Kamalvand K, Tan K, Lloyd G, et al. Alterations in atrial electrophysiology in patients with chronic atrial fibrillation. Circulation 1996;94:I–554 (Abstr).
Kates RE, Yee Y-G, Hill I. Effects of albumin on the electrophysiologic stability of isolated perfused rabbit hearts. J Cardiovasc Pharmacol 1989;13:168–172.
Wood MA, Mangano RA, Schieken RM, et al. Modulation of atrial repolarization by site of pacing in the isolated rabbit heart. Circulation 1996;94:1465–1470.
Qi A, Yeung-Lai-Wah JA, Xioo J, et al. Regional differences in rabbit atrial repolarization: importance of transient outward current. Am J Physiol 1994;266:H643–H649.
Firek L, Giles WR. Outward currents underlying repolarization in human atrial myocytes. Cardiovasc Res 1995;1: 31–38.
Hirano Y, Fozzard HA, January CT. Characteristics of Land T-type Ca2+ currents in canine cardiac Purkinje cells. Am J Physiol 1989;256:H1478–H1492.
Barry DM, Nerbonne JM. Myocardial potassium channels: electrophysiological and molecular diversity. Ann Rev Physiol 1996;58:363–394.
Fermini B, Wang Z, Duan D, Nattel S. Differences in rate dependence of transient outward current in rabbit and human atrium. Am J Physiol 1992;263:H1747–H1754.
Giles WR, Imaizumi Y. Comparison of potassium currents in rabbit atrial and ventricular cells. J Physiol 1988;405: 123–145.
Clark RB, Giles WR, Imaizumi Y. Properties of the transient outward current in rabbit atrial cells. J Physiol 1988;405: 147–168.
Wu JY, Lipsuis SL. Effects of extracellular Mg2+ on T-and L-type Ca2+ currents in single atrial myocytes. Am J Physiol 1990;259:H1842–H1850.
Hilgemann DW. Extracellular calcium transients and action potential configuration changes related to post-stimulatory potentiation in rabbit atrium. J Gen Physiol 1986;87: 675–706.
Kirk RE. Experimantal Design, 2nd ed. Pacific Grove, CA: Brooks/Cole Publishing Co., 1982;144–145.
Leistad E, Verbrug E, Christensen G. Cytosolic calcium overload, not atrial ischemia, accounts for post-fibrillation atrial dysfunction. Circulation 1994;94:I–492 (Abstr).
Bassingthwaighte JB, Fry CH, McGuigan JAS. Relationship between internal calcium and outward current in mammal ventricular muscle; a mechanism for the control of the action potential duration? J Physiol 1976;262:15–37.
Colatsky TJ, Hogan PM. Effects of external calcium, calcium channel-blocking agents and stimulation frequency on cycle length-dependent changes in canine cardiac action potential duration. Circ Res 1980;46:543–552.
Kass RS, Tsien RW. Control of action potential duration by calcium ions in cardiac Purkinje fibers. J Gen Physiol 1976; 67:599–617.
Siegelbaum SA, Tsien RW. Calcium-activated transient outward current in calf cardiac Purkinje fibres. J Physiol 1980; 299:485–506.
Wang Z, Fermim B, Fing J, et al. Role of chloride currents in repolarizing rabbit atrial myocytes. Am J Physiol 1995; 268:H1992–H2002.
Wang Z, Fermini B, Nattel S. Sustained depolarization-induced outward current in human atrial myocytes: evidence for a novel delayed rectifier K9+ current similar to Kv1.5 cloned channel currents. Circ Res 1993;73:1061–1076.
Boyle WA, Neerbonne JM. A novel type of depolarizationactivated K+ current in isolated adult rat atrial myocytes. Am J Physiol 1991;260:H1236–122247.
Isenberg G. Is potassium conductance of cardic Purkinje fibers controlls by \(\left[ {{\text{Ca}}^{2{\text{ + }}} } \right]_{\text{i}} ?\) Nature 1975;253:273–274.
Kline RP, Morad M. Potassium efflux in heart muscle during activity: extracellular accumulation and its implications. J Physiol 1978;280:537–558.
Kunze DL. Rate-dependent changes in extracellular potassium in the rabbit atrium. Circ Res 1977;41:122–127.
Kline RP, Kupersmith J. Effects of extracellular potassium accumulation and sodium pump activation on automatic canine Purkinje fibers. J Physiol 1982;324:507–533.
Li G-R, Fermini B, Nattel S. Properties and electrophysiologic role of calcium current in human atrial myocytes. Circulation 1994;92:I–206.
Bean BP. Pharmacology of calcium channels in cardiac muscle, vascular muscle and neurons. Am J Hypertens 1991;4: 406S–411S.
Missiaen L, Wuytack F, Raeymaekers L, et al. Ca2+ extrusion across plasma membrane and Ca2+ uptake by intracellular stores. Pharmac Ther 1991;50:191–232.
Koller BS, Kaerasik PE, Solomon AJ, et al. Relation between repolarization and refractoriness during programmed electrical stimulation in the human right ventricle. Implications for ventricular tachycardia induction. Circulation 1995; 91:2378–2384.
Papageorgiou P, Monahan K, Boyle NG, et al. Site-dependent intra-atrial conduction delay: relationship to initiation of atrial fibrillation. Circulation 1996;94:384–389.
Hoffman BF, Cranefield PF, Lepeschkin E, Surawicz B, et al. Comparision of monophasic action potentials recorded by intracellular and suction electrodes. Am J Physiol 1959; 196: 1297–1301.
Shenasa M, Kus T, Fromer M, LeBlanc RA, Dubuc M, Nadeaw R. Effect of intravenous and oral calcium antagonists (diltiazem and verapamil) on sustenance of atrial fibrillation. Am J Cardiol 1988;62:403–407.
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Wood, M.A., Caponi, D., Sykes, A.M. et al. Atrial Electrical Remodeling by Rapid Pacing in the Isolated Rabbit Heart: Effects of Ca++ and K+ Channel Blockade. J Interv Card Electrophysiol 2, 15–23 (1997). https://doi.org/10.1023/A:1009752405126
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DOI: https://doi.org/10.1023/A:1009752405126