Penelope A. Boyden

Pathophysiology and Prevention of Atrial Fibrillation

Atrial fibrillation (AF) is a ubiquitous yet diverse cardiac arrhythmia whose incidence increases with age; with most forms of cardiac and some pulmonary diseases; and with a number of metabolic, toxic, endocrine, or genetic abnormalities.1 2 Classification of clinical AF subtypes can be achieved on the basis of the ease by which episodes of the arrhythmia terminate as follows3 : “Paroxysmal” AF refers to episodes that generally stop spontaneously after no more than a few days. “Persistent” AF occurs less frequently than paroxysmal AF and, rather than self-terminating, requires cardioversion to restore sinus rhythm. “Permanent” AF cannot be converted to sinus rhythm. These terms apply strictly to chronic AF, because a single episode of the arrhythmia cannot be fully categorized. Although there are some mixed patterns, they generally derive from physician impatience for early cardioversion or from pragmatic clinical considerations (eg, to avoid thrombus formation or hemodynamic decompensation). Patients initially presenting with paroxysmal AF often progress to longer, non–self-terminating bouts. An exception may be paroxysmal AF during intense vagotonia. Moreover, AF initially responsive to pharmacological or electrical cardioversion tends to become resistant and cannot then be converted to sinus rhythm. To some extent, the failure of the physician to suggest or the patient to accept further cardioversion attempts may lead to diagnosis of “permanent” AF. Thus, the “point of no return” may be determined by true pathophysiological abnormalities or may merely be an artifact of clinical pragmatism. Effective prevention is essential in managing this arrhythmia whose occurrence is widespread, progression is relentless, and morbidity and mortality are significant. To focus on means for prevention necessitates considering both clinical risk factors and pathophysiology. AF derives from a complex continuum predisposing factors, summarized in Table 1⇓. In the West, about 5% of the population >65 years of age …

Alterations of Na+ Currents in Myocytes From Epicardial Border Zone of the Infarcted Heart : A Possible Ionic Mechanism for Reduced Excitability and Postrepolarization Refractoriness

Previously, we have shown abnormalities in Vmax and in the recovery of Vmax in myocytes dispersed from the epicardial border zone (EBZ) of the 5-day infarcted canine heart (myocytes from the EBZ [IZs]). Thus, we sought to determine the characteristics of the whole-cell Na+ current (INa) in IsZs and compare them with the INa of cells from noninfarcted hearts (myocytes from noninfarcted epicardium [NZs]). INa was recorded using patch-clamp techniques under conditions that eliminated contaminating currents and controlled INa for measurement (19 degrees C, 5 mmol/L [Na+]zero). Peak INa density (at -25 mV) was significantly reduced in IZs (4.9 +/- 0.44 pA/pF, n = 36) versus NZs (12.8 +/- 0.55 pA/pF, n = 54; P < .001), yet the half-maximal activation voltage (V0.5), time course of decay, and time to peak INa were no different. However, in IZs, V0.5 of the availability curve (I/Imax curve) was shifted significantly in the hyperpolarizing direction (-80.2 +/- 0.48 mV in NZs [n = 45] versus -83.9 +/- 0.59 mV in IZs [n = 27], P < .01). Inactivation of INa directly from a depolarized prepotential (-60 mV) was significantly accelerated in IZs versus NZs (fast and slow time constants [T1 and T2, respectively] were as follows: NZs [n = 28], T1 = 71.5 +/- 5.6 ms and T2 = 243.7 +/- 17.1 ms; IZs [n = 21], T1 = 36.3 +/- 2.4 ms and T2 = 153 +/- 11.3 ms; P < .001). Recovery of INa from inactivation was dependent on the holding potential (VH) in both cell types but was significantly slower in IZs. At (VH) = -90 mV, INa recovery had a lag in 18 (82%) of 22 IZs (with a 17.6 +/- 1.5-ms lag) versus 2 (9%) of 22 NZs (with 5.9- and 8.7-ms lags); at VH = -100 mV, T1 = 60.9 +/- 2.6 ms and T2 = 352.8 +/- 28.1 ms in NZs (n = 41) versus T1 = 76.3 +/- 4.8 ms and T2 = 464.4 +/- 47.2 ms in IZs (n = 26) (P < .002 and P < .03, respectively); at VH = -110 mV, T1 = 33.4 +/- 1.8 ms and T2 = 293.5 +/- 33.6 ms in NZs (n = 21) versus T1 = 44.3 +/- 2.9 ms and T2 = 388.4 +/- 38 ms in IZs (n = 18) (P < .002 and P < .07, respectively). In sum, INa is reduced, and its kinetics are altered in IZs. These changes may underlie the altered excitability and postrepolarization refractoriness of the ventricular fibers of the EBZ, thus contributing to reentrant arrhythmias in the infarcted heart.

Electrical remodeling in ischemia and infarction

This is a review of the electrophysiologic changes occurring at different times following myocardial infarction, both in the infarcted region (substrate) and in areas remote from the infarct. Regulators of channel function which might contribute to re-modeling, including autocrine/paracrine factors involved in ion channel gene regulation, are discussed.

Abnormal electrical properties of myocytes from chronically infarcted canine heart. Alterations in Vmax and the transient outward current.

BackgroundReentrant ventricular arrhythmias can occur in the surviving muscle fibers of the epicardial border zone of the canine heart 5 days after coronary artery occlusion. To understand the cellular basis of these arrhythmias, we developed a method of dispersing myocytes (IZs) from the epicardial border zone. Methods and ResultsWe compared the electrophysiological properties of IZs with those of cells dispersed from the epicardium of control noninfarcted (NZs) and of sham-operated animals (NZsham). Transmembrane action potentials of IZs are reduced in total action potential amplitude and maximum upstroke velocity compared with NZs. However, resting potential of IZs is no different from that of NZs. Action potential duration at −10 mV is significantly reduced in IZs compared with control, and IZ potentials do not show the typical “spike and dome” morphology that is evident in all NZs. Using Vmax as an indirect measure of the peak inward current available for the upstroke of the action potential, we found that the availability curve for IZs is significantly different from the NZ curve. Furthermore, the time course of recovery of Vmax after a depolarizing voltage clamp step was significantly altered in IZs. Using whole-cell voltage clamp techniques, we determined that the voltage-dependent, Ca2+-independent, 4-aminopyridine-sensitive transient outward current (it01) occurred in all NZs (n = 16) but existed in only 37% of IZs (n = 16). There was a significant reduction in the density of ito1 elicited by depolarizing steps in those IZs showing it., compared with it01 density in NZs. ConclusionsWe have developed a single-cell model of cells that survive in the infarcted heart. Our studies indicate that there are changes in Vmax in IZs. In addition, there is no prominent phase 1 of repolarization in IZ action potentials. This is consistent with the dramatic loss in the function of the ionic channel responsible for the voltage-dependent transient outward current, it01.

Remodeling of Gap Junctional Channel Function in Epicardial Border Zone of Healing Canine Infarcts

Abstract— The epicardial border zone (EBZ) of canine infarcts has increased anisotropy because of transverse conduction slowing. It remains unknown whether changes in gap junctional conductance (Gj) accompany the increased anisotropy. Ventricular cell pairs were isolated from EBZ and normal hearts (NZ). Dual patch clamp was used to quantify Gj. At a transjunctional voltage (Vj) of +10 mV, side-to-side Gj of EBZ pairs (9.2±3.4 nS, n=16) was reduced compared with NZ side-to-side Gj (109.4±23.6 nS, n=14, P <0.001). Gj of end-to-end coupled cells was not reduced in EBZ. Steady-state Gj of both NZ and EBZ showed voltage dependence, described by a two-way Boltzmann function. Half-maximal activation voltage in EBZ was shifted to higher Vj in positive and negative directions. Immunoconfocal planimetry and quantification showed no change in connexin43 per unit cell volume or surface area in EBZ. Decreased side-to-side coupling occurs in EBZ myocytes, independent of reduced connexin43 expression, and is hypothesized to contribute to increased anisotropy and reentrant arrhythmias.

Voltage-gated Nav channel targeting in the heart requires an ankyrin-G–dependent cellular pathway

Voltage-gated Nav channels are required for normal electrical activity in neurons, skeletal muscle, and cardiomyocytes. In the heart, Nav1.5 is the predominant Nav channel, and Nav1.5-dependent activity regulates rapid upstroke of the cardiac action potential. Nav1.5 activity requires precise localization at specialized cardiomyocyte membrane domains. However, the molecular mechanisms underlying Nav channel trafficking in the heart are unknown. In this paper, we demonstrate that ankyrin-G is required for Nav1.5 targeting in the heart. Cardiomyocytes with reduced ankyrin-G display reduced Nav1.5 expression, abnormal Nav1.5 membrane targeting, and reduced Na+ channel current density. We define the structural requirements on ankyrin-G for Nav1.5 interactions and demonstrate that loss of Nav1.5 targeting is caused by the loss of direct Nav1.5–ankyrin-G interaction. These data are the first report of a cellular pathway required for Nav channel trafficking in the heart and suggest that ankyrin-G is critical for cardiac depolarization and Nav channel organization in multiple excitable tissues.

Circus movement in the canine atrium around the tricuspid ring during experimental atrial flutter and during reentry in vitro.

A Y-shaped lesion in the right atrium allows induction of atrial flutter in dogs. We recorded the activation sequence during this tachycardia from 96 endocardial bipolar electrodes using intracavitary electrode arrays during 12 separate episodes in three isolated perfused hearts. In each case a reentrant impulse circulated around the tricuspid valve orifice in either a clockwise or counter-clockwise direction. Cutting the pathway terminated the rhythm and prevented its reinduction. There was no discrete segment of markedly slow conduction in the reentrant circuit. The tachycardia cycle length was decreased by methacholine and increased by lidocaine. Reentry was also induced in atrial tissue around the tricuspid orifice when this structure was isolated and superfused in vitro. Tachycardia cycle lengths varied from 205 to 399 msec, depending on the circumference of the ring and temperature. Induction of tachycardia by premature stimulation depended on differences in the duration of the effective refractory period among parts of the ring. Conduction velocity was relatively uniform and was slower during tachycardias than during pacing at long cycle lengths. Analysis of the response to premature stimuli that reset the tachycardia provided evidence for incomplete recovery of excitability between depolarizations during the tachycardia. Fast-response action potentials were recorded throughout the pathway and up to six to eight cell layers deep. Histologic studies showed the supravalvular lamina, a circumferential band of fibers several cell layers below the endocardial surface, to be continuous around the tricuspid orifice. Propagation through this layer best explains the conduction velocities observed in the intact heart during flutter in this preparation.

Multiple types of Ca2+ currents in single canine Purkinje cells.

Whole-cell Ca2+ channel currents were recorded from isolated single canine Purkinje and ventricular cells to determine whether there were multiple types of Ca2+ channels in these two cell types, as in many other excitable tissues. The experimental conditions were such that currents other than Ca2+ channel currents were largely suppressed. The charge carrier was either Ca2+ or Ba2+ (5 mM). In every canine Purkinje cell studied (n=36), we saw T and L Ca2+ channel currents that are similar to their counterparts in other tissues. Neither current was affected by tetrodotoxin (30 fiM), but both were reduced by Mn2+ (5 mM). Ni1+ (SO fiM) blocked T more than L current. Nisoldipine (1 μM) apparently abolished the L current but also decreased the T current by 50%. Substitution of Ba2+ for Ca2+ augmented and prolonged L current but did not affect T current significantly. At 36° C and with 5 mM (Ca2+]0, T current inactivated over a voltage range from -70 to -30 mV whereas L current inactivated between -30 and +20 mY. T current was detectable in only some of the ventricular cells studied (8 out of 12). In these cells the ratio of maximal T current to maximal L current (0.2 ± 0.1, n=S) was lower than the T/L ratio in Purkinje cells (0.6 ± 0.2, n-6). The density of peak L current in ventricular cells (7.5 ± 1.7 pA/pF, n=8) was higher than that in Purkinje cells (4.4 ± 3.4 pA/pF, n=6). Therefore, in ventricular cells the L current is the main Ca2+ current whereas in Purkinje cells, the T current also contributes significantly to membrane electrical activity. In Purkinje cells, β-adrenoceptor stimulation by isoproterenol (1 μM) increased L current but did not affect T current. On the other hand, in 70% (7 out of 10) of the Purkinje cells, α-adrenoceptor stimulation by 10 μM norepinephrine (in the presence of 2 μM propranolol) increased the T current. Our observations show that the distribution of the two types of Ca2+ channels in canine ventricle is heterogeneous and that the two types of Ca2+ channels are modulated by catecholamines by different receptors.

Oxidative Mediated Lipid Peroxidation Recapitulates Proarrhythmic Effects on Cardiac Sodium Channels

Sudden cardiac death attributable to ventricular tachycardia/fibrillation (VF) remains a catastrophic outcome of myocardial ischemia and infarction. At the same time, conventional antagonist drugs targeting ion channels have yielded poor survival benefits. Although pharmacological and genetic models suggest an association between sodium (Na+) channel loss-of-function and sudden cardiac death, molecular mechanisms have not been identified that convincingly link ischemia to Na+ channel dysfunction and ventricular arrhythmias. Because ischemia can evoke the generation of reactive oxygen species, we explored the effect of oxidative stress on Na+ channel function. We show here that oxidative stress reduces Na+ channel availability. Both the general oxidant tert-butyl-hydroperoxide and a specific, highly reactive product of the isoprostane pathway of lipid peroxidation, E2-isoketal, potentiate inactivation of cardiac Na+ channels in human embryonic kidney (HEK)-293 cells and cultured atrial (HL-1) myocytes. Furthermore, E2-isoketals were generated in the epicardial border zone of the canine healing infarct, an arrhythmogenic focus where Na+ channels exhibit similar inactivation defects. In addition, we show synergistic functional effects of flecainide, a proarrhythmic Na+ channel blocker, and oxidative stress. These data suggest Na+ channel dysfunction evoked by lipid peroxidation is a candidate mechanism for ischemia-related conduction abnormalities and arrhythmias.

Age-related appearance of outward currents may contribute to developmental differences in ventricular repolarization.

Ventricular repolarization significantly influences contractility, refractoriness, and ion channel state. Factors affecting repolarization will thus affect these secondary phenomena. To understand the influence of age on ventricular repolarization, we studied neonatal, young, and adult dogs using electrocardiogram, action potential, and whole-cell voltage-clamp recordings from single epicardial myocytes. Hearts of neonatal and 57-58-day-old dogs require a significantly longer time for repolarization than those of adult dogs, as determined by analysis of rate-corrected QT and JT (QT minus QRS) intervals. Epicardial action potentials of neonates are significantly longer than those of adults, as determined by measurements of duration at 50% and 90% repolarization. The adult action potential is characterized by a large phase 1 notch that is absent from neonatal recordings. This notch develops between 58 and 64 days of age, and by 64-68 days of age, it is equal to that in adults. In addition, action potentials recorded from adult and young epicardial muscle are more greatly affected by rapid pacing and superfusion of 2 mM 4-aminopyridine than are potentials recorded from neonatal tissue. Whole-cell voltage-clamp recordings reveal a 4-aminopyridine-sensitive transient outward current in adult myocytes that is absent from neonatal myocytes. The correlation between developmental changes in the 4-aminopyridine-sensitive current, the action potential, and the QT interval suggests that the transient outward current may be an important determinant in the relation between age and repolarization.