Repolarization Gradients Research Articles

In vivo gene transfer of Kv1.5 normalizes action potential duration and shortens QT interval in mice with long QT phenotype.

Mutations in cardiac voltage-gated K+ channels cause long QT syndrome (LQTS) and sudden death. We created a transgenic mouse with a long QT phenotype (Kv1DN) by overexpression of a truncated K+ channel in the heart and investigated whether the dominant negative effect of the transgene would be overcome by the direct injection of adenoviral vectors expressing wild-type Kv1.5 (AV-Kv1.5) into the myocardium. End points at 3-10 days included electrophysiology in isolated cardiomyocytes, surface ECG, programmed stimulation of the right ventricle, and in vivo optical mapping of action potentials and repolarization gradients in Langendorff-perfused hearts. Overexpression of Kv1.5 reconstituted a 4-aminopyridine-sensitive outward K+ current, shortened the action potential duration, eliminated early afterdepolarizations, shortened the QT interval, decreased dispersion of repolarization, and increased the heart rate. Each of these changes is consistent with a physiologically significant primary effect of adenoviral expression of Kv1.5 on ventricular repolarization of Kv1DN mice.

Effects of halothane on action potential configuration in sub-endocardial and sub-epicardial myocytes from normotensive and hypertensive rat left ventricle

Halothane shortens ventricular action potential duration (APD), as a consequence of its inhibitory effects on a variety of membrane currents, an effect that is greater in sub-endocardial than sub-epicardial myocytes. In hypertrophied ventricle, APD is prolonged as a consequence of electrical remodelling. In this study, we compared the effects of halothane on transmural APD in myocytes from normal and hypertrophied ventricle. Myocytes were isolated from the sub-endocardium and sub-epicardium of the left ventricle of spontaneously hypertensive (SHR) and normotensive Wistar-Kyoto (WKY) rats. Action potentials were recorded before, during, and after a 1-min exposure to 0.6 mM halothane and APD measured from the peak of the action potential to repolarization at -50 mV (APD(-50 mV)). Data are presented as mean (SEM). In WKY myocytes, halothane reduced APD(-50 mV) from 21 (2) to 18 (2) ms (P<0.001, n=15) in sub-epicardial myocytes but abbreviated APD(-50 mV) to a greater extent in sub-endocardial myocytes (37 (4) to 28 (3) ms; P<0.001, n=14). In SHR myocytes, APD(-50 mV) values were prolonged compared with WKY and APD(-50 mV) was reduced by halothane from 36 (6) to 27 (4) ms (P<0.016) and from 77 (10) to 38 (4) ms (P<0.001) in sub-epicardial and sub-endocardial myocytes, respectively. In the SHR, hypertrophic remodelling was not homogeneous; APD(-50 mV) was prolonged to a greater extent in sub-endocardial than sub-epicardial cells. Halothane reduced APD to a greater extent in sub-endocardium than sub-epicardium in both WKY and SHR but this effect was larger proportionately in SHR myocytes. The transmural gradient of repolarization was reduced in WKY and effectively abolished in SHR by halothane, which might disturb normal ventricular repolarization.

Transmural action potential repolarization heterogeneity develops postnatally in the rabbit

Introduction: In the hereditary long QT syndrome, arrhythmia risk changes with age despite the presence of an ion channel mutation throughout development. Age-dependent changes in the transmural dispersion of repolarization may modulate this vulnerability. We recorded cardiac action potentials in infant, periadolescent, and adult rabbit myocardium to determine if transmural heterogeneities in repolarization are developmentally determined. Methods and Results: Arterially perfused ventricular preparations were studied from 2-week (n = 7), 7-week (n = 7), and adult (n = 6) NZW rabbits. Action potentials were recorded with microelectrodes in five regions: epicardium (epi), subepicardium (subepi), midwall (mid), subendocardium (subendo), and endocardium (endo) during endocardial S1 pacing at cycle lengths of 2,000, 1,000, and 500 ms. At 2 weeks, the transmural APD90 profile was flat. With age, APD prolongation from subepi to endo created a transmural repolarization gradient. At 7 weeks, APD90 was significantly longer at subendo [204 ± 2 ms (mean ± SE) 2,000-ms cycle length, P < 0.05] vs both endo (193 ± 2 ms) and epi (172 ± 2 ms), causing a heterogeneous transmural APD90 gradient. In adults, the transmural gradient was a smooth continuum such that APD was shortest in epicardium and longest in endocardium. Conclusion: The transmural distribution of APD is developmentally determined. Tissue-specific age-dependent changes in APD can result in transmural repolarization heterogeneity. These age-related effects may modulate arrhythmia vulnerability during development. (J Cardiovasc Electrophysiol, Vol. 15, pp. 795-801, July 2004)

Relation of twelve-lead electrocardiographic T-wave morphology descriptors to left ventricular mass

Echocardiographically detected left ventricular (LV) hypertrophy is an independent risk factor for sudden cardiac death, and the relative risk increases as LV mass increases. 1 Experimental studies strongly suggest that development of LV hypertrophy creates arrhythmia-generating repolarization abnormalities. 2‐6 The inscription of the T wave on the body surface electrocardiogram (ECG) is generated by repolarization gradients at the myocardial level. 7,8 A change in these gradients has an effect on T-wave morphology. 7‐10 Thus, repolarization gradients, arrhythmic vulnerability, and T-wave morphology are interrelated. 8,11 Recently, novel T-wave morphology descriptors on the 12-lead ECG 12 were shown to carry important prognostic information on arrhythmic susceptibility in patients with coronary artery disease. 13,14 We examined whether T-wave morphology descriptors are associated with echocardiographically determined LV hypertrophy and correlate with the degree of LV hypertrophy. ••• We studied 50 subjects who participated in an ongoing study examining the capability of body surface mapping techniques to detect LV hypertrophy. The LV hypertrophy group (n 35) consisted of 24 patients with hemodynamically significant aortic stenosis and 11 patients with essential arterial hypertension, all of whom had echocardiographic LV hypertrophy by gender-specific criteria (LV mass indexed to body surface area 116 g/m 2 in men; 104 g/m 2 in women). 15 No patient had echocardiographic wall motion abnormalities or pathologic Q waves on the ECG. In addition, no patient with aortic stenosis had 70% stenosis of the luminal diameter in epicardial arteries on routine coronary angiography, and no patient with essential hypertension had a history of effort angina. The control group consisted of 15 healthy middleaged volunteers who had no cardiovascular risk factors or a history or signs of heart disease. In these 15 subjects, a screening echocardiogram showed no evidence of anatomic or valvular abnormalities, and a symptom-limited exercise test without ST-segment

Cytosolic Ca2+ triggers early afterdepolarizations and Torsade de Pointes in rabbit hearts with type 2 long QT syndrome.

The role of intracellular Ca2+ (Ca2+i) in triggering early afterdepolarizations (EADs), the origins of EADs and the mechanisms underlying Torsade de Pointes (TdP) were investigated in a model of long QT syndrome (Type 2). Perfused rabbit hearts were stained with RH327 and Rhod-2/AM to simultaneously map membrane potential (V(m)) and Ca2+i with two photodiode arrays. The I(Kr) blocker E4031 (0.5 microM) together with 50 % reduction of [K+]o and [Mg2+]o elicited long action potentials (APs), V(m) oscillations on AP plateaux (EADs) then ventricular tachycardia (VT). Cryoablation of both ventricular chambers eliminated Purkinje fibres as sources of EADs. E4031 prolonged APs (0.28 to 2.3 s), reversed repolarization sequences (baseapex) and enhanced repolarization gradients (30 to 230 ms, n = 12) indicating a heterogeneous distribution of I(Kr). At low [K+]o and [Mg2+]o, E4031 elicited spontaneous Ca2+iand V(m) spikes or EADs (3.5 +/- 1.9 Hz) during the AP plateau (n = 6). EADs fired 'out-of-phase' from several sites, propagated, collided then evolved to TdP. Phase maps (Ca2+ivs. V(m)) had counterclockwise trajectories shaped like a 'boomerang' during an AP and like ellipses during EADs, with V(m) preceding Ca2+iby 9.2 +/- 1.4 (n = 6) and 7.2 +/- 0.6 ms (n = 5/6), respectively. After cryoablation, EADs from surviving epicardium (~1 mm) fired at the same frequency (3.4 +/- 0.35 Hz, n = 6) as controls. At the origins of EADs, Ca2+ipreceded V(m) and phase maps traced clockwise ellipses. Away from EAD origins, V(m) coincided with or preceded Ca2+i. In conclusion, overload elicits EADs originating from either ventricular or Purkinje fibres and 'out-of-phase' EAD activity from multiple sites generates TdP, evident in pseudo-ECGs.

Unique topographical distribution of M cells underlies reentrant mechanism of torsade de pointes in the long-QT syndrome.

Specific ion channel mutations underlie the congenital long-QT syndrome (LQTS). However, the mechanisms by which dysfunction at the molecular level translates into functional electrical instability leading to torsade de pointes (TdP) in LQTS are poorly understood. The cellular basis of TdP was investigated using a novel approach of transmural optical imaging in the canine wedge preparation (n=14). The spatial organization of repolarization and arrhythmogenesis were determined in a surrogate model of LQT2. Action potentials were recorded simultaneously from 128 sites spanning the transmural wall of the left ventricle. In LQT2, QT interval prolongation was paralleled by an abrupt rise in transmural dispersion of repolarization (DOR) from 2.7 plus/minus 0.9 ms/mm (controls) to 12.2 plus/minus 2.1 ms/mm (LQT2). Islands of midmyocardial (M) cells formed zones of increased refractoriness in LQT2, producing steep spatial gradients of repolarization that were directly responsible for conduction block and self-sustained intramural reentrant circuits underlying TdP. These data provide direct evidence supporting the functional expression of M cells in intact myocardium and a central role for M cells in the development of reentrant TdP arrhythmias in LQTS.

T-Wave Shape in Clinical Research

To the Editor: The editorial by Wilde and Roden1 in the December 5, 2000, issue of Circulation discussed how differences in electrocardiographic ST-T–wave patterns, together with other phenotypic differences, arise in genetically distinct forms of long-QT syndrome (LQTS).2 The authors observed how important these results can be for the investigation of the pathophysiology of ventricular repolarization. The T wave is the result of repolarization gradients across the ventricular myocardium. The LQTS ST-T–wave pattern study by Zhang et al,2 to which the editorial referred, showed that broad-based T waves are characteristic for LQT1. The editorial also referred to the work of Yan and Antzelevitch,3 …

Global repolarization sequence of the ventricular endocardium: monophasic action potential mapping in swine and humans.

The aim of this study was to evaluate the global sequence of repolarization over the ventricular endocardium. Disturbances in myocardial repolarization are associated with the genesis of arrhythmias. However, little is known about the global sequence of repolarization. Monophasic action potentials (MAPs) were recordedfrom 61 +/- 18 LV and/or RV sites in ten healthy pigs and from 43 +/- 15 LV or RV sites in eight patients using the CARTO system. Local activation time (AT), end-of-repolarization (EOR) time, and MAP duration were calculated and three-dimensional global maps of AT, EOR, and MAP duration constructed. LV maps were obtained from all ten pigs and RV maps from three pigs. Five RV maps and five LV maps were obtained from the eight patients. (1) EOR sequence was recognizable in 12 of 13 pig maps and in all the patient maps. (2) EOR followed the sequence of activation in 12 of 13 pig maps and 8 of 10 patient maps. (3) The longest MAPs were recorded in or near the earliest activation area, and the shortest ones in or near the latest activation area in all the pig maps and in nine often and eight often patient maps, respectively. (4) In all maps, MAP duration and AT were negatively correlated, and EOR and AT positively correlated. In conclusion, repolarization gradients exist over the pig and the human ventricular endocardium. The activation sequence is a determinant for the repolarization sequence. The magnitude of the progressive MAP shortening with progressively later activation, relative to local AT, is a critical factor governing the direction and pattern of the EOR.

Cycle length-associated modulation of the regional dispersion of ventricular repolarization in a canine model of long QT syndrome.

Previous tridimensional activation mapping showed that the development of functional conduction block at the onset of torsades de pointes was regionally heterogeneous; conduction block was frequently observed in the LV and the interventricular septum (IVS) but not in the RV, in the canine anthopleurin-A (AP-A) model of long QT syndrome (LQTS). This may be related to the distribution of myocytes with M celllike electrophysiological characteristics. To better understand the regional difference of arrhythmogenicity in LQTS, the authors investigated cycle length related modulation of ventricular repolarization among three different layers: the endocardium (End), mid-myocardium (Mid), and epicardium (Epi) of the LV and RV and at two different areas: the Epi and septum (Sep) in the IVS. The LQT3 model was produced by AP-A in dogs. Using constant pacing and single premature stimulation (S1S2), the ventricular repolarization pattern was analyzed from 256 unipolar electrograms. Activation-recovery intervals (ARIs) were used to estimate local repolarization. In seven experiments, AP-A increased regional ARI dispersion to 88.1 +/- 36.0 ms in the LV, to 72.9 +/- 35.7 ms in the IVS, and to 23.0 +/- 8.7 ms in the RV at the pacing cycle length (CL) of 1,000 ms. Development of the large ARI dispersion was due to greater ARI prolongation at the Mid site in the LV and at Sep site in the IVS. As the S1S2 interval was shortened, regional ARI dispersion decreased gradually, and finally, ARI dispersion showed a reversal gradient of repolarization between the Mid and Epi sites in the LV and between the Sep and Epi sites in the IVS. Two factors contributed to create the reversal gradient of repolarization: (1) a difference in restitution kinetics at the Mid site in the LV and at the Sep site in the IVS, characterized by a larger delta ARI and slower time constant (tau), and (2) a difference in diastolic intervals at each site resulting in different input to restitution at the same CL. However, the RV showed small alteration in the transmural dispersion of repolarization in the S1S2 protocol. S2 created heterogeneous functional conduction block in the LV and IVS but not in the RV. In the LQT3 model, the arrhythmogenicity of torsades de pointes is primarily due to dispersion of repolarization in the LV and IVS because of prominent distribution of M cells. The RV seems to participate passively in reentrant excitation during torsades de pointes.

Influence of transmural repolarization gradients on the electrophysiology and pharmacology of ventricular myocardium. Cellular basis for the Brugada and long–QT syndromes

Ventricular myocardium comprises at least three electrophysiologically distinct cell types: epicardial, endocardial and M cells. Epicardial and M cells, but not endocardial cells, display action potentials with a notched or spike–and–dome morphology: the result of a prominent, transient, outward current–mediated phase 1. M cells are distinguished from endocardial and epicardial cells by the ability of their action potential to disproportionately prolong in response to a slowing down of rate and/or in response to agents with class III actions. This intrinsic electrical heterogeneity contributes to the inscription of the electrocardiogram (ECG) as well as to the development of a variety of cardiac arrhythmias. Heterogeneous response of the three cell types to pharmacological agents and/or pathophysiological states results in amplification of intrinsic electrical heterogeneities, thus providing a substrate as well as a trigger for the development of re–entrant arrhythmias, including Torsade de Pointes, commonly associated with the long–QT syndrome (LQTS), and the polymorphic ventricular tachycardia/ventricular fibrillation (VT/VF) encountered in the Brugada syndrome. Despite an abundance of experimental data describing the heterogeneity of cellular electrophysiology that exists across the ventricular wall, relatively few computer models have been developed to investigate the physiological and pathophysiological consequences of such electrical heterogeneity. As computer power increases and numerical algorithms improve, three–dimensional computer models of ventricular conduction that combine physiological membrane kinetics with realistic descriptions of myocardial structure and geometry will become more feasible. With sufficient detail and accuracy, these models should illuminate the complex mechanisms underlying the initiation and maintenance of Torsade de Pointes and other arrhythmias.

Transmural repolarisation in the left ventricle in humans during normoxia and ischaemia.

Studies in isolated tissues and myocytes show different repolarisation properties in subepicardium, midmyocardium and subendocardium. Whether these differences are present in vivo and are relevant to humans has been the subject of controversy. Our objectives were (1) to ascertain whether transmural repolarisation gradients are present in humans, (2) to determine whether the greater sensitivity of subepicardial cells to ischaemia in vitro is manifest during early ischaemia in humans in vivo. We studied 21 patients during routine coronary artery surgery. Unipolar activation recovery intervals (ARI) were recorded from five transmural locations between subepicardium and subendocardium in the left ventricular wall. A pacing protocol spanned a range of cycle lengths from a cycle length of 300 ms to the maximum permitted by the intrinsic atrial activity. Following the onset of cardiopulmonary bypass recordings were obtained before (control) and during a 3-min period of global ischaemia. During control transmural ARIs were homogeneous between 300 and 1500 ms (ventricular pacing) and 750 and 1500 ms (atrial spontaneous beats). During ischaemia, ARIs shortened similarly at all transmural electrode sites and transmural homogeneity was maintained. Transmural repolarisation differences within the ventricular wall of the human heart were absent at cycle lengths within the physiological range but also during prolonged cycles. During early (global) ischaemia repolarisation changed equally in subepicardial and subendocardial regions and transmural homogeneity of repolarisation was preserved.

Role of structural barriers in the mechanism of alternans-induced reentry.

Previously, using an animal model of T-wave alternans in structurally normal myocardium, we demonstrated that repolarization can alternate with opposite phase between neighboring myocytes (ie, discordant alternans), causing spatial dispersions of repolarization that form the substrate for functional block and reentrant ventricular fibrillation (VF). However, the mechanisms responsible for cellular discordant alternans and its electrocardiographic manifestation (ie, T-wave alternans) in patients with structural heart disease are unknown. We hypothesize that electrotonic uncoupling between neighboring regions of cells by a structural barrier (SB) is a mechanism for discordant alternans. Using voltage-sensitive dyes, ventricular action potentials were recorded from 26 Langendorff-perfused guinea pig hearts in the absence (ie, control) and presence of an insulating SB produced by an epicardial laser lesion. Quantitative analysis of magnitude and phase of cellular alternans revealed that in controls, action potential duration alternated in phase at all ventricular sites above a critical heart rate (269+/-17 bpm), ie, concordant alternans. Also, above a faster critical heart rate threshold (335+/-24 bpm), action potential duration alternated with opposite phase between sites, ie, discordant alternans. In contrast, only discordant but not concordant alternans was observed in 80% of hearts with the SB, and discordant alternans always occurred at a significantly slower heart rate (by 68+/-28 bpm) compared with controls. Therefore, the SB had a major effect on the alternans-heart rate relation, which served to facilitate the development of discordant alternans. Whether a SB was present or not, discordant alternans produced considerable increases (by approximately 170%) in the maximum spatial gradient of repolarization, which in turn formed the substrate for unidirectional block and reentry. However, by providing a structural anchor for stable reentry, discordant alternans in the presence of a SB led most often to sustained monomorphic ventricular tachycardia rather than to VF, whereas in the absence of a SB discordant alternans caused VF. SBs facilitate development of discordant alternans between cells with different ionic properties by electrotonically uncoupling neighboring regions of myocardium. This may explain why arrhythmia-prone patients with structural heart disease exhibit T-wave alternans at lower heart rates. These data also suggest a singular mechanism by which T-wave alternans forms a substrate for initiation of both VF and sustained monomorphic ventricular tachycardia.

Interdependence of modulated dispersion and tissue structure in the mechanism of unidirectional block.

We previously showed that a premature stimulus can significantly alter vulnerability to arrhythmias by modulating spatial gradients of ventricular repolarization (ie, modulated dispersion). However, it is not clear if such changes in arrhythmia vulnerability can be attributed to the formation of an electrophysiological substrate for unidirectional block and what the potential role is of tissue structure in this process. Therefore, the main objective of the present study was to examine the concomitant effect repolarization gradients and tissue structure have on unidirectional block. Optical action potentials were recorded from 128 ventricular sites (1 cm(2)) in 8 Langendorff-perfused guinea pig hearts. Propagation was confined to the epicardial surface using an endocardial cryoablation procedure, and a 12-mm barrier with a 1.5-mm isthmus was etched with a laser onto the epicardium. A premature stimulus (S2) was delivered over a range of S1S2 coupling intervals to modulate repolarization gradients in a predictable fashion. When a second premature stimulus (S3) was delivered from the center of the isthmus, the occurrence and orientation of unidirectional block were highly dependent on repolarization gradients created by the S2 beat. In this model, a local repolarization gradient of 3.2 ms/mm was required for unidirectional block at this isthmus. In addition, the formation of unidirectional block was critically dependent on the presence of the source-sink mismatch imposed by the isthmus. These results may explain how the interplay between spatial heterogeneities of repolarization and tissue structure form a substrate for unidirectional block and reentry.

Reversal of repolarization gradient does not reverse the chirality of shock-induced reentry in the rabbit heart.

Two hypotheses have been proposed to explain the mechanisms of vulnerability and related failure of defibrillation therapy: the cross-field-induced critical point hypothesis and the virtual electrode-induced phase singularity hypothesis. These two hypotheses predict the opposite effect of preshock repolarization on the chirality (direction of rotation) of shock-induced reentry. The former suggests its reversal upon reversal of repolarization, whereas the latter suggests its preservation. The aim of this study was to determine, by reversing the repolarization sequence, which of the mechanisms is responsible for internal shock-induced arrhythmia in the Langendorff-perfused rabbit heart. We used high-resolution optical mapping to assess the chirality of postshock reentry in 11 hearts. Hearts were paced at a coupling interval of 300 msec at various sites around the field of view (13.5 x 13.5 to 16.5 x 16.5 mm). Cathodal monophasic implantable cardioverter defibrillator shocks (-100 V, 8 msec) were applied during the T wave from a 10-mm coil electrode placed into the right ventricular cavity. We used 3.5 +/- 0.8 different pacing sites per heart. Change in direction of repolarization did not result in change of chirality. Chirality was constant in all 11 hearts despite the complete reversal of activation and repolarization patterns. However, the position of resulting vortices depended on transmembrane polarization gradient inverted delta Vm and amplitude of negative polarization Vm (deexcitation). Stronger gradients and deexcitation produced earlier epicardial break excitation (P = 0.04 and P < 0.0001, respectively). Virtual electrode-induced phase singularity mechanism underlies internal shock-induced arrhythmia in this model.

Cellular basis for dispersion of repolarization underlying reentrant arrhythmias

Substantial heterogeneity in ion channel density and expression exists in cells isolated from various regions of the heart. Cell-to-cell coupling in the intact heart, however, is expected to attenuate the functional expression of the ion channel heterogeneities. Due to limitations of conventional electrophysiological recording techniques, the extent to which cellular electrical heterogeneities are functionally present in intact myocardium remains unknown. High-resolution optical mapping with voltage-sensitive dyes was used to measure transepicardial and transmural repolarization gradients in the Langendorff perfused guinea pig ventricle and the canine wedge preperation, respectively. Diversity of repolarization kinetics in the transepicardial direction modulated dispersion of repolarization in a biphasic fashion as premature coupling interval was shortened. Moreover, modulation of repolarization paralleled arrhythmia vulnerability in a predictable fashion. Transmural optical mapping revealed significant gradients of repolarization across the ventricular wall that were markedly increased in a surrogate model of LQTS. Transmural gradients of repolarization in LQTS were associated with an enhanced susceptibility to TdP. Therefore, despite strong cell-to-cell coupling in the normal heart, heterogeneities in the ionic make-up of cells across the epicardial and transmural surfaces result in functional heterogeneities of repolarization leading to arrhythmias.

Electrophysiological responses of canine atrial endocardium and epicardium to acetylcholine and 4-aminopyridine

Prior studies demonstrated marked electrophysiological and pharmacological differences between canine ventricular epicardium and endocardium. For atrium, however, it has been assumed that, because of the thin wall, electrical properties of epicardium and endocardium are similar. The aim of the present study was to compare the action potential (AP) characteristics in epicardial and endocardial atrial cells before and following addition of acetylcholine (ACh) and 4-aminopyridine (4-AP). Microelectrode techniques were used to study the effects of ACh (10(-7)-10(-5) M) and 4-AP (0.5 mM) on epicardial and endocardial AP of canine right atrial free wall at cycle lengths (CL) of 250 to 2000 ms. ACh hyperpolarized epicardial and endocardial cells (by 5-8 mV at 10(-5) M). In control, AP duration to 90% repolarization (APD90) was longer in endocardium at all CL. ACh shortened APD90 in either tissue with more prominent effect in endocardium (at 10(-5) M and CL = 2000 ms, from 179 +/- 10 to 90 +/- 11 ms in epicardium and from 209 +/- 10 to 65 +/- 6 ms in endocardium, P < 0.05). As a result, at 10(-5) M, APD90 in endocardium was shorter than in epicardium at all CL 4-AP effects on AP duration were similar in both tissue types. No effects of 4-AP was seen at CL = 250 ms and at long CL, the compound shortened APD90 and prolonged AP duration to 50% repolarization. (1) ACh exerts direct effects on atrial epicardial and endocardial AP; (2) 4-AP-sensitive transient outward current (Itol) is expressed both in canine atrial epicardial and endocardial cells; (3) differential response of epicardial and endocardial APD to ACh may alter the gradient of repolarization across the atrial wall and contribute to vagally induced atrial flutter and fibrillation.

Silent Myocardial Ischemia and Late Ventricular Repolarization in the Genesis of Ventricular Fibrillation in Humans

BackgroundWe report a well‐documented case of a patient, a 62‐year‐old man, with severe and asymptomatic left main coronary artery disease who had several episodes of silent myocardial ischemia and a syncopal attack during Holter recording.Methods and ResultsAmbulatory monitoring showed isolated giant U waves separated from the T wave 60 minutes before syncope that was due to reversible ventricular fibrillation lasting about 4 minutes and spontaneously reverting to asystole (7 seconds) and then to atrial fibrillationConclusionOur experience suggests that myocardial ischemia may differently affect the repolarization times within the myocardium leading to widely disparate repolarization gradients that may represent the arrhythmogenic substrate for the occurrence of life‐threatening ventricular tachyarrhythmias. A.N.E. 1999; 4(2):250–254

Mechanism linking T-wave alternans to the genesis of cardiac fibrillation.

Although T-wave alternans has been closely associated with vulnerability to ventricular arrhythmias, the cellular processes underlying T-wave alternans and their role, if any, in the mechanism of reentry remain unclear. -T-wave alternans on the surface ECG was elicited in 8 Langendorff-perfused guinea pig hearts during fixed-rate pacing while action potentials were recorded simultaneously from 128 epicardial sites with voltage-sensitive dyes. Alternans of the repolarization phase of the action potential was observed above a critical threshold heart rate (HR) (209+/-46 bpm) that was significantly lower (by 57+/-36 bpm) than the HR threshold for alternation of action potential depolarization. The magnitude (range, 2.7 to 47.0 mV) and HR threshold (range, 171 to 272 bpm) of repolarization alternans varied substantially between cells across the epicardial surface. T-wave alternans on the surface ECG was explained primarily by beat-to-beat alternation in the time course of cellular repolarization. Above a critical HR, membrane repolarization alternated with the opposite phase between neighboring cells (ie, discordant alternans), creating large spatial gradients of repolarization. In the presence of discordant alternans, a small acceleration of pacing cycle length produced a characteristic sequence of events: (1) unidirectional block of an impulse propagating against steep gradients of repolarization, (2) reentrant propagation, and (3) the initiation of ventricular fibrillation. Repolarization alternans at the level of the single cell accounts for T-wave alternans on the surface ECG. Discordant alternans produces spatial gradients of repolarization of sufficient magnitude to cause unidirectional block and reentrant ventricular fibrillation. These data establish a mechanism linking T-wave alternans of the ECG to the pathogenesis of sudden cardiac death.

Factors affecting epicardial dispersion of repolarization: a mapping study in the isolated porcine heart.

Non-uniform drug-induced prolongation of repolarization predominating in the midmyocardial (M) cell layers has been shown to be responsible for perpetuation of reentry, giving rise to torsade de pointes. However, the absence of M cells in immature animals, especially the pig, suggests other possible underlying mechanisms. We sought to examine, in this species, the effects of predisposing factors to torsade de pointes on the dispersion of epicardial repolarization and their contribution to arrhythmogenesis. Computerized mapping of repolarization and activation was conducted on the epicardial surface in 29 Langendorff-perfused hearts of eight-week-old pigs. Activation-recovery intervals were measured simultaneously from 128 unipolar electrograms. Baseline iso-interval maps were dipolar (41%) or multipolar (59%). Dispersion of repolarization was reverse frequency-dependent but was unaffected by lowering [K+]o. DL-Sotalol (0.1 mmol/l) reinforced local gradients and thus increased epicardial dispersion, whereas intramural recordings did not demonstrate any predominant effect in midmyocardial layers. Phenylephrine (1 mumol/l) notably augmented DL-sotalol effects. After [Mg++]o lowering, although dispersion was not significantly increased, DL-sotalol was associated with the spontaneous occurrence of polymorphic ventricular tachycardia in seven out of nine experiments. When maps of repolarization of escape beats were compared with activation maps of first arrhythmic beats, an arc of functional dissociation was observed in the vicinity of a steep gradient of repolarization in two out of nine tachycardias. Epicardial dispersion of repolarization is increased by slow rates, DL-sotalol and phenylephrine but is not the only requirement for initiation of polymorphic ventricular tachycardia. In combination with other factors, it helps continuation of the arrhythmia in this model.

Paradoxical QRST integral changes with ventricular repolarization dispersion

Body surface QRST integral (QRSTI) maps have been shown theoretically to reflect disparity of intrinsic repolarization properties and have been experimentally linked to increased arrhythmia susceptibility. Paradoxically, a lower magnitude of QRSTI in patients with heart disease and at risk for arrhythmias has been reported. We hypothesized that this paradoxical reduction in QRST magnitude is a consequence of increased heterogeneity of repolarization gradients in normal hearts. We generated QRSTI using a previously published heart model to compare QRSTI for aligned and random repolarization gradients. The heart model consisted of 50,000 cubic units in an anatomically correct arrangement that included parameters to simulate anisotropic conduction and inhomogeneous distribution of refractoriness. Body surface potential maps (BSPMs) were generated on a torso surface assuming a homogeneous torso and using the boundary element method for normal alignment of repolarization gradients and spatially reassigned repolarization values that randomized repolarization directions. QT duration was measured by the subtraction of Q onset time from T offset time on the BSPM. T offset was defined as the last potential to be detected at intervals of 3 ms that was above the threshold of 0.1 mV during recovery. The time of T offset showed a consistent tendency to shift to the left posterior and to split. When slow conduction velocities were assigned, BSPMs showed delayed propagation and multiple extrema. QRSTI showed systematic magnitude decrease with increasing randomness of repolarization gradient direction. Ventricular fibrillation (VF) could be induced by successive extrastimuli under the conditions of over 70% deviation and slow conduction of 0.5 m/s for the longitudinal direction. In conclusion, a possible explanation for the paradoxical reduction in QRSTI in the presence of constant repolarization disparity is the change in alignment of repolarization gradients.