A novel LQT3 mutation implicates the human cardiac sodium channel domain IVS6 in inactivation kinetics

The Long QT3 syndrome is associated with mutations in the cardiac sodium channel gene SCN5A. OBJECTIVE: The aim of the present study was the identification and functional characterization of a mutation in a family with the long QT3 syndrome. METHODS: The human cardiac sodium channel gene SCN5A was screened for mutations by single-stranded conformation polymorphism. The functional consequences of mutant sodium channels were characterized after expressing mutant and wild-type cRNAs in Xenopus oocytes by two-electrode voltage clamp measurements. RESULTS: SCN5A screening revealed an A-->G substitution at codon 1768, close to the C-terminal end of domain IVS6, which changes an isoleucine to a valine. Functional expression of mutant I1768V-channels in Xenopus oocytes showed that the voltage-dependence and slope factors of activation and inactivation were unchanged compared to wild-type channels. No difference in persistent TTX-sensitive current could be detected between wild-type and I1768V channels, a channel feature often increased in LQT3 mutants. However, I1768V mutant channels recovered faster from inactivation (2.4 times) than wild-type channels and displayed less slow inactivation. CONCLUSIONS: We postulate that severe destabilization of the inactivated state leads to increased arrhythmogenesis and QT prolongation in I1768V mutation carriers in the absence of a persistent inward sodium current.     

Effects of Sodium Channel Block with Mexiletine to Reverse Action Potential Prolongation in In Vitro Models of the Long QT Syndrome

Sodium Channel Block in In Vitro Models of LQTS. Introduction: Recent clinical studies have reported a greater effectiveness of sodium channel block with mexiletine to abbreviate the QT interval in patients with the chromosome 3 variant (SCN5A, LQT3) of the long QT syndrome (LQTS) than those with the chromosome 7 form of the disease (HERG, LQT2), suggesting the possibility of gene-specific therapy for the two distinct forms of the congenital LQTS. Experimental studies using the arterially perfused left ventricular wedge preparation have confirmed these clinical observations on the QT interval but have gone on to further demonstrate a potent effect of mexiletine to reduce dispersion of repolarization and prevent torsades de pointes (TdP) in both LQT2 and LQT3 models. A differential action of sodium channel block on the three ventricular cell types is thought to mediate these actions of mexiletine. This study provides a test of this hypothesis by examining the effects of mexiletine in isolated canine ventricular epicardial, endocardial, and M region tissues under conditions that mimic the SCN5A and HERG gene defects. Methods and Results: We used standard microelectrode techniques to record transmembrane activity from endocardial, epicardial, mid-myocardial, and transmural strips isolated from the canine left ventricle, d-Sotalol, an I_kr blocker, was used to mimic the HERG defect (LQT2), and ATX-II, which increases late Na channel current, was used to mimic the SCN5A defect (LQT3). d-Sotalol (100 μM) preferentially prolonged the action potential of the mid-myocardial M cell (APD₉₀, increased from 340 ± 65 to 623 ± 203 msec) as did ATX-II (10 to 20 nM; APD₉₀, increased from 325 ± 51 to 580 ± 178 msec; basic cycle length = 2000 msec), thus causing a marked increase in transmural dispersion of repolarization (TDR). Mexiletine (2 to 20 μM) dose-dependently reversed the ATX-II-induced prolongation of APD₉₀, in all three cell types. Mexiletine also reversed the d-sotalol-induced prolongation of the M cell action potential duration (APD), but bad little effect on the action potential of epicardium and endocardium. Due to its preferential effect to abbreviate the action potential of M cells, mexiletine reduced the dispersion of repolarization in both models. Low concentrations of mexiletine (5 to 10 μM) totally suppressed early afterdepolarization (EAD) and KAD-induced triggered activity in both models. Conclusions: Our results indicate that the actions of mexiletine are both cell and model specific, but that sodium channel block with mexiletine is effective in reducing transmural differences in APD and in abolishing triggered activity induced by d-sotalol and ATX-II. The data suggest that mexiletine's actions to reduce TDR and prevent the induction of spontaneous and programmed stimulation-induced TdP in these models are due to a preferential effect of the drug to abbreviate the APD of the M cell and to suppress the development of EADs. The data provide further support for the hypothesis that block of the late sodium current may be of value in the treatment of LQT2 as well as LQT3 and perhaps other congenital and acquired (drug-induced) forms of LQTS.     

A cardiac sodium channel mutation identified in Brugada syndrome associated with atrial standstill

Mutations in the cardiac Na+ channel gene SCN5A are responsible for multiple lethal ventricular arrhythmias including Brugada syndrome and congenital long QT syndrome. Here we report a case of Brugada syndrome with ST elevation in the right precordial and inferior leads accompanied by atrial standstill and spontaneous ventricular fibrillation. Atrial standstill and J wave elevation were provoked by procainamide. Genetic analysis revealed a missense mutation (R367H) in SCN5A. The resultant mutant Na+ channel was nonfunctional when expressed heterologously in Xenopus oocytes. Our study suggests that genetic defects in SCN5A may be associated with atrial standstill in combination with ventricular arrhythmias.     

Cellular basis for the electrocardiographic and arrhythmic manifestations of Timothy syndrome: effects of ranolazine.

BACKGROUND: Timothy syndrome is a multisystem disorder associated with QT interval prolongation and ventricular cardiac arrhythmias. The syndrome has been linked to mutations in Ca(V)1.2 resulting in gain of function of the L-type calcium current (I(Ca,L)). Ranolazine is an antianginal agent shown to exert an antiarrhythmic effect in experimental models of long QT syndrome. OBJECTIVE: The purpose of this study was to develop and characterize an experimental model of Timothy syndrome by using BayK8644 to mimic the gain of function of I(Ca,L) and to examine the effects of ranolazine. METHODS: Action potentials from epicardial and M regions and a pseudo-electrocardiogram (ECG) were simultaneously recorded from coronary-perfused left ventricular wedge preparations, before and after addition of BayK8644 (1 microM). RESULTS: BayK8644 preferentially prolonged action potential duration of the M cell, leading to prolongation of the QT interval and an increase in transmural dispersion of repolarization (from 44.3 +/- 7 ms to 86.5 +/- 25 ms). Stimulation at cycle lengths of 250-500 ms led to ST-T wave alternans due to alternation of the plateau voltage of the M cell action potential as well as development of delayed afterdepolarizations in epicardial and M cell action potentials. Ventricular extrasystoles and tachycardia (monomorphic, bidirectional, or torsades de pointes) developed spontaneously or after rapid pacing. Peak and late I(Na) were unaffected by BayK8644. Clinically relevant concentrations of ranolazine (10 microM) suppressed all actions of BayK8644. CONCLUSION: A left ventricular wedge model of long QT syndrome created by augmentation of I(Ca,L) recapitulates the ECG and arrhythmic manifestations of Timothy syndrome, which can be suppressed by ranolazine.     

Analysis of action potentials in the canine ventricular septum: no phenotypic expression of M cells

OBJECTIVE: Transmural heterogeneity in the ventricular free wall, enhanced by the midmyocardial long action potential duration (APD) of M cells, plays an important role in the arrhythmogenesis of long QT syndrome. Although we observed dynamic expression of M cell phenotypes in the canine ventricular free wall, it is still unclear whether similar phenomena are present in the interventricular septum. This study evaluated transmural heterogeneity of APD in the septum. METHODS: We isolated and perfused 22 canine septal preparations through the septal branch of the anterior descending coronary artery, and optically mapped 256 channels of action potentials on their cut-exposed transseptal surfaces before and after treatment with sotalol (I(Kr) blocker), anemone toxin II (ATX-II, which slows the inactivation of I(Na)), or drug-free state in 6, 9, and 22 preparations, respectively. The preparations were paced from the left ventricular endocardium at cycle lengths of 500, 1000, 2000, and 4000 ms. RESULTS: We observed progressively lengthening of APD across the septum from the right ventricular to the left ventricular endocardium without a midmyocardial maximum under all conditions. All action potentials had minor phase-1 notches, resembling the endocardial action potential in the ventricular free wall. Increasing cycle lengths and concentrations of sotalol and ATX-II prolonged APD without midmyocardial preference and increased the transseptal dispersion of APDs. CONCLUSIONS: Canine interventricular septal action potentials are similar in shape to the endocardial action potentials in the ventricular free wall, with smooth transseptal transition in APD. We found no phenotypical expression of M cells in the canine interventricular septum.     

Differential effects of beta-adrenergic agonists and antagonists in LQT1, LQT2 and LQT3 models of the long QT syndrome

OBJECTIVES: To define the cellular mechanisms responsible for the development of life-threatening arrhythmias in response to sympathetic activity in the congenital and acquired long QT syndromes (LCQTS). METHODS: Transmembrane action potentials (AP) from epicardial (EPI), M and endocardial (ENDO) cells and a transmural electrocardiogram were simultaneously recorded from an arterially perfused wedge of canine left ventricle. We examined the effect of beta-adrenergic agonists and antagonists on action potential duration (APD90), transmural dispersion of repolarization (TDR) and the development of Torsade de Pointes (TdP) in models of LQT1, LQT2 and LQT3 forms of LQTS. RESULTS: I(Ks) block with chromanol 293B (LQT1) homogeneously prolonged APD90 of the three cell types without increasing TDR. Addition of isoproterenol prolonged QT and APD90 of M but abbreviated that of EPI and ENDO, causing a persistent increase in TDR; Torsade de Pointes developed or could be induced only in the presence of isoproterenol. I(Kr) block with d-sotalol (LQT2) and augmentation of late I(Na) with ATX-II (LQT3) prolonged APD90 of M more than EPI and ENDO, causing increases in QT and TDR. TdP developed in the absence of isoproterenol. In LQT2 isoproterenol initially prolonged, then abbreviated, the APD90 of M but always abbreviated EPI, thus transiently increasing TDR and the incidence of TdP. In LQT3, isoproterenol always abbreviated APD90 of the three cell types, causing a persistent decrease in TDR and suppression of TdP. The arrhythmogenic as well as protective actions of isoproterenol were reversed by propranolol. CONCLUSIONS: Our data suggest that beta-adrenergic stimulation induces TdP by increasing transmural dispersion of repolarization in LQT1 and LQT2 but suppresses TdP by decreasing dispersion in LQT3. The data indicate that beta-blockers are protective in LQT1 and LQT2 but may facilitate TdP in LQT3.     

A sodium channel pore mutation causing Brugada syndrome

BACKGROUND: Brugada and long QT type 3 syndromes are linked to sodium channel mutations and clinically cause arrhythmias that lead to sudden death. We have identified a novel threonine-to-isoleucine missense mutation at position 353 (T353I) adjacent to the pore-lining region of domain I of the cardiac sodium channel (SCN5A) in a family with Brugada syndrome. Both male and female carriers are symptomatic at young ages, have typical Brugada-type electrocardiogram changes, and have relatively normal corrected QT intervals. OBJECTIVES: To characterize the properties of the newly identified cardiac sodium channel (SCN5A) mutation at the cellular level. RESULTS: Using whole-cell voltage clamp, we found that heterologous expression of SCN5A containing the T353I mutation resulted in 74% +/- 6% less peak macroscopic sodium current when compared with wild-type channels. A construct of the T353I mutant channel fused with green fluorescent protein failed to traffic properly to the sarcolemma, with a large proportion of channels sequestered intracellularly. Overnight exposure to 0.1 mM mexiletine, a Na(+) channel blocking agent, increased T353I channel trafficking to the membrane to near normal levels, but the mutant channels showed a significant late current that was 1.6% +/- 0.2% of peak sodium current at 200 ms, a finding seen with long QT mutations. CONCLUSIONS: The clinical presentation of patients carrying the T353I mutation is that of Brugada syndrome and could be explained by a cardiac Na(+) channel trafficking defect. However, when the defect was ameliorated, the mutated channels had biophysical properties consistent with long QT syndrome. The lack of phenotypic changes associated with the long QT syndrome could be explained by a T353I-induced trafficking defect reducing the number of mutant channels with persistent currents present at the sarcolemma.     

Effect of sodium channel blockers on ST segment, QRS duration, and corrected QT interval in patients with Brugada syndrome

INTRODUCTION: Brugada syndrome is characterized by an ST segment elevation in leads V1-V3 and a high incidence of ventricular fibrillation (VF). A mutation in a cardiac Na+ channel gene, SCN5A, has been linked to Brugada syndrome, and sodium channel blockers have been shown to be effective in unmasking the syndrome when concealed. The aim of this study was to examine the effects of Na+ channel blockers on ST segment elevation, QRS, corrected QT (QTc) interval, and ventricular arrhythmias in patients with Brugada syndrome. METHODS AND RESULTS: We examined the effects of three different Na+ channel blockers (flecainide, disopyramide, and mexiletine) on the amplitude of the ST segment 20 msec after the end of QRS (ST20), QRS duration, QTc interval measured from 12-lead ECG, and ventricular arrhythmias in 12 Brugada and 10 control patients. Maximum ST20 observed in the V2 or V3 leads under baseline conditions was greater in the Brugada patients than in control patients, whereas QRS duration and maximum QTc interval were no different between the two groups. Flecainide and disopyramide, but not mexiletine, significantly increased maximum ST20 and QRS duration in both groups, although these effects were much more pronounced in the Brugada patients. The increases in ST20 and QRS duration with flecainide were significantly larger than those with disopyramide. An increase of 0.15 mV in ST20 with flecainide separated the two groups without overlap. Ventricular premature complexes developed only with flecainide in Brugada patients (3/12) displaying a marked ST elevation but not widening of QRS. CONCLUSION: Our findings suggest that Na+ channel blockers amplify existing I(Na) and possibly other ion channel defects, with a potency inversely proportional to the rate of dissociation of the drug from the Na+ channel, thus causing a prominent elevation of the ST segment and, in some cases, prolongation of QRS duration in patients with Brugada syndrome.     

跨壁复极离散在多形性折返性室性心动过速发生中的作用

目的探讨跨壁复极离散与室性心律失常发生的关系。方法以冠状动脉灌注兔左室楔形组织块为研究对象,对标本施加刺激基础周长分别为500,1000,2000ms的S1刺激,记录内、外膜侧心肌细胞动作电位和跨壁心电图,测量QT间期、时间易损窗及Tp-e/QT值。每10个S1刺激后施加期前S2刺激,S1S2耦联间期以1ms递增,以测量引起单向传导阻滞的时间易损窗。结果时间易损窗与QT间期呈正相关;Tp-e/QT比值在0.10～0.14之间无多形性室性心动过速(PVT)发生,当Tp-e/QT比值大于0.15,可引起PVT发生,而该比值在0.18～0.21时,无论S2刺激施加于内膜侧还是外膜侧,均可引起PVT。结论随着QT间期的延长时间易损窗增大;Tp-e/QT比值越大,室性心律失常越易发生。     

Proarrhythmic consequences of a KCNQ1 AKAP-binding domain mutation: computational models of whole cells and heterogeneous tissue

The KCNQ1-G589D gene mutation, associated with a long-QT syndrome, has been shown to disrupt yotiao-mediated targeting of protein kinase A and protein phosphatase-1 to the I(Ks) channel. To investigate how this defect may lead to ventricular arrhythmia during sympathetic stimulation, we use integrative computational models of beta-adrenergic signaling, myocyte excitation-contraction coupling, and action potential propagation in a rabbit ventricular wedge. Paradoxically, we find that the KCNQ1-G589D mutation alone does not prolong the QT interval. But when coupled with beta-adrenergic stimulation in a whole-cell model, the KCNQ1-G589D mutation induced QT prolongation and transient afterdepolarizations, known cellular mechanisms for arrhythmogenesis. These cellular mechanisms amplified tissue heterogeneities in a three-dimensional rabbit ventricular wedge model, elevating transmural dispersion of repolarization and creating other T-wave abnormalities on simulated electrocardiograms. Increasing heart rate protected both single myocyte and the coupled myocardium models from arrhythmic consequences. These findings suggest that the KCNQ1-G589D mutation disrupts a critical link between beta-adrenergic signaling and myocyte electrophysiology, creating both triggers of cardiac arrhythmia and a myocardial substrate vulnerable to such electrical disturbances.     

Electrical heterogeneity within the ventricular wall

Recent studies have established the presence of three distinct cell types in the ventricular myocardium: epicardial, M and endocardial cells. Epicardial and M cell action potentials differ from endocardial cells with respect to the morphology of phase 1. These cells possess a prominent transient outward current (I_to)-mediated notch responsible for the 'spike and dome' morphology of the epicardial and M cell response. M cells are distinguished from the other cell types in that they display a smaller slowly activating delayed rectifier current (I_Ks), but a larger late sodium current (late I_Na) and sodium-calcium exchange current (I_Na-Ca). These ionic distinctions underlie the longer action potential duration (APD) and steeper APD-rate relationship of the M cell, which is more pronounced in the presence of antiarrhythmic agents with class III actions. The preferential prolongation of the M cell action potential results in the development of a transmural dispersion of repolarization (TDR), which can be estimated from the electrocardiogram (ECG) as the interval between the peak and the end of the T wave (QT_peak-QT_end interval). Using the canine arterially perfused ventricular wedge model, transmembrane action potentials of the various cardiac cell types can be correlated to the waveforms of the ECG, providing insight into the cellular etiology of ECG abnormalities. Two congenital syndromes of sudden cardiac death that have been modeled using this technique are the long QT and Brugada syndromes. The long QT syndrome has been linked to 5 gene mutations on chromosomes 3, 7, 11, and 21. Mutations in the cardiac sodium channel SCN5A have been linked to families with a history of the Brugada syndrome. Although the etiologies of these two syndromes are different, lethal arrhythmias in both are thought to arise due to amplification of intrinsic electrical heterogeneities. Similar mechanisms are likely responsible for life-threatening arrhythmias in a variety of other cardiomyopathies ranging from heart failure and hypertrophy, which involve mechanisms similar to those operative in LQTS, to ischemia and infarction, which may involve mechanisms more closely resembling those responsible for the Brugada syndrome. Received: 17 April 2001, Returned for revision: 15 May 2001, Revision received: 13 June 2001, Accepted: 18 June 2001     

Epicardial but not endocardial premature stimulation initiates ventricular tachyarrhythmia in canine in vitro model of long QT syndrome

OBJECTIVES: To explore the mechanism, we tested the hypothesis that premature epicardial stimulation transiently increased the dispersion of repolarization leading to VT. BACKGROUND: Premature stimulation initiated ventricular tachycardia (VT) when applied to the epicardium but not to the endocardium in a canine model of long QT syndrome (LOTS). METHODS: We optically mapped action potentials (APs) on the cut-exposed transmural surfaces of isolated wedges of canine ventricular walls perfused with anemone toxin II (ATX-II), which produced type 3 LQTS with an asymmetrical transmural profile of repolarization that was earliest in the epicardium and latest in deep subendocardium. RESULTS: Earliest excitable epicardial stimulation triggered VT in 5 of 18 wedges receiving > or =5 nmol/L ATX-II by direct activation of epicardium, which delayed repolarization in the still refractory midmyocardium and further enhanced the dispersion of repolarization. These VTs were initiated 197 +/- 72 ms (n = 10) after the premature stimulation, from focal regions of earliest repolarization downstream to the steepest local spatial gradients of repolarization, and maintained by new focal activation and reentry. Transmural differences in the cycle lengths of activations altered conduction pathways and resulted in torsades de pointes-like polymorphic VT. In contrast, VTs were not initiated by endocardial stimulation at the same premature intervals or when ATX-II was < or =2.5 nmol/L. Failed VT initiation was associated with significantly lower maximum local gradient of repolarization. CONCLUSIONS: Heterogeneic repolarization in LQTS provides a transmural asymmetrical substrate for the earliest excitable epicardial, but not endocardial, stimulation to further delay midmyocardial repolarization and produce a steep spatial gradient of repolarization potential initiating torsades de pointes-like polymorphic VT.     

急性心肌缺血犬心肌细胞瞬时外向钾电流和跨壁复极离散度变化致心律失常机制研究

目的:探讨急性心肌缺血对犬左室心肌楔形组织块瞬时外向钾电流(Ito)、跨壁复极离散度(TDR)变化及其与室性心律失常的关系。方法:建立冠状小动脉灌注犬左室心肌楔形组织块模型,应用浮置玻璃微电极和心电图同步记录技术,观察急性无灌流心肌缺血对内、中、外3层心肌细胞Ito、动作电位时程(APD)、TDR和心律失常的影响。结果:急性心肌缺血早期犬左室内、中、外3层心肌细胞的Ito增大,APD缩短,均以外膜心肌细胞最明显,TDR增加,诱发早期后除极、R-on-T期前收缩和室性心动过速。结论:急性心肌缺血时Ito增大,TDR增加,产生2相位折返,是多型性室性心动过速发生的重要机制。     

Sodium pentobarbital reduces transmural dispersion of repolarization and prevents torsades de Pointes in models of acquired and congenital long QT syndrome

INTRODUCTION: Sodium pentobarbital is widely used for anesthesia in experimental studies as well as in clinics, and it is known to prevent the development of torsades de pointes (TdP) in in vivo models of the long QT syndrome (LQTS). METHODS AND RESULTS: This study examines the effects of pentobarbital on transmural dispersion of repolarization (TDR) and induction of TdP in arterially perfused canine left ventricular wedge preparations in which transmembrane action potentials were simultaneously recorded from epicardial, M, and endocardial regions using floating glass microelectrodes together with a transmural ECG. d-Sotalol and ATX-II were used to mimic the LQT2 and LQT3 forms of congenital LQTS. Both d-sotalol (100 micromol/L, n = 6) and ATX-II (20 nmol/L, n = 6) preferentially prolonged the action potential duration (APD90) of the M cell, thus increasing in the QT interval and TDR, and leading to the development of spontaneous and stimulation-induced TdP. In the absence and presence of d-sotalol, pentobarbital (10, 20, and 50 microg/mL) prolonged the APD90 of epicardial and endocardial cells, and, to a lesser extent, that of the M cell, thus prolonging the QT interval but reducing TDR. In the ATX-II model, the effects of pentobarbital on the QT interval and APD90 were biphasic: 10 microg/mL pentobarbital further prolonged APD90 of epicardial and endocardial cells more than that of the M cell; 20 to 50 microg/mL pentobarbital abbreviated the APD90 of epicardial and endocardial cells less than that of the M cell, thus abbreviating the QT interval and markedly reducing TDR. Twenty to 50 microg/mL pentobarbital totally suppressed spontaneous as well as stimulation-induced TdP in both models CONCLUSION: Our data indicate that pentobarbital reduces TDR in control and under conditions of congenital and acquired LQTS, and suggest that this mechanism may contribute to the ability of the anesthetic to prevent the development of spontaneous as well as stimulation-induced TdP under conditions mimicking LQT2, LQT3, and acquired (drug-induced) forms of the LQTS. The data also serve to illustrate that there are circumstances under which QT prolongation may not be arrhythmogenic.     

Mutation-specific effects of lidocaine in Brugada syndrome

Brugada syndrome (BrS) is a hereditary cardiac disease characterized by right bundle-branch block, an elevation of the ST-segment in leads V1 through V3 on the electrocardiogram, and ventricular fibrillation that can lead to sudden cardiac death. Mutations in the cardiac sodium channel gene SCN5A, which encodes the alpha-subunit of the human cardiac voltage-dependent Na+ channel (Na(v)1.5), are identified in 15-30% of patients with BrS. Most SCN5A mutations lead to a 'loss-of-function' phenotype, reducing the Na+ current during the early phases of the action potential. Anti-arrhythmic drugs that affect Na+ channels typically block these Na+ channels, thereby exaggerating the ECG abnormalities and arrhythmogenicity in the BrS. However, the N406S mutation in SCN5A causes distinct gating defects and enhanced intermediate inactivation of Na+ channels, which led to unexpected pharmacological effects of lidocaine in a patient carrying this mutation. In the presence of the N406S mutation, use-dependent block by lidocaine is reduced and recovery from intermediate inactivation is hastened by lidocaine. These findings suggest that lidocaine may improve the Brugada phenotype in patients with N406S by increasing the availability of Na+ channels.     

急性心肌缺血时瞬时外向钾电流和跨壁复极离散度的变化及其计算机仿真研究

目的探讨急性心肌缺血时犬左室心肌楔形组织块瞬时外向钾电流(Ito)、跨壁复极离散度(TDR)的变化及其计算机仿真研究。方法建立冠状小动脉灌注犬左室心肌楔形组织块模型,应用浮置玻璃微电极和心电图同步记录技术,观察急性无灌流心肌缺血对内中外三层心肌细胞Ito、动作电位时程(APD)、TDR和心律失常的影响,并结合急性心肌缺血Ito离子流和TDR的变化,应用修正Luo-Rody参数进行计算机仿真。结果急性心肌缺血早期犬左室内中外三层心肌细胞的Ito离子流增大,APD缩短,均以心外膜层细胞最明显,TDR增加,诱发R-on-T早搏和室性心动过速,并经计算机仿真可以证实与临床一致的心电图特点。结论急性心肌缺血时Ito离子流增大,TDR增加,产生2位相折返,是多型性室性心动过速发生的重要机制,计算机仿真可以显示这些特点。     

Phenotypic characterization of a large European family with Brugada syndrome displaying a sudden unexpected death syndrome mutation in SCN5A:

INTRODUCTION: Brugada syndrome is characterized by sudden death secondary to malignant arrhythmias and the presence of ST segment elevation in leads V(1) to V(3) of patients with structurally normal hearts. This ECG pattern often is concealed but can be unmasked using potent sodium channel blockers. Like congenital long QT syndrome type 3 (LQT3) and sudden unexpected death syndrome, Brugada syndrome has been linked to mutations in SCN5A. METHODS AND RESULTS: We screened a large European family with Brugada syndrome. Three members (two female) had suffered malignant ventricular arrhythmias. Ten members showed an ECG pattern characteristic of Brugada syndrome at baseline, and eight showed the pattern only after administration of ajmaline (total 12 female). Haplotype analysis revealed that all individuals with positive ECG at baseline shared the SCN5A locus. Sequencing of SCN5A identified a missense mutation, R367H, previously associated with sudden unexpected death syndrome. Two of the eight individuals who displayed a positive ECG after the administration of ajmaline, but not before, did not have the R367H mutation, and sequencing analysis failed to identify any other mutation in SCN5A. The R367H mutation failed to generate any current when heterologously expressed in HEK cells. CONCLUSION: Our results support the hypothesis that (1) sudden unexpected death syndrome and Brugada syndrome are the same disease; (2) male predominance of the phenotype observed in sudden unexpected death syndrome does not apply to this family, suggesting that factors other than the specific mutation determine the gender distinction; and (3) ajmaline may provide false-positive results. These findings have broad implications relative to the diagnosis and risk stratification of family members of patients with the Brugada syndrome.     

Combination of cardiac conduction disease and long QT syndrome caused by mutation T1620K in the cardiac sodium channel

AIMS: The aim of the present study was to elucidate the molecular mechanism underlying the concomitant occurrence of cardiac conduction disease and long QT syndrome (LQT3), two SCN5A channelopathies that are explained by loss-of-function and gain-of-function, respectively, in the cardiac Na+ channel. METHODS AND RESULTS: A Caucasian family with prolonged QT interval, intermittent bundle-branch block, sudden cardiac death, and syncope was investigated. Lidocaine (1 mg/kg i.v.) normalized the prolonged QT interval and rescued bundle-branch block. An SCN5A mutation analysis was performed that revealed a C-to-A mutation at position 4859 (exon 28), predicted to change a highly conserved threonine for a lysine at position 1620. Mutant channels were characterized both in Xenopus oocytes and HEK293 cells. The T1620K mutation remarkably altered the properties of Nav1.5 channels. In particular, the voltage-dependence of the current decay time constants was largely lost. As a consequence, mutant channels inactivated faster than wild-type channels at potentials negative to -30 mV, resulting in less Na+ inward current (loss-of-function), but significantly slower at potentials positive to -30 mV, resulting in an increased Na+ inward current (gain-of-function). Moreover, we found a hyperpolarized shift of steady-state activation and an accelerated recovery from inactivation (gain-of-function). At the same time, channel availability was significantly reduced at the resting membrane potential (loss-of-function). CONCLUSION: We conclude that lysine at position 1620 leads to both loss-of-function and gain-of-function properties in hNav1.5 channels, which may consequently cause in the same individuals impaired impulse propagation in the conduction system and prolonged QTc intervals, respectively.     

Role of sodium and calcium channel block in unmasking the Brugada syndrome

OBJECTIVE: We hypothesized that a combination of I(Na) and I(Ca) blockade may be more effective in causing loss of the epicardial action potential (AP) dome and precipitating the Brugada syndrome (BS). The present study was designed to test this hypothesis in an in vitro model of BS. BACKGROUND: The Brugada syndrome is characterized by an ST segment elevation in the right precordial ECG leads and a high risk of sudden death. The ECG sign of BS is often concealed, but can be unmasked with potent sodium channel blockers. Using canine right ventricular (RV) wedge preparations, we previously developed an experimental model of BS using flecainide to depress the AP dome in RV epicardium. METHODS: Intracellular APs and a transmural ECG were simultaneously recorded from canine RV wedge preparations. RESULTS: Terfenadine (5-10 microM)-induced block of I(Ca) and I(Na) caused heterogeneous loss of the epicardial AP dome, resulting in ST segment elevation, phase 2 reentry (12/16), and spontaneous polymorphic VT/VF (6/16). Flecainide (相似文献