Electrocardiographic changes after successful recanalization of a chronic total coronary occlusion. A systematic review and meta-analysis.

BACKGROUND: Observational studies suggest that in patients with a CTO successful recanalization is associated with better clinical outcome. This could be related to a reduction in the occurrence of arrhythmias, which may result from modifications of the hibernating myocardium in a CTO region. METHODS AND RESULTS: We aimed to evaluate the effect of CTO PCI on electrophysiological parameters, and conducted a systematic review and meta-analysis according to the PRISMA guidelines. MEDLINE and EMBASE were searched. Titles and abstracts identified by the search strategy were independently screened by two investigators. Data were extracted and used for meta-analyses where possible. In total, eight studies incorporating 467 patients were included in this review, evaluating the effect of successful CTO PCI on various ECG parameters. Three studies showed a significant decrease in mean QT dispersion of 17.46ms [95% CI 10.62-24.30] after successful CTO PCI. QTc dispersion also decreased significantly, with a mean decrease of 18.74ms [95% CI 11.53-25.94]. In one trial a significant decrease in Tp-e interval in leads V2 and V5, and a significant decrease in Tp-e/QT ratio in leads V2 and V5 post-CTO PCI were observed. CONCLUSIONS: This first systematic review and meta-analysis suggests that successful CTO PCI is associated with an immediate decrease in ECG parameters that reflect heterogeneity in depolarization and repolarization, which could lead to a reduction in the risk for ventricular arrhythmias and sudden cardiac death. We raise the hypothesis that hibernating myocardium in a CTO region may not be as deeply "in sleep" as one would assume.

Reduced Sodium Current in the Lateral Ventricular Wall Induces Inferolateral J-Waves.

BACKGROUND: J-waves in inferolateral leads are associated with a higher risk for idiopathic ventricular fibrillation. We aimed to test potential mechanisms (depolarization or repolarization dependent) responsible for inferolateral J-waves. We hypothesized that inferolateral J-waves can be caused by regional delayed activation of myocardium that is activated late during normal conditions. METHODS: Computer simulations were performed to evaluate how J-point elevation is influenced by reducing sodium current conductivity (GNa), increasing transient outward current conductivity (Gto), or cellular uncoupling in three predefined ventricular regions (lateral, anterior, or septal). Two pig hearts were Langendorff-perfused with selective perfusion with a sodium channel blocker of lateral or anterior/septal regions. Volume-conducted pseudo-electrocardiograms (ECG) were recorded to detect the presence of J-waves. Epicardial unipolar electrograms were simultaneously recorded to obtain activation times (AT). RESULTS: Simulation data showed that conduction slowing, caused by reduced sodium current, in lateral, but not in other regions induced inferolateral J-waves. An increase in transient outward potassium current or cellular uncoupling in the lateral zone elicited slight J-point elevations which did not meet J-wave criteria. Additional conduction slowing in the entire heart attenuated J-waves and J-point elevations on the ECG, because of masking by the QRS. Experimental data confirmed that conduction slowing attributed to sodium channel blockade in the left lateral but not in the anterior/septal ventricular region induced inferolateral J-waves. J-waves coincided with the delayed activation. CONCLUSION: Reduced sodium current in the left lateral ventricular myocardium can cause inferolateral J-waves on the ECG.

Documented atrial fibrillation recurrences after pulmonary vein isolation are associated with diminished quality of life.

AIMS: Pulmonary vein isolation (PVI) aims at eliminating symptomatic atrial fibrillation. In this regard, the most relevant indication for this procedure is the reduction of symptoms and improvement of quality of life (QoL) in patients who remain symptomatic despite antiarrhythmic drug treatment. We investigated the relation between documented atrial fibrillation recurrences and QoL in patients after PVI. METHODS: One hundred and six PVIs were performed in 99 patients. Follow-up was mainly performed at referring hospitals. Short Form 36 (SF-36) QoL questionnaires were completed before and 1 year after PVI. Electrocardiographic recordings from the first postprocedural year were retrospectively collected, 3 months blanking excluded. Atrial fibrillation recurrence was defined as any recurrence of atrial arrhythmia documented on ECG or 24-h-Holter. RESULTS: Before PVI, patients had lower QoL than the general Dutch population in 7/8 SF-36 questionnaire subscales (sumQoL 419.4 ±â€Š161 vs. 617.9, P < 0.001). Atrial fibrillation recurred in 52 (49%) patients. In these patients, four subscales increased following PVI (physical functioning P < 0.001, role physical P = 0.006, bodily pain P = 0.011 and social functioning P = 0.047). SumQoL remained lower than the general Dutch population (546.7 ±â€Š157, P = 0.003). In patients without documented recurrences, QoL improved to a level similar to that of the general Dutch population (602.9 ±â€Š148; P = 0.46). The number of electrocardiographic recordings was lower in the group without documented recurrences (2.5 ±â€Š1.8 vs. 3.8 ±â€Š1.7, P = 0.002). CONCLUSION: In patients without documentation of atrial fibrillation, QoL increased up to the level of the general population after PVI, but it remained lower in patients with recurrences. In the latter group more ECGs were done, suggesting that QoL relates particularly to symptomatic episodes. Improvement of QoL is therefore an important attribute of PVI.

ST-Segment Elevation and Fractionated Electrograms in Brugada Syndrome Patients Arise From the Same Structurally Abnormal Subepicardial RVOT Area but Have a Different Mechanism.

BACKGROUND: Brugada syndrome (BrS) is characterized by a typical ECG pattern. We aimed to determine the pathophysiologic basis of the ST-segment in the BrS-ECG with data from various epicardial and endocardial right ventricular activation mapping procedures in 6 BrS patients and in 5 non-BrS controls. METHODS AND RESULTS: In 7 patients (2 BrS and 5 controls) with atrial fibrillation, an epicardial 8×6 electrode grid (interelectrode distance 1 mm) was placed epicardially on the right ventricular outflow tract (RVOT) before video-assisted thoracoscopic surgical pulmonary vein isolation. In 2 other BrS patients, endocardial, epicardial RV (CARTO), and body surface mapping was performed. In 2 additional BrS patients, we performed decremental preexcitation of the RVOT before endocardial RV mapping. During video-assisted thoracoscopic surgical pulmonary vein isolation and CARTO mapping, BrS patients (n=4) showed greater activation delay and more fractionated electrograms in the RVOT region than controls. Ajmaline administration increased the region with fractionated electrograms, as well as ST-segment elevation. Preexcitation of the RVOT (n=2) resulted in ECGs that supported the current-to-load mismatch hypothesis for ST-segment elevation. Body surface mapping showed that the area with ST-segment elevation anatomically correlated with the area of fractionated electrograms and activation delay at the RVOT epicardium. CONCLUSIONS: ST-segment elevation and epicardial fractionation/conduction delay in BrS patients are most likely related to the same structural subepicardial abnormalities, but the mechanism is different. ST-segment elevation may be caused by current-to-load mismatch, whereas fractionated electrograms and conduction delay are expected to be caused by discontinuous conduction in the same area with abnormal myocardium.

Electrocardiographic T wave and its relation with ventricular repolarization along major anatomical axes.

BACKGROUND: The genesis of the electrocardiographic T wave is incompletely understood and subject to controversy. We have correlated the ventricular repolarization sequence with simultaneously recorded T waves. METHODS AND RESULTS: Nine pig hearts were Langendorff-perfused (atrial pacing, cycle length 650 ms). Local activation and repolarization times were derived from unipolar electrograms sampling the ventricular myocardium. Dispersion of repolarization time was determined along 4 anatomic axes: left ventricle (LV)-right ventricle (RV), LV:apico-basal, LV:anterior-posterior, and LV:transmural. The heart was immersed in a fluid-filled bucket containing 61 electrodes to determine Tp (Tpeak in lead of maximum integral), TpTe (Tp to Tend), and TpTe_total (first Tpeak in any lead to last Tend in any lead). Repolarization was nonlinearly distributed in time. RT25 (time at which 25% of sites were repolarized, 288±26 ms) concurred with Tp. TpTe was 38±8 ms, and TpTe_total was 75±9 ms. TpTe_total correlated with dispersion of repolarization time in the entire heart (73±18 ms), but not with dispersion of repolarization times along individual axes (LV-RV, 66±17 ms; LV:apico-basal, 51±18 ms; LV:anterior-posterior, 51±27 ms; mean LV:transmural, 14±7 ms; all n=9). CONCLUSIONS: We provide a correlation between local repolarization and T wave in a pseudo-ECG. Repolarization differences along all anatomic axes contribute to the T wave. TpTe_total represents total dispersion of repolarization. At Tp, ≈25% of ventricular sites have been repolarized.

Ventricular repolarization: an overview of (patho)physiology, sympathetic effects and genetic aspects.

Most textbook knowledge on ventricular repolarization is based on animal data rather than on data from the in vivo human heart. Yet, these data have been extrapolated to the human heart, often without an appropriate caveat. Here, we review multiple aspects of repolarization, from basic membrane currents to cellular aspects including extrinsic factors such as the effects of the sympathetic nervous system. We critically discuss some mechanistic aspects of the genesis of the T-wave of the ECG in the human heart. Obviously, the T-wave results from the summation of repolarization all over the heart. The T-wave in a local electrogram ideally reflects local repolarization. The repolarization moment is composed of the moment of local activation plus local action potential duration (APD) at 90% repolarization (APD90). The duration of the latter largely depends on the balance between L-type Ca2+ current and the delayed rectifier currents. Generally speaking, there is an inverse relationship between local activation time and local APD90, leading to less dispersion in repolarization moments than in activation moments or in APD90. In transmural direction, the time needed for activation from endocardium toward epicardium has been considered to be overcompensated by shorter APD90 at the epicardium, leading to the earliest repolarization at the subepicardium. In addition, mid-myocardial cells would display the latest repolarization moments. The sparse human data available, however, do not show any transmural dispersion in repolarization moment. Also, the effect of adrenergic stimulation on APD90 has been studied mainly in animals. Again, sparse human data suggest that the effect of adrenergic stimulation is different in the human heart compared to many other mammalian hearts. Finally, aspects of the long QT syndrome are discussed, because this intrinsic genetic disease results from repolarization disorders with extrinsic aspects.

Intercellular coupling through gap junctions masks M cells in the human heart.

OBJECTIVES: M cells have been described in many mammalian species. They are thought to be relevant for the genesis of long QT intervals, afterdepolarizations and for dispersion in action potential duration and in repolarization time. Their role in the human heart is subject to debate. METHODS: We simulated action potential propagation in a strand of transversally oriented myocytes running from endocardium towards epicardium through the left ventricular free wall. The characteristics of the myocytes were either based on the Priebe-Beuckelmann ventricular cell model or on the Luo-Rudy ventricular cell model. The former model is based on the latter and includes adaptations in order to mimic the human ventricular myocyte. The amount and location of M cells as well as the intercellular coupling through gap junctions were varied. Also, we assessed action potential duration in a Langendorff-perfused explanted human heart and in a wedge preparation obtained from such a heart. RESULTS: At low, but physiological intercellular coupling conductance, the inclusion of M cells leads to a much longer 'QT interval' in the simulations than in the in vivo or isolated human heart. Dispersion in repolarization time becomes unphysiologically large when M cells are included in the strand and is also substantially larger than in the in vivo or isolated human heart. At stronger intercellular coupling this effect disappears. CONCLUSIONS: The manifestation of M cells is absent in the human heart, probably by effective intercellular coupling, turning them functionally "invisible".

Gender differences in the long QT syndrome: effects of beta-adrenoceptor blockade.

BACKGROUND: Gender differences have been reported in patients with the congenital long QT syndrome (LQTS). We analyzed whether electrocardiographic differences existed in females, males, girls and boys in response to beta-adrenoceptor blockade. METHODS: 12-lead ECGs before and during beta-adrenoceptor blockade were collected in 87 genotyped LQTS patients (48 women, 14 men, 12 girls and 13 boys). Up to three QTc intervals were determined in each lead of the ECG. V4 was used for QT/QTc analysis. Difference between longest and shortest QT interval was taken as a measure for dispersion of QT intervals. RESULTS: (1) Adult males had the greatest shortening of the QTc interval upon treatment with beta-adrenoceptor blockade. During treatment, adult males with LQTS(1) (mutation in the KCNQ1 gene, affecting I(Ks) current) were found to have shorter QTc intervals than adult females; this difference did not exist in LQTS(2) patients (mutation in the HERG gene, affecting I(Kr) current). (2) Female LQTS(2) patients had a 50% larger dispersion than female LQTS(1) patients both before and during treatment. (3) Adult male LQTS(1) patients constitute the only patient group with a marked decrease in QTc intervals and dispersion associated with a 100% efficacy of treatment in response to beta-adrenoceptor blockade. CONCLUSIONS: These findings indicate that, in addition to underlying differences in repolarization between men and women, cardiac electrophysiological responses to beta-adrenoceptor blockade can be modulated by gender-related factors.