Virtual Electrophysiological Study of Atrial Fibrillation in Fibrotic Remodeling

Research has indicated that atrial fibrillation (AF) ablation failure is related to the presence of atrial fibrosis. However it remains unclear whether this information can be successfully used in predicting the optimal ablation targets for AF termination. We aimed to provide a proof-of-concept that patient-specific virtual electrophysiological study that combines i) atrial structure and fibrosis distribution from clinical MRI and ii) modeling of atrial electrophysiology, could be used to predict: (1) how fibrosis distribution determines the locations from which paced beats degrade into AF; (2) the dynamic behavior of persistent AF rotors; and (3) the optimal ablation targets in each patient. Four MRI-based patient-specific models of fibrotic left atria were generated, ranging in fibrosis amount. Virtual electrophysiological studies were performed in these models, and where AF was inducible, the dynamics of AF were used to determine the ablation locations that render AF non-inducible. In 2 of the 4 models patient-specific models AF was induced; in these models the distance between a given pacing location and the closest fibrotic region determined whether AF was inducible from that particular location, with only the mid-range distances resulting in arrhythmia. Phase singularities of persistent rotors were found to move within restricted regions of tissue, which were independent of the pacing location from which AF was induced. Electrophysiological sensitivity analysis demonstrated that these regions changed little with variations in electrophysiological parameters. Patient-specific distribution of fibrosis was thus found to be a critical component of AF initiation and maintenance. When the restricted regions encompassing the meander of the persistent phase singularities were modeled as ablation lesions, AF could no longer be induced. The study demonstrates that a patient-specific modeling approach to identify non-invasively AF ablation targets prior to the clinical procedure is feasible.     

The Mineralocorticoid Receptor Promotes Fibrotic Remodeling in Atrial Fibrillation

We studied the role of the mineralocorticoid receptor (MR) in the signaling that promotes atrial fibrosis. Left atrial myocardium of patients with atrial fibrillation (AF) exhibited 4-fold increased hydroxyproline content compared with patients in sinus rhythm. Expression of MR was similar, as was 11β-hydroxysteroid dehydrogenase type 2 (11β-HSD2), which also increased. 11β-HSD2 converts cortisol to receptor-inactive metabolites allowing aldosterone occupancy of MR. 11β-HSD2 was up-regulated by arrhythmic pacing in cultured cardiomyocytes and in a mouse model of spontaneous AF (RacET). In cardiomyocytes, aldosterone induced connective tissue growth factor (CTGF) in the absence but not in the presence of cortisol. Hydroxyproline expression was increased in cardiac fibroblasts exposed to conditioned medium from aldosterone-treated cardiomyocytes but not from cardiomyocytes treated with both cortisol and aldosterone. Aldosterone increased connective tissue growth factor and hydroxyproline expression in cardiac fibroblasts, which were prevented by BR-4628, a dihydropyridine-derived selective MR antagonist, and by spironolactone. Aldosterone activated RhoA GTPase. Rho kinase inhibition by Y-27632 prevented CTGF and hydroxyproline, whereas the RhoA activator CN03 increased CTGF expression. Aldosterone and CTGF increased lysyl oxidase, and aldosterone enhanced miR-21 expression. MR antagonists reduced the aldosterone but not the CTGF effect. In conclusion, MR signaling promoted fibrotic remodeling. Increased expression of 11β-HSD2 during AF leads to up-regulation of collagen and pro-fibrotic mediators by aldosterone, specifically RhoA activity as well as CTGF, lysyl oxidase, and microRNA-21 expression. The MR antagonists BR-4628 and spironolactone prevent these alterations. MR inhibition may, therefore, represent a potential pharmacologic target for the prevention of fibrotic remodeling of the atrial myocardium.     

虚拟生理心脏模型及房颤机制研究进展

房颤是临床上最常见的持续性心律失常.揭示房颤的发病机制和病理生理过程是其诊断、预防、治疗、药物研发及临床设备设计的关键,而实验和临床只能呈现细胞或亚细胞的局部特性及房颤病症的宏观结果.随着生物信息技术、统计分析技术等的发展,运用多物理尺度的虚拟生理心脏模型,来实现宏观结果与微观机制相统一的研究方法备受关注.本文综述了离子通道、心肌细胞、心脏组织及器官等多尺度的虚拟生理心脏模型研究进展,探讨了近年来基于虚拟生理心脏模型的房颤机制研究以及房颤的治疗手段,提示了房颤研究的挑战和未来的发展方向.     

Mechanistic Inquiry into the Role of Tissue Remodeling in Fibrotic Lesions in Human Atrial Fibrillation

Atrial fibrillation (AF), the most common arrhythmia in humans, is initiated when triggered activity from the pulmonary veins propagates into atrial tissue and degrades into reentrant activity. Although experimental and clinical findings show a correlation between atrial fibrosis and AF, the causal relationship between the two remains elusive. This study used an array of 3D computational models with different representations of fibrosis based on a patient-specific atrial geometry with accurate fibrotic distribution to determine the mechanisms by which fibrosis underlies the degradation of a pulmonary vein ectopic beat into AF. Fibrotic lesions in models were represented with combinations of: gap junction remodeling; collagen deposition; and myofibroblast proliferation with electrotonic or paracrine effects on neighboring myocytes. The study found that the occurrence of gap junction remodeling and the subsequent conduction slowing in the fibrotic lesions was a necessary but not sufficient condition for AF development, whereas myofibroblast proliferation and the subsequent electrophysiological effect on neighboring myocytes within the fibrotic lesions was the sufficient condition necessary for reentry formation. Collagen did not alter the arrhythmogenic outcome resulting from the other fibrosis components. Reentrant circuits formed throughout the noncontiguous fibrotic lesions, without anchoring to a specific fibrotic lesion.     

Mechanistic Inquiry into the Role of Tissue Remodeling in Fibrotic Lesions in Human Atrial Fibrillation

Atrial fibrillation (AF), the most common arrhythmia in humans, is initiated when triggered activity from the pulmonary veins propagates into atrial tissue and degrades into reentrant activity. Although experimental and clinical findings show a correlation between atrial fibrosis and AF, the causal relationship between the two remains elusive. This study used an array of 3D computational models with different representations of fibrosis based on a patient-specific atrial geometry with accurate fibrotic distribution to determine the mechanisms by which fibrosis underlies the degradation of a pulmonary vein ectopic beat into AF. Fibrotic lesions in models were represented with combinations of: gap junction remodeling; collagen deposition; and myofibroblast proliferation with electrotonic or paracrine effects on neighboring myocytes. The study found that the occurrence of gap junction remodeling and the subsequent conduction slowing in the fibrotic lesions was a necessary but not sufficient condition for AF development, whereas myofibroblast proliferation and the subsequent electrophysiological effect on neighboring myocytes within the fibrotic lesions was the sufficient condition necessary for reentry formation. Collagen did not alter the arrhythmogenic outcome resulting from the other fibrosis components. Reentrant circuits formed throughout the noncontiguous fibrotic lesions, without anchoring to a specific fibrotic lesion.     

人类心房纤维性颤动变化的分子机制

近年来确认了心房纤维性颤动(AF)以促进心房的发生和维持的方式修饰了心房的电特征.并确立了节律紊乱发生的电生理变化.主要描述了功能的快变化和蛋白质表达的慢变化的分子机制,这种慢变化会引起心房纤维性颤动的电改变和收缩异常.心房纤维性颤动的一个重要分子特征是L型钙离子通道功能和蛋白质表达的减少.这种减少可能有助于保护细胞抵制由于心房纤维性颤动的激活率增加产生的潜在致死钙离子超载.对蛋白水解系统的可能作用也进行了讨论,其中重点讨论了钙蛋白酶作为一种与钙离子超载导致蛋白表达减少相联系的机制.     

心房重构与心房纤颤的病理学机制研究进展

目前,发生率最高的心率失常被认为是心房纤颤,且该病的发生率随着年龄的增长而上升。伴随着我国人口年龄结构的变化,心房纤颤在我国的发病率逐渐增加。了解该病的发生和发展的机制十分迫切。已经证明,心房重构是该病的重要发生机制。随着研究的加深,研究人员对心房重构与该病的病理学机制有了更加深刻的了解。现就心房纤颤和重构在发病中的机制进行回顾。     

Fibroblast Electrical Remodeling in Heart Failure and Potential Effects on Atrial Fibrillation

Fibroblasts are activated in heart failure (HF) and produce fibrosis, which plays a role in maintaining atrial fibrillation (AF). The effect of HF on fibroblast ion currents and its potential role in AF are unknown. Here, we used a patch-clamp technique to investigate the effects of HF on atrial fibroblast ion currents, and mathematical computation to assess the potential impact of this remodeling on atrial electrophysiology and arrhythmogenesis. Atrial fibroblasts were isolated from control and tachypacing-induced HF dogs. Tetraethylammonium-sensitive voltage-gated fibroblast current (I_Kv,fb) was significantly downregulated (by ∼44%), whereas the Ba²⁺-sensitive inward rectifier current (I_Kir,fb) was upregulated by 79%, in HF animals versus controls. The fibroblast resting membrane potential was hyperpolarized (−53 ± 2 mV vs. −42 ± 2 mV in controls) and the capacitance was increased (29.7 ± 2.2 pF vs. 17.8 ± 1.4 pF in controls) in HF. These experimental findings were implemented in a mathematical model that included cardiomyocyte-fibroblast electrical coupling. I_Kir,fb upregulation had a profibrillatory effect through shortening of the action potential duration and hyperpolarization of the cardiomyocyte resting membrane potential. I_Kv,fb downregulation had the opposite electrophysiological effects and was antifibrillatory. Simulated pharmacological blockade of I_Kv,fb successfully terminated reentry under otherwise profibrillatory conditions. We conclude that HF induces fibroblast ion-current remodeling with I_Kv,fb downregulation and I_Kir,fb upregulation, and that, assuming cardiomyocyte-fibroblast electrical coupling, this remodeling has a potentially important effect on atrial electrophysiology and arrhythmogenesis, with the overall response depending on the balance of pro- and antifibrillatory contributions. These findings suggest that fibroblast K⁺-current remodeling is a novel component of AF-related remodeling that might contribute to arrhythmia dynamics.     

房颤不同时期结构重构的血清学变化

目的:探讨转化生长因子-β1(TGF-β1)、基质金属蛋白酶-9(MMP-9)、金属蛋白酶组织抑制因子-1(TIMP-1)、肿瘤坏死因子-α(TNF-α)、白介素-6(IL-6)、白介素-10(IL-10)与阵发性或持续性房颤结构重构的关系。方法:入选患者分为3组,其中持续性房颤组30例、阵发性房颤组45例,以及32例阵发性室上速(包括预激综合征)作为对照组,通过ELISA方法检测上述患者左房血清的TGF-β1、MMP-9、TIMP-1、TNF-α、IL-6、IL-10水平,超声测量左心房长径。分析上述细胞因子水平与阵发性房颤或持续性房颤的关系。结果:阵发性房颤组与对照组相比,左房内径增大、TGF-β1、TNF-α升高(P0.05),IL-10、TIMP-1降低(P0.05),MMP-9无统计学差异。持续性房颤组与对照组相比,TGF-β1无统计学差异(P0.05),MMP-9、TNF-α、IL-6均升高(P0.05),IL-10、TIMP-1降低(P0.05);阵发性房颤组TGF-β1高于持续性房颤组(P0.05),持续性房颤组左房内径及MMP-9高于阵发性房颤组(P0.05)。结论:阵发性房颤患者左房扩大,已出现结构重构,结构重构的血清学变化以TGF-β1升高为主;持续性房颤患者结构重构血清学变化以MMP-9、IL-6升高为主。     

Atrial Fibrillation Complicated by Heart Failure Induces Distinct Remodeling of Calcium Cycling Proteins

Atrial fibrillation (AF) and heart failure (HF) are two of the most common cardiovascular diseases. They often coexist and account for significant morbidity and mortality. Alterations in cellular Ca²⁺ homeostasis play a critical role in AF initiation and maintenance. This study was designed to specifically elucidate AF-associated remodeling of atrial Ca²⁺ cycling in the presence of mild HF. AF was induced in domestic pigs by atrial burst pacing. The animals underwent electrophysiologic and echocardiographic examinations. Ca²⁺ handling proteins were analyzed in right atrial tissue obtained from pigs with AF (day 7; n = 5) and compared to sinus rhythm (SR) controls (n = 5). During AF, animals exhibited reduction of left ventricular ejection fraction (from 73% to 58%) and prolonged atrial refractory periods. AF and HF were associated with suppression of protein kinase A (PKA)_RII (-62%) and Ca²⁺-calmodulin-dependent kinase II (CaMKII) δ by 37%, without changes in CaMKIIδ autophosphorylation. We further detected downregulation of L-type calcium channel (LTCC) subunit α₂ (-75%), sarcoplasmic reticulum Ca²⁺-ATPase (Serca) 2a (-29%), phosphorylated phospholamban (Ser16, -92%; Thr17, -70%), and phospho-ryanodine receptor 2 (RyR2) (Ser2808, -62%). Na⁺-Ca²⁺ exchanger (NCX) levels were upregulated (+473%), whereas expression of Ser2814-phosphorylated RyR2 and LTCCα_1c subunits was not significantly altered. In conclusion, AF produced distinct arrhythmogenic remodeling of Ca²⁺ handling in the presence of tachycardia-induced mild HF that is different from AF without structural alterations. The changes may provide a starting point for personalized approaches to AF treatment.     

Electrophysiological Changes Preceding the Onset of Atrial Fibrillation after Coronary Bypass Grafting Surgery

Background

The incidence of Post-CABG atrial fibrillation (AF) lies between 25% and 40%. It worsens morbidity and raises post-operative costs. Detection of incoming AF soon enough for prophylactic intervention would be helpful. The study is to investigate the electrophysiological changes preceding the onset of AF and their relationship to the preoperative risk.

Methods and Results

Patients were recorded continuously for the first four days after coronary artery bypass grafting surgery (CABG) with three unipolar electrodes sutured to the atria (AEG). The patients experiencing an AF lasting more than 10 minutes were selected and the two hours before the onset were analyzed. Four variables were found to show significant changes in the two hours prior to the first prolonged AF: increasing rate of premature atrial activation, increasing incidence of short transient arrhythmias, acceleration of heart rate, and rise of low frequency content of heart rate. The main contrast was between the first and last hour before AF onset. Preoperative risk was not predictive of the onset time of AF and did not correlate with the amplitude of changes prior to AF.

Conclusions

Post-CABG AF were preceded by electrophysiological changes occurring in the last hour before the onset of the arrhythmia, whereas none of these changes was found to occur in all AF patients. The risk was a weighted sum of factors related to the density of premature activations and the state of atrial substrate reflected by the sinus rhythm and its frequency content prior to AF. Preoperative risk score seems unhelpful in setting a detection threshold for the AF onset.     

房颤大鼠模型心室重构与心肌细胞钙稳态和心律失常的关联

摘要 目的：探讨房颤大鼠模型心室重构与心肌细胞钙稳态和心律失常的关联性。方法：将雄性Wistar大鼠随机平分为两组,各组8只,模型组采用乙酞胆碱-氯化钙混合液尾静脉注射法建立房颤动物模型,对照组注射同剂量的生理盐水,记录两组心室重构、心肌细胞钙稳态、心律失常情况并进行相关性分析。结果：模型组建模第2周与第4周的左室舒张末期内径（LVEDD）、左室收缩末期内径（LVESD）值都高于对照组（P<0.05）。模型组建模第2周与第4周的血清肌钙蛋白（cTnT）含量高于对照组（P<0.05）。模型组建模第2周与第4周心脏体外牵张性心律失常持续时间都高于对照组（P<0.05）。Pearson相关分析显示建模第2周与第4周的LVEDD、LVESD、cTnT与牵张性心律失常持续时间存在正相关（P<0.05）。结论：房颤大鼠伴随有心室重构与心肌细胞钙离子的大量释放,可增加牵张性心律失常持续时间,相关性分析结果表明：心室重构、心肌细胞钙稳态和心律失常存在显著正相关性。     

In Silico Screening of the Key Cellular Remodeling Targets in Chronic Atrial Fibrillation

Chronic atrial fibrillation (AF) is a complex disease with underlying changes in electrophysiology, calcium signaling and the structure of atrial myocytes. How these individual remodeling targets and their emergent interactions contribute to cell physiology in chronic AF is not well understood. To approach this problem, we performed in silico experiments in a computational model of the human atrial myocyte. The remodeled function of cellular components was based on a broad literature review of in vitro findings in chronic AF, and these were integrated into the model to define a cohort of virtual cells. Simulation results indicate that while the altered function of calcium and potassium ion channels alone causes a pronounced decrease in action potential duration, remodeling of intracellular calcium handling also has a substantial impact on the chronic AF phenotype. We additionally found that the reduction in amplitude of the calcium transient in chronic AF as compared to normal sinus rhythm is primarily due to the remodeling of calcium channel function, calcium handling and cellular geometry. Finally, we found that decreased electrical resistance of the membrane together with remodeled calcium handling synergistically decreased cellular excitability and the subsequent inducibility of repolarization abnormalities in the human atrial myocyte in chronic AF. We conclude that the presented results highlight the complexity of both intrinsic cellular interactions and emergent properties of human atrial myocytes in chronic AF. Therefore, reversing remodeling for a single remodeled component does little to restore the normal sinus rhythm phenotype. These findings may have important implications for developing novel therapeutic approaches for chronic AF.