Arias-Mutis Óscar J, Calvo Conrado J, Bizy Alexandra, Ortiz-Guzmán Johan E, Such-Miquel Luis, Such Luis, Alberola Antonio, Zhao Jichao, Chorro Francisco J, Zarzoso Manuel
CIBERCV, Instituto de Salud Carlos III, Madrid, Spain.
Department of Physiology, University of Valencia, Valencia, Spain.
J Physiol. 2025 May;603(10):2979-3000. doi: 10.1113/JP286516. Epub 2025 May 5.
Metabolic syndrome (MetS) has been associated with an increased prevalence of cardiac arrhythmias and sudden cardiac death caused by ventricular fibrillation (VF), but the exact underlying mechanisms are not known. Our aim here was to study the effects that diet-induced MetS produces on ventricular remodelling and its potential electrophysiological arrhythmogenic mechanisms. Thirty-five male NZW rabbits were assigned to a control (n = 16) or MetS group (n = 19), fed for 28 weeks with a high-fat and high-sucrose diet. Echocardiography and electrocardiography were performed before diet and at weeks 14 and 28. Hearts were isolated and perfused in a Langendorff system and epicardial optical mapping was performed using two EMCCD cameras focused on the left (LV) and right (RV) ventricles. mRNA expression levels for ion channel proteins were examined by quantitative RT-PCR. A mixed-model ANOVA and unpaired t test were used for statistical analysis. MetS animals showed LV hypertrophy and electrophysiological abnormalities (increased PQ, QRS, QTc and T wave). In isolated hearts, MetS animals had shorter optical APD90 (action potential duration at 90% repolarization), increased restitution slope and alternans, and faster frequency of activation during VF in the RV, whereas no difference was observed in the LV. The mRNA expression for KvLQT1 and KChIP2 increased in the RV. MetS produced LV hypertrophy, and altered atrioventricular and ventricular conduction and repolarization abnormalities. In isolated hearts, the physiological gradients of refractoriness and frequency of activation during VF were abolished in MetS animals, with fast activation rates in both ventricles, which could be explained, at least in part, by upregulation of KvLQT1 and KChIP2 in the RV. KEY POINTS: Metabolic syndrome (MetS) has been associated with ventricular arrhythmias and sudden cardiac death, but the exact underlying mechanisms are not known. Previous studies have addressed the effects that individual components of MetS exert, individually, upon electrical cardiac remodelling, but the results obtained in some cases prove inconclusive or contradictory. We investigated the effects of diet-induced MetS on ventricular remodelling and its potential electrophysiological arrhythmogenic mechanisms. We found that diet-induced MetS produced altered activation-repolarization abnormalities as well as fast-activation non-stable flattening of the spatial distribution of dominant frequencies driving ventricular fibrillation, which might be explained, at least in part, due to increased expression of potassium channels in the right ventricle.
代谢综合征(MetS)与心律失常患病率增加以及室颤(VF)导致的心脏性猝死有关,但确切的潜在机制尚不清楚。我们的目的是研究饮食诱导的MetS对心室重构及其潜在的电生理致心律失常机制的影响。将35只雄性新西兰白兔分为对照组(n = 16)或MetS组(n = 19),用高脂高糖饮食喂养28周。在饮食前以及第14周和第28周进行超声心动图和心电图检查。分离心脏并在Langendorff系统中灌注,使用两台聚焦于左心室(LV)和右心室(RV)的EMCCD相机进行心外膜光学标测。通过定量RT-PCR检测离子通道蛋白的mRNA表达水平。采用混合模型方差分析和非配对t检验进行统计分析。MetS动物表现出左心室肥厚和电生理异常(PQ、QRS、QTc和T波增加)。在离体心脏中,MetS动物的光学APD90(90%复极化时的动作电位持续时间)较短,恢复斜率和交替变化增加,右心室室颤期间的激活频率更快,而左心室未观察到差异。右心室中KvLQT1和KChIP2的mRNA表达增加。MetS导致左心室肥厚,并改变房室和心室传导以及复极化异常。在离体心脏中,MetS动物消除了室颤期间不应期和激活频率的生理梯度,两个心室的激活速率都很快,这至少部分可以通过右心室中KvLQT1和KChIP2的上调来解释。要点:代谢综合征(MetS)与室性心律失常和心脏性猝死有关,但确切的潜在机制尚不清楚。先前的研究探讨了MetS的各个组成部分对心脏电重构的单独影响,但在某些情况下获得的结果尚无定论或相互矛盾。我们研究了饮食诱导的MetS对心室重构及其潜在的电生理致心律失常机制的影响。我们发现,饮食诱导的MetS产生了激活-复极化异常以及驱动室颤的主导频率空间分布的快速激活不稳定扁平化,这至少部分可以归因于右心室钾通道表达的增加。
