The most studied fat depot linked to arrhythmia is epicardial adipose tissue (EAT). Firstly, the presence of some adipose tissue in and around the heart is physiologic. Fat around the heart can be divided into pericardial adipose tissue and visceral EAT. Pericardial fat is defined by fat surrounding the parietal pericardium while visceral EAT is defined by fat between the myocardium and visceral pericardium (Tam et al., 2016). EAT covers 80% of the heart and is present mostly along the coronary arteries, in the atrioventricular/intraventricular grooves, over the right ventricle (three or four times more than the left ventricle) especially along the right border, anterior surface and at the apex. Physiologic functions include buffering the coronary arteries against torsion and facilitating coronary artery remodeling. EAT has higher fatty acid synthesis and breakdown compared to many other fat depots (Marchington and Pond, 1990), which may serve to protect the heart against high levels of circulating lipids and as reserve in case of increased physiologic demand (i.e., exercise or infection; Iacobellis and Barbaro, 2008).

Although EAT is a type of visceral adipose tissue (VAT), it has unique characteristics such as smaller adipocytes (Bambace et al., 2014), different fatty acid composition, higher protein content and lower rates of glucose utilization (Iacobellis et al., 2005a; Iacobellis and Barbaro, 2008). The brown fat protein, uncoupling protein-1 (UCP-1), has been found to be expressed at high levels in EAT, suggesting a possible role in heart thermogenesis (Sacks et al., 2009). However, as with other homeostatic processes in the human body, there is a fine balance between physiologic quantity of EAT vs. excess. For instance, EAT accumulation may be part of a compensatory mechanism developed in response to chronic insults of the myocardial tissue, to support its higher demand-metabolic condition with free fatty acids, but this response can lead to increased inflammation and fibrosis to create a substrate for arrhythmias (Suffee et al., 2017).

Clinical imaging studies have demonstrated a strong direct correlation between epicardial adipose tissue (EAT) and abdominal visceral adiposity. EAT thickness has been reported to be associated with severity of coronary artery disease (CAD) (Jeong et al., 2007), atrial fibrillation (AF) recurrences after catheter ablation (Tsao et al., 2011), and adverse cardiovascular (CV) outcomes associated with AF (Chu et al., 2016). EAT and pericardial fat quantified by magnetic resonance imaging (MRI) is associated with the development of ventricular tachycardia (VT), ventricular fibrillation (VF) and long-term overall mortality in patients with systolic heart failure (HF; Wu et al., 2015). In an Asian population, pericardial fat thickness was also associated with increased frequency of premature ventricular contractions (Tam et al., 2016).

Multiple possible mechanisms could explain these findings. In the presence of obesity or metabolic syndrome, adipose tissue develops different characteristics resulting in changes such as “whitening” of the adipose tissue embedded within or surrounding the myocardial tissue. The adipocytes become larger in size with increased expression of inflammatory markers and decreased adiponectin levels (Bambace et al., 2014; Song et al., 2015; Zghaib et al., 2016). This pro-inflammatory environment likely leads to recruitment of inflammatory cells to perpetuate inflammation, leading to fibrosis (Cherian et al., 2012). Moreover, EAT shares the same coronary blood supply as the adjacent ventricular myocardium and has direct contact with it given the lack of fascia between adipocyte and myocardial layers (Guglielmi and Sbraccia, 2017). Therefore, EAT can have paracrine effects and directly infiltrate myocardium affecting cardiac function. Gap junctions have also been demonstrated within epicardial fat, which may lead to abnormal electrical coupling between the myocardium and EAT (Linck et al., 1974). For example, peri-atrial EAT has been found to express genes implicated in oxidative phosphorylation, muscular contraction, and calcium signaling in AF patients, which could potentially increase the translocation of cytosolic calcium into the lumen of the sarcoplasmic reticulum promoting excitation-contraction coupling and thus lead to disruptive electrophysiologic signals (Gaborit et al., 2015). Specific mechanisms associating EAT with development of arrhythmias are discussed below.

There have been numerous links made between intramyocardial fat and arrhythmias. Fibrofatty replacement of myocytes is one of the hallmarks of arrhythmogenic right ventricular cardiomyopathy (ARVC) and is thought to constitute the nidus for re-entry ventricular arrhythmias (Bauce et al., 2005). The characteristic adiposis associated with ARVC seems to be part of a non-specific repair process similar to the one that takes place after ischemia (Samanta et al., 2016). It is thought that after myocardial infarction (MI), patients are at risk of developing ventricular arrhythmias due to scar tissue formation. Yet, not all patients develop VT after MI despite the presence of intramyocardial collagen (Pouliopoulos et al., 2013). This may be explained in part by the greater electrical resistance of adipose tissue compared to myocardium or collagen, which may promote reentry (Rudy et al., 1979; Fallert et al., 1993; Pouliopoulos et al., 2013). This is also supported by animal studies showing that intramyocardial adipose tissue can impede myocardial conduction and attenuate both electrogram amplitude and slope to a greater extent than collagen (Pouliopoulos et al., 2013). However, conflicting findings have been shown in an in-silico computational model, where adipose tissue was found to be less arrhythmogenic than fibrotic tissue in terms of percentage of non-conducting tissue needed to induce the arrhythmias (De Coster et al., 2018). Other mechanisms for arrhythmogenesis should also be considered, such as the presence of gap junctions in adipose tissue, that as mentioned before may lead to aberrant signal propagation (Linck et al., 1974).

Intramyocardial fat has also been associated with supraventricular arrhythmias (Haemers et al., 2017). These fibro-fatty infiltrations in human atrial biopsy samples have also been associated with increased inflammation given findings of small lymphoid aggregates composed mainly of CD8+ cytotoxic effector T cells (Haemers et al., 2017) which have been reported to have a pathogenic role in adipose tissue inflammation in the setting of obesity (Nishimura et al., 2009; Pouliopoulos et al., 2013; Haemers et al., 2017).

The relationship between EAT and the myocardium is likely to be bidirectional. In an animal model of AF using rapid atrial pacing, there was an increase in expression of genes that favor adipocyte differentiation and infiltration to the right atrium, leading to increases in adipose tissue mass (including EAT) and lipid accumulation (Chilukoti et al., 2015). A recent study also found that progenitor cells located in the epicardium can undergo epithelial-to-mesenchymal transition process and give origin to adult EAT adipocytes, and this process is driven by atrial natriuretic peptide (ANP) secreted by the atrial myocardium (Suffee et al., 2017). Recently, NLRP3 inflammasome activation in atrial cardiomyocytes was shown to promote AF, likely due to increased calcium release from the ER and increased production of pro-inflammatory cytokines (Yao et al., 2018). This is relevant given that in the setting of obesity the NLRP3 inflammasome is activated (Haneklaus and O'Neill, 2015). So it is possible that inflammasome activation can contribute to arrhythmia pathogenesis.

Remote fat cells have numerous endocrine effects. The interplay between the endocrine function of fat and the heart has not been fully elucidated. However, there are a couple of examples highlighting how increased fat burden can lead to arrhythmia. Obesity is characterized by a change in cardiac metabolism (Lopaschuk et al., 2007). Under normal conditions free fatty acids are the major source of energy for the heart given its high demand. In the setting of obesity, there is increased circulating free fatty acids, which may lead to fatty acid infiltration of myocardial tissue, increases in fatty acid oxidation, insulin resistance, and glucose intolerance, all of which decreases cardiac metabolic efficiency (Lopaschuk et al., 2007). Insulin resistance provokes systemic hyperglycemia which can result in myocardial injury (glucotoxicity; Ebong et al., 2014). Classically, obesity is also associated with low grade chronic inflammation. Visceral fat has higher levels of pro-inflammatory cytokines compared to EAT in CAD patients, leading some to think that part of the inflammatory effects may be systemic, arising from sources such as visceral fat and not just epicardial or local fat (Cheng et al., 2008).

Adipocytes secrete leptin, a peptide hormone which regulates sympathetic outflow. In a canine MI model of left anterior descending artery occlusion, leptin injection into the left stellate ganglion was associated with increased ventricular arrhythmia incidence and decreased action potential duration and duration dispersion compared to controls (Yu et al., 2018). Adipocyte fatty acid-binding protein (FABP4), which is predominantly expressed in adipose tissues, is known to depress shortening amplitude as well as intracellular systolic peak Ca²⁺ in a dose-dependent manner in isolated rat cardiomyocytes. Both the calcium dysregulation effect as well as the cardio-inhibitory effect leading to heart failure can lead to atrial/ventricular arrhythmias (Lamounier-Zepter et al., 2009). Also, increased leptin levels can lead to increased aldosterone secretion, systemic inflammation, endothelial dysfunction, increased vascular stiffness, hypertension, and cardiac hypertrophy, all of which could contribute to the pathogenesis of AF (Huby et al., 2015). Obesity-related adrenergic activation in particular may allow for more triggered arrhythmia. Overexpression of angiotensin I receptor and angiotensin converting enzyme related carboxypeptidase (ACE2) can lead to AV block and spontaneous ventricular tachycardia (Verheule et al., 2004).

In summary, remote adipose tissue can cause arrhythmia via a multitude of mechanisms from total body adipose tissue load related hemodynamic changes, neurohormonal mediated cardiac structural remodeling, adrenergic system activation and chronic low grade inflammation. Figure 2 reviews the different possible mechanisms implicated in arrhythmogenesis previously described.

Independent of obesity-induced cardiac structural changes mentioned earlier (i.e., biventricular enlargement/hypertrophy, diastolic/systolic dysfunction), increased dietary fat burden alone can lead to arrhythmia. For example, even a short period of HFD in gerbils can lead to radical inflammation and apoptosis causing cardiac remodeling (Sahraoui et al., 2016). Rats fed a high fat diet had an increased incidence of malignant ventricular tachyarrhythmias (Liptak et al., 2017) in the setting of induced ischemia. Furthermore, atria from rats fed high fat diet showed upregulation of transforming growth factor-β1 and matrix metalloproteinase-2 (atrial fibrosis pathway proteins), gap junction remodeling with alterations and distribution of connexin 40 (Cx40) and Cx43, broadened interstitial space, and myocyte disarray, and increased apoptotic cell death (Meng et al., 2017). In guinea pigs, HFD produces alteration of atrial cell electrophysiology favilitating the development of reentrant arrhythmias (Aromolaran et al., 2016).

In humans, hypercholesterolemia has been associated with QT prolongation, offering yet another mechanism for potential arrhythmia (el-Gamal et al., 1995). When studying the effect of palmitic, stearic, and oleic free fatty acids on sheep atrial myocytes, it was found that stearic acid disrupts t-tubular and induces inhibition of I_Ca−L and I_TO ionic currents in sheep atrial myocytes. This could result in abbreviation (I_Ca−L) or a prolongation (I_TO) of atrial myocyte action potential duration and thus play role in arrhythmogenesis (O'Connell et al., 2015). This also highlights that not all dietary lipid is the same. In pig ventricular myocytes, for example, dietary fish oil prevents calcium overload and reduces incidence of norepinephrine induced triggered activity (Berecki et al., 2007). Clinical trials in humans looking at the utility of fish oil in the prevention of arrhythmia in various cohorts, however have been contradictory. In the Alpha-Omega trial, low-dose EPA-DHA, or ALA did not reduce the rate of major cardiovascular events, but secondary analysis of the data showed a reduction in arrhythmias in the fish oil groups (Kromhout et al., 2010). In the SOFA trial, omega-3 poly unsaturated fatty acids from fish oil did not significantly protect against ventricular arrhythmia in patients with implantable cardioverter defibrillators (Brouwer et al., 2006).

High fat diet (HFD) has also been studied in AF. In a study using a sheep model of HFD-induced obesity, there was infiltration of the posterior left atrium by EAT associated with reduced endocardial voltage in this region compared to lean sheep (Mahajan et al., 2015). HFD was associated with biatrial endocardial remodeling, conduction abnormalities, increased expression of TGF- β₁ in the left atrium and interstitial atrial fibrosis leading to increase frequency and duration of AF (Mahajan et al., 2015). In mice, HFD-induced obesity has been shown to be related to increased LA fibrosis and higher vulnerability of developing AF (AF was able to be induced in 50% of animals that were treated with HFD vs. 0% in the control group; Kondo et al., 2018). Further, studies are needed to observe the impact of diet modifications and weight loss in animals in reversing alterations in electrophysiology.

Small animal models (such as mice or rats) are valuable for the study of cardiac physiology given the lower maintenance cost, easier handling, cost effectiveness and possibility for genetic manipulation (Milani-Nejad and Janssen, 2014). Techniques for assessing cardiac function and electrophysiology measures are well-established for rodents. Despite being the most common in vivo model used, differences between murine models and human patients can make the generalizability of the data obtained from murine experiments on action potentials, cardiac contraction, cardiomyocytes characteristics and protein expression difficult (Nerbonne, 2004; Milani-Nejad and Janssen, 2014). Specifically, for the study of arrhythmias, baseline heart rates for rodents are greater than humans, which leads to a rapid repolarization and lack of plateau phase in the action potentials of ventricular myocytes observed in large animals (Nerbonne, 2004). Guinea-pigs have a more similar action potential wave given similarities in ionic currents contributing to repolarization (Bosch et al., 1998). Rabbits have also been used for the study of cardiac diseases given that rabbit myocardium shares more similarities with the human myocardium than small rodents (Milani-Nejad and Janssen, 2014); but the action potential is still faster than humans (Szél et al., 2011). Larger animal models share more similarities with human physiology, but their maintenance and costs can be challenging. Moreover, the contractile and relaxation kinetics in larger animal models remain slightly faster than humans (Milani-Nejad and Janssen, 2014), and the ion channel distribution in the different species is unknown (Schram et al., 2002; Milani-Nejad and Janssen, 2014).

Specific rat models which available for study would include those with mutations in the calcium channel SCN5A in mice which is associated with Brugada syndrome (Milan and MacRae, 2005) and mice with human Na_V1.5 variant with a mutation in the anesthetic-binding site that produces an incomplete Na⁺ channel inactivation (F1759A-Na_V1.5), who develop spontaneous AF induction (Wan et al., 2016). How these arrhythmia prone models respond to obesity may offer further insight into the link between arrhythmia and obesity.

Possible human clinical areas of research would be rigorous quantification of different types of adipose tissue. This would allow risk stratification for hard clinical outcomes such as predicting new AF development as well as recurrence after ablation, prediction of ventricular arrhythmias after MI, risk stratification for need for implantable cardioverter defibrillator in various disease where risk is not clear (e.g., asymptomatic, gene positive, phenotype negative hypertrophic cardiomyopathy patients).

Recently human induced pluripotent stem cell derived cardiomyocytes from disease patients have been shown to be a promising method to study cardiac arrhythmias, especially in arrhythmias related to genetic mutations (Garg et al., 2018). Pluripotent stem cell derived cardiomyocytes can be used to study channelopathies by modeling genetic syndromes in an in vitro dish (Garg et al., 2018). Even though the relevance of pluripotent stem cells in arrhythmias with multifactorial etiologies (including metabolic syndrome) is limited, endothelial cells derived from HFD mice exhibit signs of endothelial dysfunction compared to regular diet mice (Gu et al., 2015). Further studies are needed to delucidate if pluripotent stem cell derived cardiomyocytes from obese animals or patients can be used to model arrhythmias.

The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.