Inflammation and arrhythmogenesis: mechanistic insights
There are several causes of systemic inflammation, including sepsis, trauma, surgery, and long-term illnesses. There are many ways in which systemic inflammation might raise the risk of arrhythmias.
First, oxidative stress and cardiac cell damage from systemic inflammation might result in decreased electrical conduction and heightened vulnerability to reentry circuits [
10]. Oxidative stress is the result of an imbalance between the body's generation of reactive oxygen species (ROS) and antioxidants' capacity to neutralize the detrimental effects of ROS [
10,
18]. This oxidative stress can lead to inflammation and damage to the heart's tissue, which can accelerate the development of heart failure [
10,
18].
Second, the autonomic nervous system (ANS) might have its equilibrium upset by systemic inflammation [
19,
20]. Arrhythmias may be brought on or made worse by this imbalance [
19,
20]. Through its sympathetic and parasympathetic branches, the ANS controls both innate and adaptive immunity. An imbalance in this system can lead to an altered inflammatory response, which is commonly seen in long-term illnesses such systemic autoimmune disorders [
20].
Third, since potassium, calcium, and magnesium are necessary for a proper ventricular action potential, systemic inflammation may have an impact on these electrolyte levels [
13]. The most prevalent intracellular cation in the body, potassium keeps muscle and nerve cells excitable [
21]. Variations in potassium concentrations can impact an action potential's ability to conduct, which, in severe cases, can result in ventricular tachycardia [
21].
Fourth, systemic inflammation has the potential to trigger the coagulation system and raise the risk of thromboembolism, both of which can result in myocardial infarction and ischemia [
13]. Increased thrombin production, improved platelet activation, downregulation of anticoagulant regulatory proteins, and elevation of procoagulant factors such as tissue factor and cellular adhesion molecules can all result from inflammation [
22]. This may lead to the creation of a blood clot, which may cause ischemia, or the limitation of oxygen and blood flow, if it breaks off and plugs an artery [
22].
Systemic inflammatory markers were found to have high correlations with the development of atrial fibrillation/flutter (AF), ventricular arrhythmia (VA), and bradyarrhythmia in a research including 478,524 participants from the UK Biobank cohort [
10] (Table
1). C-reactive protein (CRP) levels were found to have an almost linear positive connection with the incidence of different arrhythmias after correcting for all possible confounding factors [
10]. The greatest correlation was seen with VA, and then AF and bradyarrhythmia in that order [
10].
Table 1
Indicators of systemic inflammation and incident arrhythmia risk—observational study summary
Gender | 46.75% male |
Mean age | 40–69 years |
Study design | Observational study |
Study period | 2006–2010 |
Study population | 478,524 participants from the UK Biobank cohort |
Statistical percentage of developing arrhythmias | About 1 in 50 Americans under 65 and 1 in 10 Americans over 65 suffer from atrial fibrillation. Ventricular arrhythmias vary greatly in frequency. Ventricular arrhythmias affected 48 out of 100,000 individuals in one research, or around 1 in 2,100 persons. Ventricular arrhythmias affect 2–3 out of 100 older persons without known risk factors and 15–16 out of 100 adults with coronary artery disease |
Hazard ratio | The likelihood of an incident in a treatment group compared to the probability in the control group over a given period of time is called the hazard ratio, or HR. For time-to-event data, this ratio serves as a metric of impact magnitude |
Follow-up duration | 32,877 patients had arrhythmias throughout a mean follow-up of 12.2 years; these included 10,527 episodes of bradyarrhythmia, 24,484 cases of VA, and 3789 occurrences of AF |
Key findings | Following adjustment for possible confounders, the risk of different arrhythmias was shown to be positively correlated with CRP levels; the risk was found to be negatively correlated with neutrophil count, monocyte count, and NLR; the risk was found to be U-shaped with lymphocyte count, SII, PLR, and LMR. The greatest correlation with markers of systemic inflammation was shown in VA, then AF, and bradyarrhythmia |
Conclusions | The development of AF, VA, and bradyarrhythmia was strongly correlated with a number of systemic inflammatory markers, the latter two of which have not received much attention. More randomized controlled trials are required; however, active systemic inflammation treatment may be beneficial in lowering the burden of arrhythmias |
Specific infections include bacterial, fungal, or viral infections as well as autoimmune disorders can result in localized inflammation. Arrhythmias can result from localized inflammation through a number of mechanisms:
First, there is a chance that localized inflammation will cause structural remodeling in cardiovascular tissue, in addition to processes like necrosis, apoptosis, and fibrosis [
5,
23]. These changes result in heterogeneous and anisotropic regions by affecting the electrical connection and propagation between cardiac cells [
5,
23]. Increased dispersion in conduction velocity (CV) and steeper CV restitution slopes are two key outcomes of this structural remodeling that affect the stability of reentry [
5,
23]. The accumulation of extra fibrous connective tissue within an organ is known as fibrosis. This may cause arrhythmias, alter the heart's natural architecture, and hinder its functionality [
24].
Second, localized inflammation may result in inflammation of the ganglia or cardiac nerves, which may change how the heart's autonomic nervous system regulates itself [
10]. It may have an impact on contractility, arrhythmogenicity, heart rate, and conduction velocity [
25]. Neuropathic pain, which can result from inflammation, can also set off cardiac arrhythmias and reflexes [
25].
Third, localized inflammation may directly harm the heart's cells, impairing their ability to handle calcium, boosting their automaticity, or making them more susceptible to catecholamines [
10]. A vital component of cardiac muscle cell contraction is calcium. Increased sarcoplasmic reticulum (SR) calcium leak and reduced SR calcium absorption brought on by inflammatory cytokines can both lead to cytosolic calcium excess [
26]. This capacity to induce spontaneous calcium waves and delayed after-depolarizations (DADs) may lead to arrhythmias [
27].
Fourth, localized inflammation may compress or infiltrate the cardiac conduction system, including the His-Purkinje system, the atrioventricular node, and the sinoatrial node, which may result in heart block or bradyarrhythmias [
28].
Conditions like endocarditis, myocarditis, or pericarditis may result from localized inflammation that targets specific heart components [
29]. Endocarditis can cause valve destruction, leakage, or constriction. It is usually caused by bacterial or fungal infections that travel through the circulation and cling to the valves. These changes interfere with the heart's electrical impulses as well as blood flow [
30,
31]. Furthermore, endocarditis can result in vegetation or blood clots, which are masses made of bacteria and cells that can separate and spread to vital organs like the brain or lungs and cause dangerous consequences [
32]. Myocarditis can also result from autoimmune diseases, allergic responses, poisons, or parasites [
33]. It is frequently caused by viral infections that damage the heart. Myocarditis can also weaken the heart muscle, impairing its ability to contract and relax, which can affect blood pressure and the electrical activity of the heart [
34]. Arrhythmias may result from the obstruction or slowing down of electrical impulses caused by scar tissue growth in the heart as a result of myocarditis [
34]. Although viral infections are usually the cause of pericarditis, other causes include renal failure, rheumatoid arthritis, inflammatory disorders, trauma, radiation, or drugs [
35]. One of the effects of pericarditis is a buildup of fluid in the pericardial region, which puts pressure on the heart and reduces its functionality [
36]. Additionally, pericarditis may cause the pericardium to thicken and harden, which would limit the heart's motion and disrupt electrical impulses [
37].
Here are a few instances of both localized and systemic cardiac inflammation, along with the corresponding arrhythmias:
When the body's reaction to an infection results in widespread inflammation and organ malfunction, it can lead to sepsis, a potentially fatal illness [
38]. Myocardial depression, or a reduction in the heart's capacity to pump blood, and systemic inflammatory response syndrome (SIRS), a condition of hyperinflammation that can harm heart tissue, are two ways that sepsis can impact the heart [
38]. In addition, hypoxia, hypotension, acid–base imbalances, and electrolyte abnormalities can all result from sepsis and disrupt the heart's regular electrical activity, leading to arrhythmias [
38]. An autoimmune condition that damages and inflames joints is rheumatoid arthritis (RA). The heart is among the numerous organs that RA can impact [
39]. Because RA can induce inflammation of the heart's muscle (myocarditis), lining (pericarditis), or electrical system (conduction system), it can raise the risk of arrhythmias, or irregular heartbeats [
39]. In addition, RA can raise the risk of heart failure and coronary artery disease by causing atherosclerosis, or the accumulation of plaque in the arteries [
39]. Another autoimmune condition that can impact several organs, such as the skin, kidneys, lungs, and heart, is systemic lupus erythematosus (SLE) [
40]. Heart muscle, pericardium, blood arteries, and heart valves can all become inflamed and damaged as a result of SLE [
40]. Anti-phospholipid syndrome, a disorder that makes blood clot more readily, and an increased risk of heart attack and stroke can also be brought on by SLE [
40]. People with SLE may have arrhythmias as a result of these causes [
40].
Other complex and varied physiological and molecular mechanisms that link arrhythmogenesis and inflammation include:
Cardiac ion channels, which include sodium, potassium, calcium, and chloride, are impacted by inflammation and control cardiac action potentials (APs) [
41]. Inflammatory cytokines such as interleukin-1 beta (IL-1-beta) and tumor necrosis factor alpha (TNF-alpha) play a key role in altering the expression and functionality of these ion channels [
41,
42]. Specifically, these cytokines can reduce the expression and function of sodium, calcium, and potassium channels, resulting in a shorter action potential (AP) duration and greater repolarization dispersion [
41,
42]. The impact extends to the facilitation of early after-depolarizations (EADs) and the occurrence of reentrant arrhythmias [
43]. Pro-inflammatory cytokines such TNF-α, IL-1β, and IL-6 also contribute to longer action potential duration, decreased excitability, and greater dispersion of repolarization in addition to their direct effects on ion channels [
41,
42]. These cytokines also cause reactive oxygen species to be produced, which exacerbates ion channel dysfunction and results in oxidative stress [
41,
42]. They also have an impact on how other cytokines, such as interleukin-10 (IL-10), which has anti-inflammatory and anti-arrhythmic qualities, are expressed and activated [
41,
42].
Another study that used a computational model of the human ventricle showed that arrhythmogenic changes in the action potential and the pseudo-electrocardiogram, such as prolonged QT interval, early after-depolarizations, and reentry, could be caused by the effects of TNF-α, IL-1β, and IL-6 on the ion channels [
13]. In patients with a history of myocardial infarction and increased C-reactive protein, the suppression of inflammation may lower the risk of cardiovascular events, including arrhythmias, according to a randomized controlled trial utilizing canakinumab, a monoclonal antibody that targets IL-1β [
44].
The expression of connexin 43 (Cx43), a crucial part of gap junctions that mediate intercellular communication, can also be increased by inflammation [
9]. Inflammatory kinases including protein kinase C (PKC) and p38 mitogen-activated protein kinase (MAPK) have the ability to phosphorylate Cx43, altering gap junction function and distribution [
9]. This may have an impact on the electrical synchronization and coupling of heart cells [
2].
The role of cardiac bitter taste receptors (TAS2Rs) in the pathogenesis of heart diseases is discussed in a study titled “Cellular mechanisms and molecular pathways linking bitter taste receptor signalling to cardiac inflammation, oxidative stress, arrhythmia, and contractile dysfunction in heart diseases” [
43]. According to the study by Menizibeya et al. [
43], abnormal TAS2R signaling may put people at risk for developing cardiac inflammatory and oxidative stress diseases, which are marked by arrhythmia and contractile dysfunction. According to the same study, cardiac TAS2Rs serve as gateway surveillance systems that monitor and identify toxins or pathogens, including microbial components, and then launch reactions that eventually result in the host being protected against aggression [
43].
Swelling in inflammation: implications for cardiac function
A coordinated reaction to tissue damage or infection, inflammatory swelling is characterized by elevated blood flow and enhanced capillary permeability [
45]. White blood cells, proteins, and fluid from the circulation may migrate into the interstitial space thanks to this well planned mechanism, which aids in infection prevention and promotes healing. On the other hand, edema, or an abnormal buildup of fluid in tissue spaces, can result from excessive fluid leakage from capillaries [
46].
Through a variety of processes, edema can then affect the electrolyte balance as well as the mechanical and electrical activities of the heart [
47]. Edema's modification of the distribution and concentration of electrolytes in bodily fluids can lead to either an excess or a shortage of certain electrolytes, such as hyponatremia (low sodium levels) or hyperkalemia (high potassium levels), which can affect the heart and other nerve and muscle functions [
47].
Additionally, the electrical conduction system of the heart, which controls heart rate and rhythm, may be hampered by edema [
48]. Hypoxia can result from edema's buildup of fluid in the lungs, which can hinder gas exchange [
48]. In consequence, hypoxia reduces the oxygen delivery to cardiac cells, which modifies their excitability and membrane potential [
48]. Furthermore, hypoxia can increase reactive oxygen species (ROS) generation, which can harm cardiac cells and promote arrhythmias [
7,
48].
Arrhythmias can be facilitated by heterogeneity caused by edema-induced changes in plasma volume and osmolarity, which can also affect blood and cardiac cells' electrolyte levels [
7,
49]. Stretching cardiac cells mechanically triggers mechanosensitive ion channels and receptors [
7,
50]. These elements alter intracellular calcium levels, which has an impact on cardiac cells' excitability and contractility [
7,
50]. Pro-arrhythmic effects are further enhanced by the release of neurohormones and cytokines generated by stretching [
7,
50]. Stretch also modifies extracellular matrix and gap junctions, affecting heart tissue's structural integrity and electrical coupling [
7,
50].
Edema affects not only the cellular and electrical components of cardiac function but also the mechanical functions of the heart by raising heart rate and effort [
51]. Heart failure, a disease in which the heart is unable to pump enough blood to fulfill the body's demands, can be caused by or result from this increased strain [
51,
52]. Heart failure symptoms include exhaustion, swelling, and shortness of breath. It can also present as a fluid buildup in the legs and abdomen (peripheral edema) or in the lungs (pulmonary edema) [
51,
52].
Role of immune responses
Macrophages are a key player in the complex regulation of immune cells in the setting of inflammation and arrhythmogenesis. They are particularly important in regulating the electrical characteristics of cardiomyocytes, which are the main cells in charge of cardiac contraction and conduction [
6,
53]. Based on their origin, phenotype, and function, cardiac macrophages are a heterogeneous population that may be categorized as resident or recruited [
6,
53]. Originating from embryonic and fetal progenitors, resident macrophages regulate cardiac electrophysiology by preserving tissue homeostasis in steady-state settings [
53,
54]. On the other hand, when the heart is injured or infected, recruited macrophages that are sourced from circulating monocytes enter the heart and aid in tissue healing and inflammation [
53,
54].
Myocardial infarction (MI), where a blood supply stoppage results in tissue damage and necrosis, is a powerful example of the sequential activation of immune cells in the setting of inflammation and arrhythmogenesis [
6]. Damaged cardiomyocytes after MI produce signals of danger, which trigger the innate immune system and start an inflammatory response [
6]. The first immune cells to reach the infarcted region are neutrophils, which phagocytose dead cells and debris. This process releases reactive oxygen species and proteases, which worsen tissue damage [
6]. Granule protein production during neutrophil degranulation has been linked to a number of outcomes throughout the MI process [
55]. Notably, cardiac neutrophils raised the risk of arrhythmia in a mouse model of ventricular tachycardia following MI, indicating a connection between their presence and a pro-arrhythmic milieu [
56].
After that, monocytes infiltrate the tissue and differentiate into macrophages, which polarize into pro- or anti-inflammatory (M1) phenotypes depending on the tissue [
6]. By producing pro-inflammatory cytokines, M1 macrophages lead to tissue damage, fibrosis, and compromised heart function [
6,
57]. On the other hand, by generating growth factors and anti-inflammatory cytokines, M2 macrophages aid in tissue regeneration and repair [
6,
57]. For infarcted tissue repair and inflammation resolution, the delicate balance between M1 and M2 macrophages is essential [
6,
57].
Following MI, the remodeling and inflammatory processes affect the electrical characteristics of the heart as well, resulting in a pro-arrhythmic substrate that increases the risk of ventricular arrhythmias [
58]. Immune cells may affect arrhythmogenesis through a variety of mechanisms, some of which are direct (via gap junctions), indirect (through cytokines and chemokines changing the function of ion channels in cardiomyocytes), and macrophage-mediated modulation of cardiac sympathetic nervous system (SNS) activity [
6,
53,
57,
59].
An association between increased neutrophil, basophil, and lymphocyte counts and atrial fibrillation was shown in a Mendelian randomization research [
60]. More specifically, an increased incidence of atrial fibrillation was linked to genetically predicted elevations in CD4 + T cell numbers [
60]. These results emphasize even more the complex interplay of immune cells, inflammation, and arrhythmogenesis in a range of heart diseases.
Clinical implications
Arrhythmia management and therapy may be impacted by inflammation in a number of different ways.
First, inflammation can alter how the body reacts to anti-arrhythmic medications or device therapy, including catheter ablation or implanted cardioverter defibrillators (ICDs) [
2]. For instance, in specific circumstances, such as atrial fibrillation (AF) or postoperative arrhythmias, some anti-inflammatory medications, such as corticosteroids or colchicine, may have anti-arrhythmic benefits [
2]. However, several anti-arrhythmic medications, like amiodarone and sotalol, have the potential to promote inflammation or interact with inflammatory markers [
9]. In addition, inflammation could make it more likely that device implantation or ablation procedures would result in problems or infections [
2].
Second, arrhythmias can be diagnosed using inflammation as a biomarker. It has been demonstrated that a number of inflammatory markers, including C-reactive protein (CRP), interleukin-6 (IL-6), tumor necrosis factor alpha (TNF-alpha), and monocyte chemoattractant protein-1 (MCP-1), are linked to the occurrence or recurrence of arrhythmias, including atrial fibrillation (AF), ventricular tachycardia (VT), and bradyarrhythmia [
61]. These indicators can be tested in blood samples or found using imaging methods like magnetic resonance imaging (MRI) or positron emission tomography (PET) [
62]. Inflammatory indicators can aid in identifying individuals who are at a high risk for arrhythmias or help with therapy selection.
Third, new treatment approaches for arrhythmias may address inflammation. For the prevention or treatment of arrhythmias, a number of anti-inflammatory medications, including statins, omega-3 fatty acids, colchicine, corticosteroids, and biologics, have undergone clinical trials [
63].
More research is required to identify the ideal timing, dosage, duration, and safety of these therapies because the outcomes thus far have been contradictory or inconclusive.
Clinical consequences of inflammation-induced ECG alterations include:
Heightened mortality and cardiovascular disease (CVD) risk
Atherosclerosis, endothelial dysfunction, and left ventricular dysfunction are more common in patients with chronic inflammatory illnesses. These conditions can result in coronary heart disease, stroke, heart failure, and sudden cardiac death [
64].
Diagnostic challenges
In patients with chest discomfort and increased cardiac biomarkers, in particular, inflammation-induced alterations in the ECG may resemble acute coronary syndromes [
65,
66]. Therefore, it's critical to employ further testing, such as echocardiography, cardiac magnetic resonance imaging, or coronary angiography, to distinguish between ischemia and non-ischemic causes of ECG alterations [
65,
66].
Therapeutic implications
To lessen cardiac inflammation and stop more damage, inflammation-induced alterations in ECG may point to the need for anti-inflammatory therapy with corticosteroids, non-steroidal anti-inflammatory medications, or biologic agents [
67]. Furthermore, intensive care of classic CVD risk factors, such as dyslipidemia, hypertension, smoking, and diabetes, may be beneficial for individuals with chronic inflammatory illnesses [
67].
The following are the consequences of inflammation-induced arrhythmogenesis in the electrocardiogram (ECG):
Prolonged QT interval
Inflammation can impact cardiomyocytes' ion channel function, resulting in a delayed repolarization and a prolonged action potential duration (APD) [
9,
13]. An ECG manifestation of this might be a longer QT interval, which raises the possibility of torsades de pointes (TdP), a kind of ventricular tachycardia [
68].
Enhanced heterogeneity
Inflammation can also result in transmural and regional variations in the electrical characteristics of the heart tissue, including dispersion of repolarization, refractoriness, and conduction velocity [
9,
13]. As a common cause of arrhythmias, this may enhance the heterogeneity of the heart tissue and encourage the creation and maintenance of reentrant circuits [
68].
Reduced adaptability
When there is inflammation, the heart's tissue may be less able to adjust to variations in heart rate, which may occur during stress or exercise [
13]. This may lead to a decreased rate adaptation of the QT and APD intervals, which may make a person more vulnerable to arrhythmias in either a physiological or pathological setting [
68].
Therapeutic interventions
Atrial fibrillation (AF), ventricular tachycardia (VT), and sudden cardiac death (SCD) are a few arrhythmias that can be prevented or treated by reducing inflammation. Several of these strategies include:
Anti-inflammatory drugs
These consist of corticosteroids, NSAIDs, colchicine, statins, and biologics, among others. They may be used to treat inflammatory cardiomyopathies that increase the risk of arrhythmias, such as cardiac sarcoidosis, myocarditis, and rheumatic heart disease [
16]. By modifying the electrophysiological characteristics of cardiac cells, such as ion channel function, calcium handling, and gap junction coupling, they may also have anti-arrhythmic effects [
69]. Anti-inflammatory medicine effectiveness and safety for the prevention or treatment of arrhythmias, however, are only partially and inconsistently supported by data. Following cardiac surgery, corticosteroids or colchicine have been demonstrated in certain trials to be helpful in preventing AF [
69], whereas NSAIDs or biologics have been linked to an increased risk of AF [
69,
70]. Anti-inflammatory medications can also have negative side effects, including bleeding, infections, and metabolic disturbances [
69].
Lifestyle modifications
These include of reducing body weight, working out, making dietary adjustments, quitting smoking, and managing stress. They could assist in lowering blood pressure and cholesterol levels, improving endothelial function and autonomic balance, and reducing inflammation and oxidative stress [
20,
70]. The prevalence and burden of AF in obese people can be decreased with lifestyle changes, according to several research [
70,
71]. Additionally, they could enhance the results of catheter ablation for AF or VT [
70,
71]. However, lifestyle changes need long-term compliance and behavioral adjustments, which may be difficult for certain individuals. For best effects, they might also need to be paired with pharmacological or interventional therapy [
70,
71].
Other interventions
These include implanted cardioverter defibrillators (ICDs), catheter ablation, cardiac resynchronization treatment (CRT), and anti-arrhythmic medications. The underlying causes or initiators of arrhythmias, including as ischemia, scar tissue, reentry circuits, or ectopic foci, may be treated with them [
69‐
71]. By changing the generation of cytokines, immune cell infiltration, or neuro-hormonal activation, they may also modify the inflammatory response [
69]. These procedures could be restricted by procedural issues, device issues, infections, recurrent arrhythmias, or pro-arrhythmic side effects [
69‐
71]. They might also be affected by the level of inflammation or its presence. By increasing atrial fibrosis or electrical heterogeneity, inflammation, for instance, may reduce the effectiveness of catheter ablation or anti-arrhythmic medications [
69].
The kind, etiology, and severity of the arrhythmias, as well as the patient's features and comorbidities, may all affect how effective certain treatment techniques are. As a result, it's critical to customize the treatment plan based on the risk–benefit analysis and patient preferences. Several general ideas are:
Anti-inflammatory medications
They may be helpful for individuals with inflammatory cardiomyopathies or postoperative AF in terms of arrhythmia prevention or therapy [
72]. In individuals who may be at risk for drug interactions or for whom there are contraindications, they should be taken with caution [
72]. Additionally, they need to be watched for any negative effects and stopped as necessary [
71].
Lifestyle changes
The prevention or treatment of arrhythmias in people with obesity, hypertension, diabetes mellitus, or metabolic syndrome may be aided by lifestyle changes [
73]. However, they must be used in conjunction with a thorough program to lower cardiovascular risk, which may also include, if needed, pharmacological or interventional therapy [
73]. Additionally, behavioral therapy and follow-up should be provided [
70].
Other interventions
In patients with structural heart disease, ischemic heart disease, heart failure, or refractory arrhythmias, they may be beneficial in preventing or treating arrhythmias [
74]. However, they should be chosen in accordance with evidence-based recommendations and guidelines that take patient eligibility requirements and procedure results into account [
74]. Inflammatory indicators and modifiable risk factors that might reduce their effectiveness should also be addressed [
70,
71].
In the area of cardiac electrophysiology, there are a number of difficulties and constraints in applying research findings from fundamental science to clinical practice. Among them are:
Lack of relevant animal models [69, 75, 76]
Animal models are frequently employed to investigate the workings of inflammation and how it affects arrhythmogenesis. They might not, however, accurately reflect human physiology, illness, or genetics. They could also react differently to treatments or medications. Therefore, it's possible that the conclusions drawn from research on animals cannot be applied to or generalized to patients who are human.
Lack of standardized definitions and measurements [69, 75, 76]
The process of inflammation is intricate and multifaceted, including several cellular and molecular elements, pathways, and interactions. On how to define, measure, or quantify inflammation in connection to arrhythmias, there is no agreement, though. Inflammation may be measured using various biomarkers, imaging techniques, or criteria depending on the study. As a result, the findings from various research might not be comparable or reliable.
Lack of large-scale clinical trials [69, 75, 76]
To assess the effectiveness and safety of therapy strategies for arrhythmias, clinical trials are crucial. However, there aren't many extensive clinical studies that particularly discuss how inflammation plays a part in managing arrhythmias. The majority of currently conducted studies are modest, observational, or retrospective. Additionally, they could contain methodological flaws such bias in selection, confounding variables, or heterogeneity in interventions or results.
Lack of multidisciplinary collaboration and communication [75, 77]
Collaboration and communication between researchers from several fields, including fundamental science, clinical medicine, epidemiology, biostatistics, and bioinformatics, are essential for translational research. The knowledge transfer, feedback, or integration across different fields may, however, face obstacles or gaps. The involvement or engagement of doctors, patients, or other stakeholders in the study process may also be lacking.
Future directions and research gaps
Areas that require further study to broaden our comprehension include:
The ways in which cardiomyopathies and inflammatory diseases cause cardiac electrical remodeling and arrhythmogenesis [
2,
54].
Modulation of cardiac ion channels, gap junctions, calcium handling, and fibrosis by certain inflammatory cytokines, chemokines, and immune cells [
15,
54]; connections between inflammation and other arrhythmia risk factors, including oxidative stress, metabolic abnormalities, genetic mutations, and autonomic imbalance [
9,
54]; and the ongoing impacts of anti-inflammatory medications on the detection and management of arrhythmias in patients with inflammatory heart diseases [
2,
54].
Future research approaches and possible directions include:
Identifying biomarkers of inflammation and arrhythmia risk in individuals with diverse inflammatory heart diseases is the goal of prospective cohort studies [
2,
9].
Randomized controlled studies to assess the effectiveness and safety of new anti-inflammatory medications, including colchicine, statins, glucocorticoids, and biologics, in lowering arrhythmia burden and improving outcomes in patients with inflammatory heart diseases [
2].
Preclinical animal models to examine novel treatment approaches and unravel the molecular and cellular underpinnings of inflammation-induced arrhythmogenesis [
15,
54].
The effects of inflammation and anti-inflammatory therapies on cardiac electrophysiology may be predicted using computational models that include multi-scale data from research on the genomic, proteomic, metabolomic, and electrophysiological levels [
9].
Addressing these deficiencies will have the following effects on improving cardiac care:
Utilizing innovative biomarkers and imaging tools to enhance the diagnosis of inflammatory cardiac disorders and the risk classification of patients with arrhythmias [
2,
9].
Creating individualized and focused anti-inflammatory treatments that can control the inflammatory pathways implicated in arrhythmogenesis without endangering the immune system or having negative effects [
2].
Improving knowledge of the intricate connection between arrhythmogenesis and inflammation as well as the potential advantages of anti-inflammatory treatments for other cardiovascular illnesses such atherosclerosis, heart failure, and stroke [
9,
54].