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Atrioventricular node

The atrioventricular (AV) node is a compact cluster of specialized cardiac cells situated in the lower right atrium, within the triangle of Koch, that serves as an essential gatekeeper in the heart's electrical conduction system by receiving impulses from the sinoatrial node and delaying their transmission to the ventricles, ensuring coordinated atrial and ventricular contractions. Located near the coronary sinus ostium and the tricuspid valve's septal leaflet, bounded by the tendon of Todaro superiorly, the AV node measures approximately 1-5 mm in length and consists of transitional cells that transition into the penetrating portion of the atrioventricular bundle (Bundle of His). Its primary physiological role involves providing a brief conduction delay—typically 80-120 milliseconds—to allow complete atrial emptying before ventricular systole, while also filtering excessive atrial impulses to protect the ventricles from rapid rates during tachyarrhythmias. Structurally, the AV node features a compact node region with spindle-shaped cells that lack organized sarcomeres, surrounded by extensions including a longer rightward (inferior) pathway and a shorter leftward extension unique to humans; these pathways differ in molecular composition, such as the absence or presence of connexin 43 gap junctions, which influences conduction velocity. Electrophysiologically, it exhibits dual-pathway conduction: a fast pathway with rapid conduction but longer refractory period, and a slow pathway with prolonged conduction time but shorter refractory period, enabling the node to adapt to varying heart rates under autonomic nervous system influence. With an intrinsic firing rate of 40-60 beats per minute, the AV node functions as a subsidiary pacemaker, taking over rhythm generation only if the sinoatrial node fails, thereby maintaining cardiac output. Clinically, the AV node is implicated in various arrhythmias, including atrioventricular nodal reentrant tachycardia (AVNRT), where reentry circuits form between its dual pathways, and atrioventricular blocks, which can range from first-degree delays to complete dissociation requiring pacemaker intervention. It also plays a protective role in conditions like atrial fibrillation by limiting ventricular response rates, and its ablation—targeting the slow pathway—is a common, low-risk treatment for AVNRT with success rates exceeding 95%. Understanding the AV node's anatomy and electrophysiology is crucial for electrophysiological mapping and interventions in congenital heart defects or post-surgical complications.

Anatomy

Location and gross structure

The atrioventricular (AV) node is situated in the lower posterior portion of the interatrial septum, at the apex of Koch's triangle on the right atrial side of the heart. Koch's triangle is defined by three key boundaries: superiorly by the tendon of Todaro (a tendinous structure within the right atrium), inferiorly by the ostium of the coronary sinus, and anteriorly by the attachment of the septal leaflet of the tricuspid valve. This positioning places the AV node within the atrial septum, forming part of the atrial wall overlying the inferior pyramidal space adjacent to the ventricular septum. Macroscopically, the AV node appears as a compact, oval- or spindle-shaped structure composed of specialized nodal tissue. Its gross dimensions are approximately 5 mm in length, 5 mm in width, and 1 mm in thickness, though these measurements can vary slightly among individuals. The node is housed within the atrial septal buttress, bordered by the vestibules of the tricuspid and mitral valves, and it penetrates the fibrous tissues of the atrioventricular junction to connect inferiorly with the bundle of His. In relation to adjacent structures, the AV node lies in close proximity to the coronary sinus ostium (typically within 1-2 mm) and the septal leaflet of the tricuspid valve, with its posterior aspect near the inferoseptal recess of the right ventricle. These relations highlight its embedded position in the cardiac base, insulated from surrounding myocardium except at points of conduction continuity. Positional variations occur primarily within the confines of Koch's triangle, with the node's apex potentially shifting superiorly or inferiorly depending on the heart's overall geometry. These anatomical differences underscore the importance of imaging for precise localization in clinical contexts.

Histology and cellular composition

The atrioventricular (AV) node consists of a compact network of specialized cardiomyocytes embedded within dense connective tissue, forming a histological structure that ensures electrical insulation from surrounding atrial and ventricular myocardium. These cardiomyocytes are predominantly spindle-shaped, arranged in a loosely organized meshwork that transitions gradually from atrial fibers without a distinct boundary. The nodal tissue is encapsulated by a fibrous sheath composed of collagen-rich connective tissue, which provides mechanical support and electrical isolation, preventing premature ventricular activation. This architecture is evident in histological sections stained with Masson's trichrome, where the node appears as a distinct blue-collagen matrix interspersed with pale-staining cellular elements. The cellular composition of the AV node includes a heterogeneous mixture of nodal cells, transitional cells, and supporting elements. Nodal cells, often termed P cells in the compact portion, are small, pale-staining, and rounded or ovoid, resembling those in the sinoatrial node; they predominate in the central node and exhibit sparse myofibrils with abundant glycogen granules. Transitional cells, larger and more elongated, bridge the nodal cells to the atrial myocardium, displaying intermediate features such as partial sarcomere organization and increased connexin-43 expression for electrical coupling. An insulating fibrous sheath surrounds the node, while interstitial spaces contain nerve endings and autonomic ganglia that modulate conduction. These cell types contribute to the node's role in delayed impulse propagation, with P cells facilitating slow conduction through their sparse gap junctions. At the ultrastructural level, AV nodal cells lack the organized sarcomeres and intercalated discs characteristic of working myocardium, instead featuring disorganized myofibrils, numerous mitochondria, and high glycogen content that imparts a hyporeflective appearance on imaging modalities. Gap junctions are fewer and smaller compared to atrial or ventricular cells, primarily involving connexin-43, which limits intercellular coupling and underlies the slow conduction velocity. Recent studies using optical coherence tomography (OCT) have confirmed these features by visualizing the node's fibrous boundaries as high-scattering regions and its heterogeneous cell populations as areas of variable light attenuation, enhancing non-invasive assessment in ex vivo human and porcine hearts. For instance, OCT delineates the collagen-rich encapsulation and transitional zones with micron-scale resolution, revealing hyporeflective nodal cores distinct from surrounding myocardium.

Blood supply and innervation

The atrioventricular (AV) node receives its arterial blood supply primarily from the AV nodal artery, a branch that originates near the crux of the heart adjacent to the coronary sinus. In approximately 80-90% of cases, this artery arises from the right coronary artery (RCA) in right-dominant coronary systems, ensuring perfusion to the nodal tissue during the cardiac cycle. In the remaining 10-20% of individuals with left-dominant circulation, the AV nodal artery branches from the left circumflex artery (LCx), highlighting the variability in coronary dominance that influences nodal vulnerability. This arterial supply is critical for maintaining the node's metabolic demands, given its role in delaying electrical impulses. Venous drainage from the AV node follows the general pattern of the posterior heart, with small veins converging into the coronary sinus, the primary venous conduit for the atrioventricular groove and adjacent atrial myocardium. This pathway returns deoxygenated blood from the nodal region to the right atrium, supporting efficient clearance of metabolic byproducts during conduction activity. Innervation of the AV node is dominated by autonomic fibers from the cardiac plexus, with dense parasympathetic (vagal) innervation that slows impulse conduction to enforce the atrioventricular delay, and sympathetic (adrenergic) fibers that enhance nodal throughput under stress. These neural inputs modulate the node's refractory period and excitability, balancing heart rate adaptation. Recent discoveries have revealed an intrinsic GABAergic system in AV node pacemaker cells, including GABA synthesis enzymes, vesicular transporters, and GABA_A receptors, which exert inhibitory effects to fine-tune conduction velocity and prevent excessive atrioventricular synchrony.

Embryology and development

Embryonic formation

The atrioventricular (AV) node originates from the myocardium of the AV canal during early embryonic heart development, specifically forming around days 28 to 35 of gestation in humans. This timeline coincides with the looping of the primitive heart tube and the initial septation processes, where the AV canal serves as a critical junction between the developing atria and ventricles. The nodal precursors derive primarily from cells of the posterior heart field, which contribute to the formation of the conduction system components, including a specialized ring of myocardium surrounding the embryonic interventricular foramen. Key signaling pathways orchestrate the specification and differentiation of these AV nodal cells. Bone morphogenetic protein (BMP) signaling, mediated through the Alk3 receptor (also known as Bmpr1a), is essential for proper nodal specification within the AV myocardium, ensuring the development of distinct electrophysiological properties and structural integrity at the AV junction. Disruption of Alk3 leads to abnormal conduction and morphological defects in the AV node, highlighting its role in myocardial patterning. Complementing this, transcription factors such as Tbx3 and Msx2 regulate differentiation by suppressing chamber-specific gene expression (e.g., Cx40 and Nppa) in the AV canal region, thereby maintaining nodal identity and promoting slow-conducting phenotypes. These factors are activated downstream of BMP signaling, forming a regulatory network that delineates the AV nodal lineage from surrounding working myocardium. Morphogenesis of the AV node involves the progressive organization of this initial myocardial ring into a compact structure at the AV junction. Early in development, the node emerges as a diffuse, slow-conducting annular myocardium that bridges the atrial and ventricular septa, influenced by the expression of Tbx3 along these septal crests. Over time, this ring compacts dorsally, forming the definitive nodal mass, while fibro-fatty insulation develops to isolate it from adjacent tissues. Cardiac neural crest cells play an indirect but crucial role in this process by contributing to the formation of the central fibrous body and annulus fibrosus, which electrically insulate the node and facilitate its maturation into a functional delay element. Following birth, the AV node undergoes postnatal maturation, with its intrinsic automaticity stabilizing to a rate of 40-60 beats per minute in humans. This pacemaking activity relies heavily on hyperpolarization-activated cyclic nucleotide-gated (HCN) channels, particularly HCN4, which generates the "funny" current (If) essential for diastolic depolarization and rhythmicity. Recent studies (2023-2025) have elucidated how HCN4 expression and function in the AV node adapt postnatally, contributing to conduction stability and responding to autonomic modulation, with disruptions linked to arrhythmias.

Congenital variations and anomalies

Twin atrioventricular (AV) nodes, also known as duplicated AV nodes, represent a significant congenital anomaly frequently observed in heterotaxy syndrome, where they occur in up to 51.5% of cases with right atrial isomerism and 8.7% with left atrial isomerism. These duplicated nodes arise from disrupted embryonic patterning of the AV junction, leading to separate conduction pathways that can connect via a sling of tissue, often in association with complex congenital heart defects (CHD) such as atrioventricular canal defects. Accessory pathways, which bypass the AV node and enable abnormal AV connections, are another common anomaly in CHD with abnormal AV connections, with prevalence rates ranging from 4.4% in heterotaxy to 11.4% in congenitally corrected transposition of the great arteries (ccTGA), though notably absent in some cases like AV canal defects. Congenital heart block (CHB), a functional anomaly impairing AV nodal conduction, affects approximately 1 in 22,000 live births and is often linked to maternal autoantibodies against SSA/Ro and SSB/La antigens in 60-90% of non-structural cases, causing inflammation and fibrosis of the AV node during fetal development. In structural defects, CHB is associated with anomalies like Ebstein's anomaly, where accessory pathways coexist in 10-52% of patients, potentially exacerbating conduction irregularities through altered nodal positioning near the malformed tricuspid valve. Persistent fetal dispersion of the AV node and fragmentation of the His bundle constitute additional developmental anomalies, observed in approximately 20% of cases in postmortem studies of sudden cardiac death, where incomplete compaction of nodal tissue persists abnormally, predisposing to intermittent or progressive block. The prevalence of twin AV nodes in CHD elevates arrhythmia risk, with supraventricular tachycardia occurring in 65.5% of heterotaxy cases and 58.3% of double inlet ventricle cases harboring this anomaly, due to reentrant circuits between the dual nodes. In AV septal defects, nodal positioning is disrupted, shifting posteriorly and inferiorly from the typical triangle of Koch, which can lead to elongated, vulnerable conduction pathways and heightened susceptibility to injury or dysfunction in associated CHD. Recent 2024 studies reveal a developmental hierarchy in the propensity for twin AV nodes across CHD subtypes with abnormal AV connections—highest in heterotaxy and double inlet ventricle, lower in ccTGA, and absent in AV canal—independent of accessory pathway presence, underscoring distinct embryologic vulnerabilities in AV junctional patterning.

Physiology

Role in cardiac conduction

The atrioventricular (AV) node serves as a critical relay station in the heart's electrical conduction system, receiving impulses generated by the sinoatrial (SA) node through specialized internodal tracts that facilitate rapid propagation across the atria. These tracts ensure that the depolarizing wavefront reaches the AV node efficiently, positioned at the atrioventricular junction. From there, the AV node transmits the signal to the bundle of His, which then distributes it to the ventricles via the Purkinje fibers, coordinating atrial and ventricular activation. A primary function of the AV node is to introduce a deliberate delay in conduction, typically contributing approximately 0.09 seconds to the overall PR interval on an electrocardiogram, which normally ranges from 0.12 to 0.20 seconds. This delay allows the atria to fully contract and eject blood into the ventricles before ventricular systole begins, optimizing cardiac output by preventing inefficient overlapping contractions. Without this timing mechanism, the ventricles would contract prematurely, reducing filling efficiency and stroke volume. The AV node also acts as a protective gatekeeper, modulating the transmission of impulses to shield the ventricles from excessively rapid atrial rates, such as those occurring in atrial fibrillation. Through decremental conduction properties, it blocks or slows a portion of incoming atrial signals, preventing 1:1 atrioventricular conduction that could lead to ventricular tachycardia or hemodynamic instability. Additionally, the AV node possesses intrinsic automaticity, capable of generating impulses at a rate of 40 to 60 beats per minute, enabling it to function as a backup pacemaker if the SA node fails due to dysfunction or suppression. In such scenarios, it can temporarily assume rhythm control to maintain cardiac output until the primary pacemaker recovers.

Electrophysiological characteristics

The atrioventricular (AV) node exhibits decremental conduction, whereby impulse propagation slows progressively as the atrial rate increases, primarily due to prolongation of the action potential duration and refractory period in nodal cells. This property ensures that rapid atrial impulses are delayed or blocked, protecting the ventricles from excessively high rates. Conduction velocity through the AV node is approximately 0.05 m/s, significantly slower than in atrial myocardium (0.3–0.5 m/s), owing to reliance on calcium currents rather than sodium currents for depolarization. The AV node features dual pathways: the fast pathway, characterized by rapid conduction velocity but a longer effective refractory period (typically 250–350 ms), and the slow pathway, with slower conduction velocity but a shorter refractory period (200–300 ms). The fast pathway predominates at normal heart rates, providing a shorter atriohisian (AH) interval, while the slow pathway activates during faster rates when the fast pathway refractoriness blocks conduction, resulting in a sudden prolongation of the AH interval. Action potentials in AV nodal cells display a slow upstroke velocity of about 5 V/s, driven by L-type calcium channels, with low amplitude (50–70 mV) and spontaneous diastolic depolarization enabling subsidiary pacemaker activity at rates of 40–60 beats per minute. The refractory period ranges from 250–400 ms, influenced by cycle length and autonomic inputs. Key ion channels include hyperpolarization-activated cyclic nucleotide-gated channel 4 (HCN4), which generates the funny current (I_f) responsible for diastolic depolarization and pacemaking in the compact node and posterior extensions. Autonomic tone modulates these properties: parasympathetic stimulation via acetylcholine activates muscarinic receptors, enhancing potassium conductance (I_K,ACh) to hyperpolarize cells, prolong refractoriness, and slow conduction; sympathetic stimulation via norepinephrine increases calcium currents and shortens refractoriness, accelerating conduction. A 2024 discovery revealed an intrinsic GABAergic system in AV nodal pacemaker cells, where GABA_A receptors (subunits GABRA3, GABRB2, GABRG2) mediate chloride influx to hyperpolarize cells, prolong PR intervals, and regulate atrioventricular delay; deficiency accelerates conduction and heightens arrhythmia risk. Recent advances from 2022–2025 include computational models integrating autonomic tone, demonstrating AV nodal heterogeneity in atrial fibrillation where sympathetic dominance shortens refractoriness while vagal tone prolongs it, influencing ventricular rate control. Optical mapping studies have elucidated regional refractoriness differences, showing faster conduction in posterior extensions (up to 0.1 m/s) compared to the compact node, with barriers between atrial and nodal tissues contributing to delays. These insights, derived from high-resolution imaging and simulations, highlight heterogeneous ion channel expression (e.g., variable HCN4 density) as a basis for variable conduction under stress.00200-0/fulltext)

Clinical significance

Pathophysiology and disorders

The atrioventricular (AV) node is susceptible to various pathophysiological processes that impair its conduction function, leading to delays or blocks in impulse transmission from the atria to the ventricles. First-degree AV block is characterized by a prolonged PR interval on electrocardiogram, typically exceeding 200 milliseconds, reflecting slowed conduction through the AV node without interruption of atrial-ventricular synchrony. Second-degree AV block manifests as intermittent failure of atrial impulses to conduct, subdivided into Mobitz type I (Wenckebach), where PR intervals progressively lengthen until a beat is dropped, and Mobitz type II, with sudden non-conduction without prior PR prolongation. Third-degree (complete) AV block involves total dissociation between atrial and ventricular rhythms, with ventricles driven by an escape pacemaker, often resulting in bradycardia and hemodynamic instability. Common causes of these blocks include ischemia from coronary artery disease, degenerative fibrosis of the conduction system, and pharmacological effects from agents such as beta-blockers, digoxin, and calcium channel blockers, which depress AV nodal excitability and refractoriness. Arrhythmias originating from or involving the AV node often stem from reentrant circuits facilitated by its anatomical and electrophysiological properties. AV nodal reentrant tachycardia (AVNRT) is a supraventricular tachycardia caused by dual AV nodal pathways—a fast pathway with short conduction time and long refractory period, and a slow pathway with longer conduction time and shorter refractory period—allowing unidirectional block and retrograde conduction to sustain a reentrant loop within or near the node. This mechanism accounts for the majority of paroxysmal supraventricular tachycardias, with rapid rates up to 200 beats per minute. In atrial fibrillation, the AV node serves as a critical filter, but rapid irregular conduction through it can transmit excessive ventricular rates, exacerbating hemodynamic compromise, particularly if nodal refractoriness is altered by underlying disease. Beyond ischemic and degenerative etiologies, the AV node can be infiltrated by inflammatory or infectious processes, disrupting its cellular architecture. Lyme carditis, caused by Borrelia burgdorferi, leads to lymphoplasmacytic infiltration of the endocardium and perivascular regions around the AV node, commonly resulting in high-degree AV blocks that may resolve with antibiotic therapy. Sarcoidosis involves non-caseating granulomatous infiltration of the myocardium, including the AV node, which can produce conduction disturbances through direct tissue replacement and fibrosis, affecting up to 30% of cardiac sarcoidosis cases with AV block as a prominent feature. Ischemic injury specifically from right coronary artery (RCA) occlusion impairs AV nodal perfusion, as the nodal artery arises from the RCA in approximately 80% of individuals, leading to transient or persistent blocks during inferior myocardial infarction. A 2024 study identified a GABAergic system in AV nodal pacemaker cells, where deficiency in GABAA receptors accelerates atrioventricular conduction and impairs the node's physiological delay, potentially contributing to conduction defects and increased arrhythmia vulnerability. Risk factors for AV nodal dysfunction emphasize age-related and structural vulnerabilities. Aging promotes idiopathic fibrosis and fatty deposition within the AV node and surrounding conduction tissues, reducing cell density and increasing block incidence, with atrioventricular block occurring in up to 1-2% of individuals over 65 years. In congenital heart disease, particularly heterotaxy syndromes, the presence of twin AV nodes—duplicated conduction pathways connected by a sling of myocardial tissue—heightens arrhythmia risk, with supraventricular tachycardia reported in 58-65% of affected patients depending on the lesion type, due to enhanced reentry substrates.

Diagnosis and management

Diagnosis of atrioventricular (AV) node dysfunction primarily relies on electrocardiography (ECG), which detects PR interval prolongation indicative of first-degree AV block or higher-degree blocks such as second- or third-degree AV block. Electrophysiology studies (EPS) are essential for confirming dual AV nodal pathways and diagnosing AV nodal reentrant tachycardia (AVNRT), involving programmed atrial stimulation to induce tachycardia and map the reentrant circuit. Holter monitoring is used to capture intermittent conduction abnormalities, such as paroxysmal AV block, over 24-48 hours, aiding in correlation with symptoms like syncope. Echocardiography evaluates structural heart disease contributing to AV node issues, such as cardiomyopathy or valvular abnormalities, and is recommended in all patients with AV block to identify underlying causes. Emerging intracardiac imaging techniques, including optical coherence tomography (OCT), support ablation planning by providing high-resolution visualization of cardiac structures during procedures, though primarily validated in coronary and atrial applications as of 2025. Management of AV node-related bradycardia involves pharmacologic interventions like atropine, administered at 1 mg intravenously every 3-5 minutes up to a maximum of 3 mg, to temporarily enhance AV nodal conduction in acute settings. For persistent high-degree AV block, permanent pacemaker implantation is indicated to maintain ventricular rate, with transvenous pacing preferred for immediate stabilization. In AVNRT, catheter ablation targets the slow pathway within the AV node, achieving success rates over 95% with low recurrence. For refractory atrial fibrillation requiring rate control, AV node ablation combined with pacemaker implantation improves symptoms and quality of life, with 2023-2025 studies demonstrating long-term left ventricular ejection fraction (LVEF) improvements of 5-10% in patients with baseline systolic dysfunction. Recent advances from 2023-2025 emphasize conduction system pacing, including His-bundle and left bundle branch pacing, as superior to traditional right ventricular pacing following AV node ablation, reducing heart failure progression and improving LVEF by preserving physiological activation. Ongoing trials, such as those evaluating physiological pacing in refractory atrial fibrillation, support its adoption for better hemodynamic outcomes over biventricular alternatives.

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