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First-degree atrioventricular block

First-degree atrioventricular block is a conduction delay in the atrioventricular node or His-Purkinje system, defined electrocardiographically by a prolonged PR interval greater than 200 milliseconds with every P wave followed by a QRS complex, indicating intact but slowed atrioventricular conduction.^[1]^[2] This abnormality reflects slowed impulse transmission from the atria to the ventricles without interruption, often resulting from increased vagal tone, medications such as beta-blockers or calcium channel blockers, myocardial ischemia, fibrosis, or inflammatory conditions like Lyme disease.^[1]^[3] Prevalence increases with age, affecting approximately 1-4% of the general population, with higher rates in older adults and those with comorbidities like hypertension or structural heart disease.^[1]^[4] Typically asymptomatic and benign, it requires no specific treatment beyond addressing reversible causes, though "marked" first-degree block with PR intervals exceeding 300 milliseconds may cause symptoms such as fatigue or exercise intolerance due to ineffective atrial contribution to ventricular filling.^[1]^[3] Emerging longitudinal data indicate associations with increased risks of atrial fibrillation, heart failure, pacemaker requirement, and mortality, challenging the traditional view of it as inconsequential and warranting monitoring in select patients.^[5]^[6]^[7]

Pathophysiology

Definition and electrocardiographic features

First-degree atrioventricular block is characterized by a delay in conduction from the atria to the ventricles, manifested on the electrocardiogram (ECG) as a prolonged PR interval exceeding 0.20 seconds while maintaining 1:1 atrioventricular conduction, with every P wave followed by a QRS complex.^[1]^[8] The normal PR interval ranges from 0.12 to 0.20 seconds, measured from the onset of the P wave to the beginning of the QRS complex; prolongation beyond this threshold indicates first-degree block without interruption in impulse transmission.^[9]^[10] Electrocardiographic features include a consistently extended PR interval across consecutive beats, with no progressive lengthening or dropped QRS complexes as seen in higher-degree blocks.^[1] P waves remain normal in morphology and precede each QRS, which typically exhibits normal duration unless confounded by unrelated conduction abnormalities such as bundle branch block.^[3] Atrial and ventricular rates are usually preserved, reflecting intact overall rhythm without evidence of atrioventricular dissociation.^[10] When the PR interval surpasses 0.30 seconds, it is termed marked first-degree block, potentially leading to P waves overlapping preceding T waves, though conduction remains complete.^[11] Diagnosis relies on standard 12-lead ECG, with confirmation in multiple leads to exclude artifacts or measurement errors.^[1]

Mechanisms of conduction delay

The conduction delay in first-degree atrioventricular (AV) block manifests as prolongation of the PR interval beyond 200 milliseconds on electrocardiography, reflecting slowed impulse propagation from atria to ventricles while maintaining 1:1 conduction. This delay most commonly localizes to the AV node, where nodal cells exhibit inherently slow conduction velocities due to reliance on calcium-dependent action potentials and sparse intercellular connections, but it can also arise intra-atrially, within the His bundle, or in the Purkinje system.^[1]^[3] Infra-nodal delays, indicated by widened QRS complexes, are less frequent in isolated first-degree block and carry higher risk of progression to advanced blocks.^[1] Physiologically, enhanced parasympathetic (vagal) tone contributes to delay by acetylcholine-mediated activation of muscarinic receptors on AV nodal cells, leading to membrane hyperpolarization, reduced phase 0 upstroke velocity, and prolonged refractoriness.^[3] Sympathetic withdrawal or dominance inversely shortens the PR interval by increasing cyclic AMP and enhancing calcium influx. Pharmacological agents exacerbate delay via similar ion channel effects: beta-blockers and non-dihydropyridine calcium channel blockers suppress nodal excitability, while digoxin increases vagal tone indirectly through enhanced parasympathetic activity.^[1]^[3] Pathologically, structural alterations such as fibrosis or sclerosis of the AV nodal region—prevalent in aging—increase conduction resistance by disrupting cell-to-cell coupling and replacing excitable tissue with non-conductive scar. Ischemia, particularly from inferior myocardial infarction affecting the AV nodal artery, impairs ATP-dependent ion handling, while inflammatory or infiltrative processes (e.g., myocarditis, sarcoidosis) cause edema or cellular infiltration that slows propagation. Electrolyte derangements like hyperkalemia further depress nodal excitability by altering resting membrane potential.^[1]^[3] In rare cases, congenital anomalies or congenital heart defects contribute to intra-atrial delays.^[3]

Epidemiology

Prevalence and incidence

First-degree atrioventricular block exhibits a prevalence that varies by age, sex, and population studied, typically ranging from 1% to 7% in adults, with higher rates observed in older individuals due to age-related degenerative changes in the conduction system.^[12] ^[1] In general population cohorts, prevalence approximates 3-4%, as documented in electrocardiographic screenings of asymptomatic adults.^[13] ^[14] Males demonstrate consistently higher prevalence than females, with ratios around 2:1 in large-scale studies (e.g., 5.1% in men versus 2.2% in women among over 10,000 screened individuals).^[13] Age is the strongest correlate, with rates below 1% in those under 60 years rising to 6% or more in those over 60, reflecting cumulative fibrotic infiltration of the atrioventricular node.^[15] In younger populations, such as children and adolescent athletes, prevalence remains low at approximately 1%, substantially less than in older adults or non-athletic cohorts.^[16] Ethnic variations show minor differences, with some evidence of slightly higher rates in African-American versus Caucasian groups across age strata, though data are limited and confounded by comorbidities.^[17] Incidence data are scarcer, as the condition is often asymptomatic and detected incidentally, but estimates indicate about 0.13 new cases per 1,000 person-years in general populations, underscoring its gradual onset rather than acute emergence.^[18] Longitudinal studies confirm low annual progression rates from normal conduction, primarily driven by aging or underlying cardiac pathology rather than isolated incidents.^[1]

Associated demographic and risk factors

First-degree atrioventricular block demonstrates a marked increase in prevalence with advancing age, remaining relatively uncommon at 1.0-1.5% in individuals under 60 years but rising to approximately 6.0% in those over 60 years, reflecting cumulative degenerative changes in the cardiac conduction system.^[1] ^[15] Males exhibit a higher prevalence than females, with one population-based study reporting rates of 5.1% in men versus 2.2% in women, and multivariate analyses consistently identifying male sex as an independent risk factor alongside older age.^[13] ^[3] ^[19] Additional demographic correlates include greater body height, observed as an independent association in cohort studies, potentially linked to variations in cardiac anatomy or vagal tone.^[19] Limited evidence suggests elevated risk in white populations compared to others, though data on racial and ethnic disparities remain sparse and require further validation across diverse cohorts.^[20] Beyond demographics, familial aggregation contributes to risk, with first-degree relatives of affected individuals facing a significantly elevated hazard ratio for atrioventricular block, modulated by the proband's age at diagnosis and suggesting heritable components in conduction pathway integrity.^[21] Comorbid conditions such as hypertension, hyperglycemia, chronic kidney disease, and overweight status independently predict development, with population-attributable fractions indicating that modifiable metabolic factors like elevated blood pressure and glucose may underlie over half of cases in some analyses.^[22] ^[20]

Etiology

Intrinsic causes

Idiopathic fibrosis and sclerosis of the conduction system constitutes the predominant intrinsic cause of first-degree atrioventricular (AV) block, responsible for approximately 40% of cases.^[10] This degenerative process, prevalent in older adults, entails progressive fibrotic replacement of specialized conducting tissues, including the AV node and His-Purkinje system.^[1] Specific variants include Lev's disease, characterized by annular fibrocalcific changes encroaching on the AV junction, and Lenegre's disease, involving idiopathic sclerosis of the infranodal conduction pathways.^[3] These conditions arise from age-related wear, leading to conduction delay without external provocation, and prevalence of first-degree AV block rises to about 6% in those over 60 years.^[1] Ischemic heart disease accounts for roughly 20% of intrinsic etiologies, where coronary artery occlusion or infarction impairs blood supply to the AV node or bundle branches, resulting in localized necrosis and fibrosis.^[10] Inferior myocardial infarction particularly affects the AV node due to its right coronary artery dominance, prolonging the PR interval in up to 10-20% of such events.^[1] Infiltrative disorders, such as cardiac sarcoidosis or amyloidosis, deposit abnormal proteins or granulomas within the conduction tissues, disrupting impulse propagation.^[10] Sarcoidosis, for instance, underlies up to one-third of new-onset AV blocks in adults aged 18-60 without evident structural heart disease upon targeted evaluation, including cardiac MRI or biopsy.^[10] Similarly, amyloid infiltration in transthyretin or light-chain amyloidosis stiffens and replaces nodal tissue, manifesting as conduction abnormalities in advanced stages.^[3] Congenital and hereditary forms represent rarer intrinsic causes, often linked to genetic mutations affecting connexins or sodium channels essential for conduction.^[23] Progressive familial heart block, for example, involves autosomal dominant defects leading to fibrotic degeneration over time, with first-degree block as an early electrocardiographic sign progressing to higher degrees in affected families.^[24] Myocarditis sequelae, including viral-induced scarring, may also yield permanent intrinsic nodal damage if inflammation resolves with residual fibrosis.^[1]

Reversible and extrinsic causes

Reversible causes of first-degree atrioventricular (AV) block encompass extrinsic factors that delay AV nodal conduction but resolve upon correction of the underlying trigger, distinguishing them from irreversible intrinsic myocardial degeneration. These etiologies often involve pharmacological agents, metabolic derangements, or transient physiological states that modulate AV node refractoriness without permanent structural damage. Identification and reversal of such causes are critical, as they obviate the need for invasive interventions in otherwise benign presentations.^[1] Pharmacological agents represent a primary extrinsic cause, particularly those that enhance vagal tone or directly suppress AV nodal excitability. Beta-adrenergic blockers (e.g., metoprolol, atenolol) prolong the PR interval by reducing sympathetic stimulation of the AV node, with effects typically dose-dependent and reversible upon discontinuation or dose reduction. Non-dihydropyridine calcium channel blockers such as verapamil and diltiazem similarly impede calcium influx in AV nodal cells, leading to conduction delay that normalizes after drug withdrawal. Digoxin, through increased vagal activity, can induce first-degree block, especially in therapeutic or toxic ranges, with resolution following cessation or antidote administration like digoxin-specific antibodies. Amiodarone and other class III antiarrhythmics may contribute via prolongation of repolarization phases, though their effects are often multifactorial and slower to reverse.^[10]^[2]^[25] Electrolyte and metabolic imbalances frequently precipitate reversible AV conduction delays by altering membrane potentials and ion channel function. Hyperkalemia, often exceeding 5.5 mEq/L, depresses AV nodal excitability through partial depolarization and reduced sodium channel availability, with first-degree block resolving as serum potassium normalizes via medical management such as insulin-glucose therapy or kayexalate. Hypokalemia and hypomagnesemia impair repolarization, prolonging the action potential duration and PR interval, effects that abate with electrolyte repletion. Hypercalcemia, typically above 12 mg/dL, shortens but can paradoxically delay AV conduction in severe cases by accelerating phase 2 repolarization unevenly; correction via hydration and bisphosphonates restores normal timing. Acute hypothyroidism may contribute via bradycardic effects on the sinus and AV nodes, reversible with levothyroxine replacement over weeks.^[26]^[3]^[2] Autonomic influences, particularly heightened vagal tone, constitute a physiologic extrinsic cause common in asymptomatic individuals. Endurance athletes often exhibit PR prolongation due to enhanced parasympathetic dominance, with intervals normalizing during deconditioning or exercise. Obstructive sleep apnea episodes can trigger transient vagally mediated block through recurrent hypoxia and reflex arcs, resolving with continuous positive airway pressure therapy. Inferior myocardial ischemia, as in transient coronary events, may induce reversible delay via vagal activation without infarction, improving with revascularization or anti-ischemic agents.^[27] Infectious and inflammatory processes offer reversible etiologies when addressed promptly. Lyme carditis, caused by Borrelia burgdorferi, manifests as AV block in up to 10% of disseminated cases, with first-degree involvement progressing variably but often reversing completely with antibiotics like ceftriaxone within days to weeks. Acute viral myocarditis (e.g., from coxsackievirus or influenza) can cause transient nodal inflammation and edema, leading to conduction delay that abates with supportive care and resolution of viremia. Rheumatic fever historically linked first-degree block to carditis, reversible in early stages with anti-inflammatory therapy, though rare post-eradication efforts.^[28]^[1]

Clinical Presentation

Symptomatic manifestations

First-degree atrioventricular block is generally asymptomatic, with most individuals unaware of its presence due to preserved atrioventricular synchrony and adequate cardiac output.^[1]^[3] Symptoms, when they occur, are uncommon and typically arise in cases of marked conduction delay, defined as a PR interval exceeding 0.30 seconds, where asynchronous atrial and ventricular contractions may reduce stroke volume and effective cardiac output.^[1]^[29] In such symptomatic presentations, patients may experience fatigue, exercise intolerance, malaise, or dyspnea, resembling features of pacemaker syndrome despite the absence of a device.^[1]^[11] Dizziness, lightheadedness, palpitations, or even syncope can manifest, particularly during exertion or in the context of underlying comorbidities like heart failure, where first-degree block correlates with increased symptom burden.^[3]^[30]^[6] These manifestations are not directly attributable to the block in isolation but often reflect associated hemodynamic compromise or progression toward higher-degree block; isolated first-degree block rarely requires intervention based on symptoms alone.^[1]^[3] Evaluation for reversible causes, such as medications or electrolyte imbalances, is essential in symptomatic cases to distinguish conduction delay from more severe pathology.^[1]

Asymptomatic variants

First-degree atrioventricular block is frequently asymptomatic and identified incidentally during routine electrocardiography in patients lacking complaints of palpitations, fatigue, dizziness, or syncope. The conduction delay manifests as a PR interval prolonged beyond 200 milliseconds, with consistent atrioventricular synchrony preserved, distinguishing it from higher-degree blocks. In otherwise healthy individuals, particularly young adults and endurance athletes, this variant often reflects physiological enhancement of vagal tone at the atrioventricular nodal level, with prevalence reaching approximately 8.7% among trained athletes.^[3]^[10] Such cases typically show normal QRS morphology, indicating nodal rather than infranodal delay, and impose no immediate functional limitations.^[1] Although devoid of overt symptoms, asymptomatic first-degree block with marked PR prolongation exceeding 300 milliseconds may subtly impair atrial contribution to ventricular filling, potentially contributing to exercise intolerance under stress, though patients remain unaware without targeted testing. Long-term cohort data from the Framingham Heart Study reveal that even asymptomatic isolated cases carry elevated risks, including a twofold increase in atrial fibrillation incidence, a threefold higher likelihood of eventual pacemaker implantation, and a 1.4-fold rise in all-cause mortality, with each 20-millisecond PR increment correlating to hazard ratios of 1.11 for atrial fibrillation, 1.22 for pacing, and 1.08 for death.^[3]^[1] Progression to advanced block remains uncommon in isolated nodal variants without structural heart disease.^[3] Guidelines from the American College of Cardiology, American Heart Association, and Heart Rhythm Society emphasize that asymptomatic first-degree atrioventricular block requires no therapeutic intervention, such as pacing, due to its generally benign course and the risks of unnecessary procedures. Periodic electrocardiographic surveillance is advised to monitor for progression, particularly in older patients or those with PR intervals over 300 milliseconds, while evaluation for reversible etiologies like medications or electrolyte imbalances should precede dismissal as purely physiological.^[31] In athletes, reassurance suffices if no underlying pathology is evident, permitting full participation in competitive sports when PR remains below 300 milliseconds.^[32]

Diagnosis

Primary diagnostic criteria

First-degree atrioventricular block is defined electrocardiographically by a prolonged PR interval greater than 200 milliseconds (ms), measured from the onset of the P wave to the onset of the QRS complex, with consistent 1:1 atrioventricular conduction such that every P wave is followed by a QRS complex without dropped beats.^[1] The normal PR interval in adults ranges from 120 to 200 ms at a standard heart rate; prolongation beyond this threshold indicates delayed conduction through the AV node or His-Purkinje system without progression to higher-degree block.^[3] This criterion is established via a standard 12-lead ECG, which remains the gold standard for diagnosis due to its ability to precisely quantify conduction timing.^[10] A "marked" first-degree AV block is specified when the PR interval exceeds 300 ms, potentially leading to P waves overlapping with preceding T waves and increasing clinical scrutiny, though the primary diagnostic threshold remains 200 ms.^[2] Diagnosis requires confirmation that the prolongation is consistent across multiple beats and not attributable to artifacts or rate-dependent variations, with repeat ECGs recommended if initial findings are borderline.^[1] Ambulatory monitoring may supplement if intermittent conduction delay is suspected, but the defining feature is the fixed PR prolongation on resting ECG.^[3]

Differential diagnosis and confirmatory tests

The differential diagnosis for first-degree atrioventricular block encompasses higher-degree atrioventricular blocks (second- or third-degree), atrioventricular dissociation, and conditions simulating conduction delay such as concealed His bundle extrasystoles or nonconducted premature atrial contractions that may artifactually prolong the apparent PR interval.^[1] Reversible extrinsic factors must also be excluded, including medication effects (e.g., beta-blockers, calcium channel blockers, or digoxin), electrolyte imbalances (e.g., hyperkalemia), acute myocardial ischemia, increased vagal tone, Lyme carditis, or drug toxicity, which can mimic intrinsic disease but resolve upon correction.^[31] ^[1] Intrinsic causes like degenerative conduction system fibrosis or infiltrative cardiomyopathies require differentiation via clinical context and imaging, as they portend progression risk unlike benign variants in athletes or youth.^[31] Diagnosis is confirmed primarily by 12-lead electrocardiography demonstrating a PR interval exceeding 200 milliseconds (0.20 seconds) with preserved 1:1 atrioventricular conduction, where every P wave is followed by a QRS complex; intervals greater than 300 milliseconds denote marked delay.^[31] ^[2] Ambulatory electrocardiographic monitoring (e.g., 24- to 48-hour Holter or longer-term event recorders) verifies persistence, correlates intermittent symptoms like fatigue or syncope with rhythm disturbances, and detects progression to advanced block.^[31] Echocardiography evaluates for structural abnormalities such as cardiomyopathy, valvular disease, or wall motion issues contributing to conduction delay.^[31] Exercise stress testing assesses rate-dependent conduction changes, particularly in symptomatic patients, while invasive electrophysiologic studies localize the delay site (e.g., AV node versus His-Purkinje system) in cases with wide QRS or unclear etiology.^[31] ^[1] Laboratory tests screen for reversible contributors, including electrolytes, Lyme serology, and drug levels.^[31]

Management

Non-interventional approaches

In asymptomatic patients with isolated first-degree atrioventricular block, no specific intervention is required, with management centered on clinical observation and periodic electrocardiographic monitoring to detect progression to higher-degree block or associated conduction abnormalities.^[1]^[31] The 2018 ACC/AHA/HRS guidelines classify permanent pacing as inappropriate (Class III recommendation) for asymptomatic first-degree AV block without evidence of additional atrioventricular delay or symptoms attributable to bradycardia.^[31] Similarly, the 2013 ESC guidelines on cardiac pacing regard isolated first-degree AV block as a benign entity not warranting pacing unless hemodynamic compromise is evident.^[33] Patient education forms a key component, emphasizing recognition of potential symptoms such as fatigue, dizziness, or syncope that might signal progression or underlying pathology, prompting prompt reevaluation.^[34] Avoidance of exacerbating factors, including medications that prolong atrioventricular conduction (e.g., beta-blockers, non-dihydropyridine calcium channel blockers, or digoxin), is advised when feasible, particularly in patients with borderline PR intervals exceeding 300 ms, where symptoms may emerge during exertion.^[3] Lifestyle modifications, such as reducing vagal stimuli in cases linked to high athletic training, may be considered, though evidence for routine deconditioning is limited to observational data in select cohorts.^[34] Follow-up intervals vary based on risk factors; asymptomatic individuals without structural heart disease may require only annual clinical assessment, whereas those with comorbidities or marked PR prolongation (>0.30 seconds) warrant more frequent ECGs (e.g., every 6-12 months) to monitor for evolution into Mobitz type I or II block.^[35] Long-term telemetry or ambulatory monitoring is not routinely indicated for stable, asymptomatic cases, as progression rates remain low (approximately 1-2% per year in population studies).^[31] This conservative approach aligns with the low prognostic impact of isolated first-degree AV block in the absence of symptoms or myocardial disease.^[1]

Pharmacologic and procedural interventions

Pharmacologic interventions for first-degree atrioventricular (AV) block are generally limited, as the condition is often benign and self-resolving without specific therapy. Treatment emphasizes discontinuation of medications that prolong AV conduction, such as beta-blockers, non-dihydropyridine calcium channel blockers (e.g., verapamil, diltiazem), digoxin, and certain antiarrhythmics (e.g., amiodarone), particularly in symptomatic patients where these agents may contribute to or worsen the delay.^[36] ^[1] Correction of reversible extrinsic factors, including electrolyte imbalances (e.g., hyperkalemia or hypokalemia), hypothyroidism, or acute infections like Lyme disease (treated with antibiotics such as ceftriaxone), can normalize conduction without targeted AV nodal drugs.^[1] ^[34] No pharmacologic agents are routinely recommended to shorten the PR interval in isolated cases, as evidence for agents like atropine or isoproterenol is limited to acute, symptomatic bradycardia scenarios rather than chronic first-degree block.^[34] Procedural interventions are reserved for rare symptomatic cases unresponsive to conservative measures. Permanent pacemaker implantation is not indicated for asymptomatic first-degree AV block, per the 2018 ACC/AHA/HRS guidelines (Class III recommendation, level of evidence B).^[31] ^[36] However, it is reasonable (Class IIa) for marked first-degree AV block (PR interval >0.30 seconds) with documented symptoms attributable to bradycardia, such as fatigue, syncope, or heart failure exacerbation, especially if temporary atrial pacing alleviates symptoms or if associated with neuromuscular disorders like myotonic dystrophy that increase progression risk.^[31] ^[37] Temporary transvenous pacing may be employed in acute settings with hemodynamic instability, but its use should be minimized to reduce risks like infection or thrombosis.^[34] Electrophysiologic studies are occasionally performed to assess for infra-Hisian conduction disease but do not routinely guide intervention in first-degree block.^[36]

Prognosis

Natural history and outcomes

First-degree atrioventricular (AV) block, characterized by a prolonged PR interval exceeding 200 milliseconds without dropped beats, typically exhibits a stable natural history in asymptomatic individuals lacking structural heart disease. Longitudinal follow-up of patients with isolated primary first-degree AV block demonstrates minimal progression to higher-degree blocks, with advancement to second- or third-degree AV block occurring in fewer than 5% of cases over mean follow-up periods of 10 to 20 years.^[38] In the absence of symptoms or comorbidities, conduction remains unchanged in the majority, often reflecting enhanced vagal tone rather than intrinsic disease.^[1] Population-level data, however, reveal associations with adverse outcomes even in ostensibly isolated cases. Analysis from the Framingham Heart Study, involving over 7,000 participants followed for up to 18 years, found that a prolonged PR interval conferred adjusted hazard ratios of 2.06 (95% CI, 1.36-3.12) for atrial fibrillation, 3.20 (95% CI, 1.83-5.59) for pacemaker implantation, and 1.38 (95% CI, 1.11-1.72) for all-cause mortality, independent of traditional risk factors like age and hypertension.^[39] Similar findings from other cohorts link first-degree AV block to heightened risks of heart failure hospitalization (HR 1.69) and sudden cardiac death, though absolute event rates remain low (e.g., annual AF incidence ~1-2%).^[6] Prognosis worsens with advancing age, symptoms such as fatigue or syncope, or underlying pathology like myocardial infarction or degenerative conduction disease, where infra-Hisian delays predominate and progression rates may exceed 10-20% over 5-10 years.^[1] In contrast, first-degree AV block in young athletes or those with high vagal tone often resolves with deconditioning and carries negligible long-term risk.^[40] Overall mortality in uncomplicated cases approximates age-matched norms, underscoring that while relative risks exist, clinical significance hinges on context and serial monitoring.^[41]

Factors influencing progression

Progression from first-degree atrioventricular (AV) block to higher-grade blocks, such as second- or third-degree AV block, is uncommon in otherwise healthy individuals without structural heart disease, with studies indicating low annual rates of advancement in asymptomatic cases.^[42]^[3] However, specific electrocardiographic and clinical factors can elevate the risk, particularly when the block involves infranodal conduction pathways rather than the AV node alone, as infranodal delays are associated with greater potential for decompensation.^[3] Marked prolongation of the PR interval, defined as exceeding 300 ms, serves as a predictor of progression to complete AV block, potentially due to cumulative conduction system fibrosis or ischemia compromising reserve capacity.^[43] Coexisting abnormalities, including bundle branch block or widened QRS duration, further compound this risk by indicating multifocal disease within the His-Purkinje system, which impairs compensatory mechanisms and correlates with adverse remodeling.^[44] Advanced age amplifies progression likelihood through degenerative changes like Lenègre's disease, involving progressive sclerosis of the conduction fibers, independent of symptoms at initial presentation.^[1] Underlying structural heart conditions, such as coronary artery disease or hypertrophic cardiomyopathy, promote progression by inducing ischemia or myocardial infiltration that extends conduction delays into intermittent failure, with cohort data showing heightened rates of pacemaker requirement in these settings.^[39]^[12] Comorbid metabolic factors, including hypertension and hyperglycemia, contribute via endothelial dysfunction and fibrotic cascades affecting nodal tissue, accounting for a substantial portion of AV block escalations in population studies.^[45] Monitoring via insertable cardiac monitors has revealed subclinical progression in up to 53% of select cases, underscoring the need for serial assessment in high-risk profiles rather than assuming benignity.^[46]

Special Considerations and Controversies

Implications for high-risk occupations

Asymptomatic first-degree atrioventricular (AV) block, characterized by a prolonged PR interval typically between 200-300 ms without dropped beats, generally does not impose restrictions on high-risk occupations such as commercial piloting or driving, provided there are no associated symptoms like syncope or evidence of progression to higher-degree block.^[47] ^[48] In aviation, the Federal Aviation Administration (FAA) mandates submission of a Holter monitor and comprehensive cardiac evaluation for pilots with a PR interval of 300 ms or greater, but certification is often granted if the block normalizes with exercise and no structural heart disease is present, as this variant poses minimal risk of incapacitation.^[47] ^[49] Similarly, aviation authorities like the Civil Aviation Authority of New Zealand consider first-degree AV block non-disqualifying if it resolves during stress testing, reflecting its frequent physiologic occurrence in healthy individuals without causal link to sudden events.^[49] For commercial driving, guidelines from bodies such as the Canadian Cardiovascular Society permit unrestricted operation for private vehicles with isolated first-degree AV block, while commercial licensing requires confirmation of asymptomatic status and absence of conduction system disease, with no mandatory waiting period unless symptoms like dizziness occur.^[50] ^[51] The Canadian Medical Association's driver's guide echoes this, imposing no limitations for first-degree AV block even when combined with bifascicular block, absent impaired consciousness or ventricular dysfunction.^[52] In contrast, symptomatic cases or those with PR prolongation exceeding physiological norms may trigger temporary suspension until electrophysiological evaluation rules out progression risk, as longitudinal data indicate a modest association with future heart failure or pacemaker need, though causality remains unestablished in isolated instances.^[53] Occupational health assessments for roles like firefighting or military aviation prioritize individualized risk stratification over blanket disqualification, often involving exercise stress testing and echocardiography to differentiate benign vagally mediated delays from pathologic conduction slowing.^[54] Recent FAA policy updates in 2023 expanded acceptable PR intervals for pilots, previously flagged as first-degree block, underscoring empirical evidence that such findings rarely precipitate acute incapacitation in otherwise healthy candidates.^[55] Nonetheless, ongoing monitoring is recommended, as epidemiological studies link prolonged PR to elevated long-term cardiovascular mortality, necessitating periodic reevaluation to mitigate rare progression in safety-critical professions.^[39]

Relevance in athletic populations

First-degree atrioventricular block is observed more frequently in athletic populations than in the general population, with a prevalence of up to 8.7% on resting electrocardiograms in trained athletes compared to approximately 4% overall.^[3]^[42] This elevated rate stems from physiological adaptations to chronic endurance training, including enhanced parasympathetic (vagal) tone that prolongs atrioventricular nodal conduction time without underlying structural disease.^[56]^[57] The phenomenon correlates with training intensity and duration, often manifesting as part of "athlete's heart" syndrome alongside sinus bradycardia.^[56] Ambulatory Holter monitoring reveals even higher transient occurrences, present in 27.5–40% of athletes during rest, reflecting dynamic vagal influences that normalize with exercise.^[58] In contrast, the incidence is lower in pediatric and adolescent athletes, around 1%, increasing with age and training volume in adults.^[16] These findings are typically asymptomatic and benign, distinguishing them from pathological causes through exercise testing, where the PR interval shortens or normalizes, confirming reversibility with detraining in many cases.^[59]^[56] Clinically, first-degree AV block in athletes does not generally warrant restriction from sports participation or intervention absent symptoms like fatigue, syncope, or progression to higher-degree block, as longitudinal data indicate low risk of adverse outcomes in this context.^[42]^[60] Preparticipation screening ECGs may flag it as a normal variant, but echocardiography and Holter monitoring help exclude cardiomyopathy or other etiologies, emphasizing context over isolated PR prolongation.^[61] Rare profound cases (PR >300 ms) have been reported in elite athletes, yet remain training-induced without necessitating pacemaker implantation.^[62]

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Sep 27, 2024 · Conclusion: To conclude, older age, male sex, white population, overweight, combined diabetes or chronic kidney disease, impaired FVC, elevated ...Missing: demographic | Show results with:demographic
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Familial risk of atrioventricular block in first-degree relatives - Heart
A family history of AVB is associated with an increased risk of AVB among first-degree relatives with the risk being strongly associated with age of the index ...Missing: demographic | Show results with:demographic
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Risk Factors Associated With Atrioventricular Block - PMC
May 24, 2019 · Population-attributable risk calculations suggest that elevated blood pressure and glucose levels may be associated with more than half of all ...
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Progressive familial heart block - Genetics - MedlinePlus
Progressive familial heart block is a genetic condition that alters the normal beating of the heart. A normal heartbeat is controlled by electrical signals ...
[24]
Hereditary progressive cardiac conduction defect - Orphanet
A genetic cardiac rhythm disease that may progress to complete atrioventricular (AV) block. The disease is either asymptomatic or manifests as dyspnea, ...
[25]
Drug-Induced Arrhythmias: A Scientific Statement From the ...
Sep 15, 2020 · Consequently, atrioventricular node–blocking drugs should be prescribed when flecainide or propafenone is used in patients with AFL. Amiodarone ...
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First degree atrioventricular block - PubMed
... electrolyte imbalances, and many other miscellaneous causes. Isolated first degrees atrioventricular block is generally not associated with an increased ...
[27]
Atrioventricular block: Video & Meaning | Osmosis
Some important physiologic and reversible causes of AV block include increased vagal tone, as seen in endurance athletes and individuals with obstructive sleep ...
[28]
Reversible atrioventricular block and the importance of close follow-up
We report two cases of Lyme carditis-induced AV block that were successfully managed and reversed with temporary cardiac pacing and antibiotics.
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First-degree atrioventricular block. Clinical manifestations ... - PubMed
Marked first-degree AV block (PR> or =0.30 s) can produce a clinical condition similar to that of the pacemaker syndrome.
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Marked first-degree AV block may lead to complete AV block ... - NIH
May 24, 2023 · Marked first-degree AV block with a PR > 300 ms may lead to symptoms such as fatigue, poor exercise tolerance and palpitations.Missing: clinical | Show results with:clinical
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2018 ACC/AHA/HRS Guideline on the Evaluation and Management ...
Nov 6, 2018 · However, in some patients, severe first-degree atrioventricular block can cause symptoms similar to pacemaker syndrome, as well as heart failure ...<|separator|>
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Eligibility and Disqualification Recommendations for Competitive ...
Nov 2, 2015 · Asymptomatic athletes with no structural heart disease and first-degree AV block (PR interval <0.3 ms) can participate in all competitive ...
[33]
2013 ESC Guidelines on cardiac pacing and ... - Oxford Academic
Jun 24, 2013 · 4.7 Pacing for first-degree atrioventricular block (haemodynamic). First degree AV (1st AV) block is commonly considered a benign condition.
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Atrioventricular Block - StatPearls - NCBI Bookshelf
Feb 12, 2024 · Atrioventricular block represents a delay or disturbance in the transmission of an impulse from the atria to the ventricles.Atrioventricular Block · Evaluation · Review Questions
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Atrioventricular Block Treatment & Management
Jul 13, 2022 · Patients with asymptomatic first-degree or Mobitz I atrioventricular (AV) block do not require long-term monitoring with repeated rhythm strips/ ...Approach Considerations · Consultations · Pacemaker ImplantationMissing: non- | Show results with:non-
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Jun 19, 2024 · In general, no treatment is indicated for asymptomatic isolated first-degree atrioventricular (AV) heart block.Missing: variants | Show results with:variants
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[PDF] 2018 Guideline on the Evaluation and Management of Patients With ...
In the evaluation of patients with asymptomatic sinus bradycardia or first degree AV block and no clinical evidence of structural heart disease, routine ...
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The Natural History of Primary First-Degree Atrioventricular Heart ...
Nov 6, 1986 · The long-term prognosis of first-degree heart block in the absence of organic heart disease has not been clearly defined.Missing: studies | Show results with:studies
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Long-term Outcomes in Individuals With Prolonged PR Interval or ...
Jun 24, 2009 · To investigate the prognosis associated with first-degree AVB, we prospectively examined the associations of electrocardiographic PR interval ...
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Profound First-Degree Atrioventricular Block in a High-Level ... - NIH
Nov 9, 2023 · One common conduction abnormality in athletes is first-degree atrioventricular (AV) block (PR interval >200 ms). The prevalence of first-degree ...
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Long-term outcomes in individuals with prolonged PR interval or first ...
Jun 24, 2009 · Prolongation of the PR interval is associated with increased risks of AF, pacemaker implantation, and all-cause mortality.<|control11|><|separator|>
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Outcomes Related to First-Degree Atrioventricular Block and ...
The prevalence of first-degree atrioventricular block in the general population is approximately 4%, and it is associated with an increased risk of atrial ...
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(PDF) Marked first-degree AV block may lead to ... - ResearchGate
May 25, 2023 · Prolonged HV interval > 70 ms is predictive of higher-grade AV block development. Marked first-degree AV block with a PR > 300 ms may lead to ...<|separator|>
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Oct 16, 2025 · No specific treatment is required for isolated first-degree AV block in asymptomatic patients 1 · Regular cardiac follow-up with periodic ECG ...
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Risk Factors Associated With Atrioventricular Block - JAMA Network
May 24, 2019 · These results suggest that elevated blood pressure and blood glucose level may be associated with more than half of all cases of AV block. Our ...
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"First-degree AV block-a benign entity?" Insertable cardiac monitor ...
A few recent studies have shown that 1st-degree AV block is associated with an increased risk for heart failure, pacemaker (IPG) implantation, and death.
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FAA Guide for Aviation Medical Examiners
Mar 27, 2024 · 1st Degree AV Block with PR interval of 300 ms or MORE, All, Submit the following: A current Holter and cardiac evaluation ; 2nd Degree AV Block
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Arrhythmias, Sudden Cardiac Death and incapacitation of pilots - PMC
First degree AV block and second degree Mobitz I are not disqualifying. Second degree Mobitz II and third degree AV block are disqualifying. Individuals ...
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Atrio-ventricular block (AV block) | aviation.govt.nz - CAA
An applicant presenting with a first degree AV block that normalises [<200 ms] during exercise may be considered as having a condition that is not of ...
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2. Driving: Cardiac Rhythm, Arrhythmia Device and Procedures
Atrioventricular (AV) and Intraventricular Block. Isolated first degree AV block. Private driving is permitted with no restriction. Commercial driving is ...
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Driving Guidelines for Arrhythmia/Syncope - Cardio Guide
Sep 1, 2024 · First-degree AV block and bifascicular block. No restriction if no impaired level of consciousness ; Second-degree AV block; Mobitz II.
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Section 14 Cardiovascular diseases - CMA Driver's Guide
First-degree AV block + bifascicular block, No restriction if no impaired ... Patients with congenital third-degree atrioventricular block may require a driving ...
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First-degree atrioventricular block is associated with heart failure ...
May 23, 2011 · Recently, the Framingham group reported that first-degree AVB portended an increased risk for atrial fibrillation, pacemaker implantation, and ...
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Pilot Cardiac Evaluation For Fitness for Duty - StatPearls - NCBI - NIH
Sep 26, 2022 · Common training-related ECG findings were sinus bradycardia, first-degree atrioventricular block, and incomplete right bundle branch block.Missing: implications | Show results with:implications
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ICAN Threatens FAA With Legal Action Over Change in Pilot Heart ...
Feb 10, 2023 · The new parameters accept PR interval echocardiogram readings that had previously been considered indicative of a “first degree heart block.” PR ...
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Intrinsic Electrical Remodeling Underlies Atrioventricular Block in ...
Apr 14, 2021 · We conclude that electrical remodeling is a key mechanism underlying atrioventricular block in athletes.Missing: etiology | Show results with:etiology
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A Patient With Athlete's Heart Syndrome: When the Abnormal Is ...
Mar 14, 2024 · A common conduction abnormality in this population is sinus bradycardia, often coinciding with a first-degree atrioventricular (AV) block.<|separator|>
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Symptomatic bradyarrhythmias in the athlete—Underlying ...
Feb 28, 2024 · In 24-hour Holter recordings, first-degree AV block is present in up to 27.5%–40% of athletes while type I second-degree block is present in 15% ...
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A case report of profound atrioventricular block in an endurance ...
May 2, 2022 · First-degree atrioventricular block (AVB) is a common training-related change, found in up to 7.5% of athletes on a resting electrocardiogram ( ...
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Abnormal electrocardiogram findings in athletes - Oxford Academic
Sep 25, 2025 · First-degree atrioventricular block (AVB) is considered a common ECG finding in competitive athletes. Its prevalence increases with age (from ...
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Prevalence and relation to training of electrocardiographic findings ...
A heart rate of 50–55 b.p.m., first-degree atrioventricular block, right-axis deviation, and T-wave inversion in V1–V3 in athletes 12- to 16-year-old were ...
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Profound First-Degree Atrioventricular Block in a High-Level ...
Nov 9, 2023 · Profound First-Degree Atrioventricular Block in a High-Level Basketball Athlete ... athletes and military members: a systematic review and ...