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Atrioventricular (AV) conduction is evaluated by assessing the relationship between the P waves and QRS complexes. Normally, a P wave precedes each QRS complex, with a fixed PR interval of 120 to 200 milliseconds. Atrioventricular block represents a delay or disturbance in the transmission of an impulse from the atria to the ventricles. This can be due to an anatomical or functional impairment in the heart’s conduction system. This activity describes the causes and pathophysiology of AV block, discusses the evaluation of patients with atrioventricular block, and highlights the interprofessional team's role in managing these patients. Objectives: Identify the signs and symptoms associated with atrioventricular block to facilitate early recognition and diagnosis. Differentiate between different degrees of atrioventricular block (first, second, and third degree) based on ECG findings and clinical presentation. Apply evidence-based treatment strategies for atrioventricular block, including medication management, temporary or permanent pacemaker implantation, and other interventional procedures when indicated. Collaborate with cardiology specialists and other healthcare professionals to develop a comprehensive care plan for patients with atrioventricular block, considering their unique clinical circumstances and comorbidities. Access free multiple choice questions on this topic.

The cardiac conduction system is formed by specialized fibers that initiate electrical impulse and conduct it through the heart's chambers. The human heart's dominant pacemaker is the sinus node, which generates an impulse to depolarize the atria and ventricles. The impulse the sinus node generates spreads to the atria and atrial depolarization, or contraction, occurs. This action is marked by the P wave on a surface electrocardiogram (ECG). After atrial depolarization, the wave of depolarization transfers to the ventricles via the atrioventricular (AV) conduction system. QRS marks ventricular depolarization on a surface ECG.[1] The AV conduction system consists of an AV node and specialized conduction fibers forming the His-Purkinjie system.[2] The autonomic nervous system supplies the AV conduction system, particularly the AV node, resulting in variable conduction during various physiological states.[3] AV conduction is evaluated by assessing the relationship between the P waves and QRS complexes. Typically, a P wave precedes each QRS complex by a fixed PR interval of 120 to 200 milliseconds.[4] An AV block represents a delay or disturbance in the transmission of an impulse from the atria to the ventricles. This can be due to an anatomical or functional impairment in the heart's conduction system.[5] An AV block can manifest as either temporary or permanent, and its severity determines its classification into three types: first-degree, second-degree, and third-degree AV block. Anatomically, an AV block is classified as either a supra (nodal) or intra/infra-His (infranodal) block.[6] Infranodal blocks commonly present with a wide QRS complex, progress to the third-degree AV block, and require pacemakers.[7]

An AV block could be congenital or acquired. Congenital AV block can be associated with congenital heart diseases, including AV canal defects, transposition of great arteries, heterotaxy syndrome, left atrial isomerism, and tetralogy of Fallot.[8][9] Congenital AV block without structural heart disease, is relatively more common than those associated with congenital heart disease. Immune-mediated conduction system dysfunction is the main reason for congenital AV block in patients without congenital heart disease.[10] Systemic lupus erythematosus is one of the common autoimmune diseases associated with congenital AV block.[11] Maternal viral infection is another cause of congenital AV block in offspring.[12] Myocardial ischemia/infarction, drugs, electrolyte abnormalities, endocrine disorders, and toxins cause acquired AV block. However, age-related degeneration of conduction system diseases is the most common cause of acquired AV block.[13] About half of such cases result from chronic idiopathic fibrosis and sclerosis of the conduction system, as seen in Lenègre disease and Lev disease.[14][15] Higher vagal tone also causes AV block, especially in young individuals. The vagally mediated AV block is nodal in origin; it is benign and rarely requires pacemaker implantation.[16] Some atrial cardiomyopathies and muscular dystrophies also lead to bradyarrhythmias and AV blocks.[17][18] The other causes of acquired AV block include infiltrative cardiomyopathies, myocarditis, Lyme disease, rheumatic fever, and endocarditis. Cardiac surgery is also a risk factor for developing an AV block, and aortic and valve surgeries are commonly associated with an AV block due to its proximity to the conduction system.[19] Transcatheter aortic valve replacement is also found to be associated with an AV block. Male patients have a higher incidence of an AV block after transcatheter aortic valve replacement, especially in the presence of underlying conduction system diseases.[20]

The precise prevalence of AV blocks remains unknown due to the absence of extensive population-based studies focusing specifically on their occurrence. The estimated occurrence of autoantibody-mediated congenital AV block is approximately 1 in 15,000 births. However, it is important to note that the actual incidence may be underestimated due to cases resulting in intrauterine deaths.[21] An AV block due to degeneration of cardiac conduction tissue is much more common in individuals older than 65. In contrast, the prevalence of third-degree AV block is rare in young individuals.[13]  However, one study suggested that first-degree AV block is more prevalent in African-American patients than Caucasian patients in all age groups except in the eighth decade of life.[22] However, at this time, there is no well-characterized large study about the correlation between different types of AV block with age, race, or gender.

Congenital AV block mediated by the immune system results from the transfer of maternal antibodies (anti-Ro and anti-La) across the placenta into the fetal circulation. These antibodies bind to fetal myocytes and impair cytoplasmic calcium metabolism leading to apoptotic cell death in the conduction system tissues.[10] The result of this immune-mediated process is the fibrosis of the cardiac conduction system and surrounding myocardium.[23] The presence of congenital AV block in individuals with congenital structural heart diseases can be attributed to abnormal development of the central fibrous body and abnormal development or disruption of the AV conduction tissue.[8] Acquired AV block in older individuals is characterized by degeneration and fibrosis of the His-Purkinje system. Age-related degeneration is a chronic process commonly involving the intra/infra-His conduction system, and most patients require pacemaker implantation.[24] AV blocks occurring after cardiac surgery and transcatheter aortic valve replacement are primarily caused by the mechanical effects exerted on the surrounding conduction system.[19][25]

History History taking for patients with concerns for an AV block should include: [28] History of heart disease, both congenital and acquired Complete list of medications and dosing. Particular drugs of interest include beta-blockers, calcium channel blockers, antiarrhythmic drugs, digoxin Recent cardiac procedure Signs and symptoms associated with other systemic diseases associated with heart block (amyloidosis, sarcoidosis) Baseline exercise capacity Potential exposure to tick bites Patients with first and Mobitz type I, second-degree AV blocks are usually asymptomatic and diagnosed incidentally on examination or a 12-lead ECG. Patients with an AV block commonly present with symptoms such as dyspnea on exertion, easy fatigability, dizziness, and syncope. However, it is rare for them to exhibit cardiac arrest or experience sudden cardiac death.[29] Physical Exam Although a physical exam has a limited role in diagnosing an AV block, it is essential to assess underlying structural heart diseases and evaluate the hemodynamic consequences of an AV block.[30] Physical examination findings in cases of an AV block typically include bradycardia, an irregular pulse, hypotension, and the presence of distended neck veins characterized by prominent A waves.[31]

Classification of Atrioventricular Block First-degree Atrioventricular Block. First-degree AV block is a 1:1 association between P waves and QRS (1:1 AV conduction) and a constant PR interval of >200 ms. The condition is more accurately defined as an AV delay because no P waves are blocked.[32] In the first-degree AV block, the P waves always precede the QRS complexes, but the PR interval is prolonged without any dropped beats. (Figure.1) In other words, while the impulse is slowed, it can still reach the ventricles. The delay is typically due to a minor AV conduction defect occurring at or below the AV node. If the PR interval is more than 300 milliseconds, it is considered a “marked” first-degree AV block, and the P waves may be buried in the preceding T wave.[33] Second-degree Atrioventricular Block. Second-degree or incomplete AV block occurs when there is intermittent AV conduction. Second-degree AV blocks can be further classified into Mobitz type 1 (Wenckebach) or Mobitz type 2, which can be distinguished by examining the PR interval. Second degree, Mobitz type I (Wenckebach). AV block is characterized by P waves exhibiting a consistent rate (<100 bpm) and a gradual prolongation of the PR interval. This is followed by periodic occurrences of single non-conducted P waves, typically accompanied by P waves preceding and following the non-conducted P waves. (Figure.2) Wenckebach is a phenomenon commonly associated with the AV nodes; however, there are reported cases of Wenckebach associated with infra-nodal AV block.[34] Second degree, Mobitz type II. AV block is characterized by P waves occurring at a constant rate (<100 bpm) and periodic single non-conducted P waves that arise at unpredictable intervals. These non-conducted P waves are typically observed alongside other P waves, both before and after the non-conducted P wave, and exhibit consistent PR intervals.[35] Conduction of at least two consecutive P waves is required to differentiate Wenckebah from Mobitz type 2 AV block. (Figure.3) When every other P wave is blocked (not conducted), it is impossible to differentiate between Wenckebach and Mobitz type II AV block, so this entity is called a 2:1 AV block.[36]

Second degree, Mobitz type II. AV block is characterized by P waves occurring at a constant rate (<100 bpm) and periodic single non-conducted P waves that arise at unpredictable intervals. These non-conducted P waves are typically observed alongside other P waves, both before and after the non-conducted P wave, and exhibit consistent PR intervals.[35] Conduction of at least two consecutive P waves is required to differentiate Wenckebah from Mobitz type 2 AV block. (Figure.3) When every other P wave is blocked (not conducted), it is impossible to differentiate between Wenckebach and Mobitz type II AV block, so this entity is called a 2:1 AV block.[36] Second degree, high-grade. Advanced (high-grade) AV block is defined as the presence of ≥2 consecutive, non-conducted P waves occurring at a constant physiologic rate, along with evidence of AV conduction (manifesting as AV association). (Figure.4) Third-degree (complete). AV conduction is absent in third-degree or complete heart block, and the P waves are never related to the QRS complexes. In other words, the supraventricular impulses generated do not conduct to the ventricles. Instead, if ventricular conduction occurs, it is maintained by a junctional or ventricular escape rhythm.[29] There is a complete dissociation between the atria and ventricles. The atria and ventricles conduct independently of each other. The P waves (atrial activity) are said to “march through” the QRS complexes at their regular, faster rate. The QRS complexes (ventricular activity) also occur at a regular but slower rate. Two independent rhythms occur simultaneously. (Figure.5) Evaluation of Patients with Atrioventricular Block

Third-degree (complete). AV conduction is absent in third-degree or complete heart block, and the P waves are never related to the QRS complexes. In other words, the supraventricular impulses generated do not conduct to the ventricles. Instead, if ventricular conduction occurs, it is maintained by a junctional or ventricular escape rhythm.[29] There is a complete dissociation between the atria and ventricles. The atria and ventricles conduct independently of each other. The P waves (atrial activity) are said to “march through” the QRS complexes at their regular, faster rate. The QRS complexes (ventricular activity) also occur at a regular but slower rate. Two independent rhythms occur simultaneously. (Figure.5) Evaluation of Patients with Atrioventricular Block Non-Invasive Evaluation. A resting 12 lead ECG is essential for evaluating patients with a suspected AV block. It helps assess the severity of an AV block, localize the site of the AV block, and provide information about the associated structural heart diseases. However, a 12-lead ECG may not always provide a direct correlation between the observed symptoms and the presence of an AV block.[37] Ambulatory ECG monitoring is considered a superior diagnostic tool to establish a more accurate correlation between symptoms and an AV block. It offers a higher diagnostic yield for identifying a paroxysmal AV block, thereby aiding in the accurate diagnosis of this condition.[38] An exercise ECG may be considered in selective individuals to assess the exercise-induced AV block and localize the site of the block in patients with 2:1 AV block.[39] Echocardiogram is recommended in every patient with an AV block to exclude structural heart diseases. Cardiac magnetic resonance imaging (cMRI) can be considered in selective individuals suspected of AV blocks due to myocarditis or infiltrative cardiomyopathies.[40] Screening and testing for sleep apnea are recommended in patients with sleep-related AV block to provide proper treatment. Invasive Evaluation: Routine invasive evaluation is not recommended for an AV block. In cases where initial non-invasive investigations fail to provide a definitive diagnosis, patients experiencing symptoms related to bradycardia should be considered for an implantable loop recorder or an electrophysiology study.[41][42]

Invasive Evaluation: Routine invasive evaluation is not recommended for an AV block. In cases where initial non-invasive investigations fail to provide a definitive diagnosis, patients experiencing symptoms related to bradycardia should be considered for an implantable loop recorder or an electrophysiology study.[41][42] Laboratory Investigations: Selected laboratory investigations, including thyroid function tests, electrolyte levels, renal profile, and digoxin levels, should be checked in patients presenting with an AV block if indicated based on clinical evaluation. Genetic testing may be considered in patients with inherited AV blocks, followed by cascade screening and genetic counseling.[43]

In most cases, asymptomatic patients with first-degree or second-degree Mobitz type 1 atrioventricular block do not necessitate treatment. However, it is crucial to discontinue any medications triggering the AV block and address any reversible factors contributing to its occurrence. Patients can be monitored on an outpatient basis. However, patients with higher degrees of an AV block (Mobitz type 2 AV block, 3rd degree) tend to have severe damage to the conduction system. They are usually at a greater risk of progressing into asystole, ventricular tachycardia, or sudden cardiac death. Hence, they require urgent admission for cardiac monitoring and further evaluation.[26][28] Use of an urgent or emergent temporary transvenous pacemaker should not be a "knee-jerk" reaction to the presence of a second-degree, high grade or third-degree AV block. It should be carefully considered after evaluating the risk-benefit ratio in clinical settings. Factors such as hemodynamic stability, including the assessment of systolic blood pressure and the severity and duration of the patient's clinical symptoms, should be considered. Additionally, the level of an AV block and the presence of an appropriate escape rhythm should be considered before making a decision.[44] Acute Management of Atrioventricular Block Patients with suspected reversible causes of an AV block, such as digoxin toxicity, Lyme myocarditis, or an overdose of AV node-blocking drugs, often require medical therapy. This may involve administering specific reversal agents or targeted treatments to address the underlying cause and restore normal AV conduction. Intravenous atropine should be considered as initial therapy when the AV block is suspected to be supra-Hisian. Dopamine and isoproterenol can be used in symptomatic patients with second or third-degree AV block with evidence of acute myocardial ischemia.[45]

Patients with suspected reversible causes of an AV block, such as digoxin toxicity, Lyme myocarditis, or an overdose of AV node-blocking drugs, often require medical therapy. This may involve administering specific reversal agents or targeted treatments to address the underlying cause and restore normal AV conduction. Intravenous atropine should be considered as initial therapy when the AV block is suspected to be supra-Hisian. Dopamine and isoproterenol can be used in symptomatic patients with second or third-degree AV block with evidence of acute myocardial ischemia.[45] A temporary transvenous pacemaker should be considered in selective patients with hemodynamically unstable AV block who do not respond to medical therapy or are in cardiogenic shock.[46][47][48] It is important to minimize the use of temporary pacemakers, particularly in patients needing a permanent pacemaker, as they can significantly elevate the risk of infection associated with cardiac implantable electronic devices. The use of a temporary pacemaker should be kept to the shortest duration to avoid patients' risk of immobility, infection, thromboembolism, and risk of cardiac perforation. The potential complications must be kept in mind as sometimes the risk-benefit ratio may significantly outweigh justifying its potential use. Chronic Management of Atrioventricular Block

A temporary transvenous pacemaker should be considered in selective patients with hemodynamically unstable AV block who do not respond to medical therapy or are in cardiogenic shock.[46][47][48] It is important to minimize the use of temporary pacemakers, particularly in patients needing a permanent pacemaker, as they can significantly elevate the risk of infection associated with cardiac implantable electronic devices. The use of a temporary pacemaker should be kept to the shortest duration to avoid patients' risk of immobility, infection, thromboembolism, and risk of cardiac perforation. The potential complications must be kept in mind as sometimes the risk-benefit ratio may significantly outweigh justifying its potential use. Chronic Management of Atrioventricular Block Implantation of a permanent pacemaker is the mainstay of treatment for patients with AV block. Asymptomatic patients with first-degree AV block, second-degree type I AV block, or 2:1 AV block at the AV node level usually do not require a pacemaker. They should be followed as an outpatient, and a pacemaker should be considered if they develop symptoms due to an AV block.[49][50] Permanent pacemaker implantation must be considered in patients with symptomatic second-degree AV block, high-degree AV block, or third-degree AV block who do not have a reversible cause of the AV block. Patients who exhibit second-degree or third-degree atrioventricular (AV) block and have conditions such as infiltrative cardiomyopathy or muscular dystrophy should receive both a defibrillator and a permanent pacemaker implantation.[49][51][52] According to the current guidelines, a dual-chamber pacemaker is recommended over a single-chamber pacemaker. Nevertheless, a single-chamber pacemaker may be considered in specific cases with persistent atrial fibrillation or significant co-morbid conditions that restrict the advantages of a dual-chamber pacemaker.[53][54]

All patients presenting with an AV block must undergo extensive work-up to evaluate the underlying causes of the AV block. A 12-lead ECG should be examined closely to differentiate an AV block from an isorhythmic AV dissociation and a junctional escape rhythm.[55]

Atrioventricular block is the most common indication of pacemaker implantation worldwide. Untreated patients diagnosed with third-degree AV block face a 5-year survival rate as low as 37%. Asymptomatic patients with an AV block have a slightly better prognosis than symptomatic patients. Men diagnosed with a third-degree AV block generally exhibit poorer prognoses than women.[56] The prognosis of these patients also depends on the patient's age and the presence of medical conditions such as hypertension, ischemic heart disease, diabetes mellitus, chronic kidney disease, and underlying heart disease.[57] Implantation of pacemakers improves survival and quality of life in symptomatic patients with an AV block.[58][59]

The common complications of an AV block include syncope, heart failure, atrial fibrillation, and cardiac arrest. It may also lead to bradycardia-induced ventricular tachycardia and rarely may lead to sudden cardiac death.[60]

Patients with first-degree and asymptomatic Mobitz type 1 AV block usually can continue their usual activities but should be advised to avoid medications that can prolong PR interval. Patients diagnosed with Mobitz type 2 and third-degree AV block should have a thorough discussion with their cardiologists regarding the necessity of pacemaker implantation. Furthermore, educating all patients about the alarming symptoms of hypoperfusion, including fatigue, lightheadedness, syncope, presyncope, or angina, is essential. Patients should be informed about the significance of seeking prompt medical attention if they experience these symptoms.

The optimal management of heart block requires an interprofessional team approach, as the condition can lead to significant morbidity and mortality if higher degrees of heart block are missed in the diagnosis. Therefore, collaborative efforts among healthcare professionals are crucial to ensure timely and accurate diagnosis, appropriate treatment, and ongoing monitoring for patients with heart block. Advanced practice practitioners, primary care providers, internists, or emergency department physicians are among the healthcare professionals who may come across patients presenting with a heart block. Except for first-degree heart block, patients with other types of heart block should be referred to a cardiologist for a more comprehensive and definitive evaluation. In some instances, patients with an AV block may necessitate the implantation of a pacemaker, which can be a life-saving intervention. Post-treatment, it is essential for the cardiology nurse to deliver diligent follow-up care, overseeing the normalization of the patient's heart rate and confirming the absence of any related symptoms.[61] If patients with a pacemaker require surgery, it is imperative to consult with the cardiologist first. Collaboration with the cardiologist ensures a thorough understanding of the patient's pacemaker settings which may need to be reprogrammed for the procedure, any necessary precautions, and the development of a comprehensive plan to manage the pacemaker during the surgical procedure. After surgery, the pacemaker has to be reprogrammed according to the baseline settings. Today, most centers have a pacemaker nurse who monitors these patients for complications. Only through a combined team approach can the morbidity of heart block be decreased.