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Bifascicular block

Bifascicular block is a cardiac conduction abnormality characterized by impaired electrical transmission through two of the three main fascicles of the His-Purkinje system, typically involving the combined with either or . This delay in ventricular activation can alter the heart's rhythmic contraction but often does not immediately impair overall function unless it progresses to more severe forms of . On an electrocardiogram (ECG), it manifests as specific patterns, such as with for the anterior variant or for the posterior variant. The condition arises from various underlying causes, most commonly associated with structural heart diseases that lead to fibrosis or ischemia in the conduction pathways. Key etiologies include , , , degenerative changes in the conduction system, and prior , with imbalances or congenital factors also contributing in some cases. Risk factors encompass advanced age, a history of , , and familial predisposition to heart conditions, affecting approximately 1.5% of individuals undergoing routine ECG evaluations. Clinically, bifascicular block is frequently asymptomatic, though symptomatic cases may present with , , syncope, , or due to slowed or irregular heart rhythms. relies primarily on ECG interpretation to identify the characteristic conduction delays, supplemented by if structural abnormalities are suspected. focuses on addressing underlying causes through modifications, medications for comorbidities, and close monitoring; pacemaker implantation is indicated for symptomatic patients or those at high risk of progression to complete , which occurs in 1-4% per year overall, with higher rates (up to 17% cumulative over 5 years) in patients with associated syncope.

Anatomy and Physiology

Cardiac Conduction System

The is a specialized network of cells responsible for generating and propagating electrical impulses that coordinate heart contractions. It begins with the sinoatrial (SA) node, located at the junction of the and the right atrium, which serves as the heart's primary by spontaneously generating action potentials at a rate of 60 to 100 beats per minute under normal conditions. These impulses initiate atrial , spreading rapidly through the atrial myocardium via internodal pathways to ensure synchronized atrial contraction. The electrical signal then reaches the atrioventricular (AV) node, situated in the lower right atrium within the triangle of Koch near the , where it is delayed for approximately 100 milliseconds to allow complete atrial emptying into the ventricles before ventricular contraction begins. From the AV node, the impulse travels to the , an elongated structure about 1.8 cm long embedded in the , which conducts the signal rapidly to the bundle branches as extensions of itself. The bundle branches further distribute the impulse to the , a subendocardial network of specialized fibers that ramify throughout the ventricular myocardium, enabling near-simultaneous ventricular from to within about 75 milliseconds. This step-by-step propagation—from SA node through atria, AV node delay, , bundle branches, and —ensures sequential atrial and ventricular contractions, optimizing by filling ventricles before their . Electrophysiologically, the conduction system's cells exhibit distinct action potentials adapted for and rapid transmission. cells in the and nodes lack a stable ; instead, they display a phase 4 spontaneous depolarization driven by slow sodium influx, culminating in phase 0 rapid upstroke via calcium channels and phase 3 through potassium efflux, with intrinsic rates of 60–100 bpm for the node and 40–60 bpm for the node. In the and , action potentials resemble those of contractile myocytes but with faster conduction velocities (1–4 m/s), featuring a stable around -90 mV, rapid sodium-mediated , a prolonged plateau phase due to calcium influx, and , all supported by short refractory periods (absolute ~200 ms, relative ~50 ms) to prevent sustained contractions. This coordinated maintains rhythmic, efficient pumping while allowing autonomic for rate adjustments.

Bundle Branches and Fascicles

The bundle branches represent the terminal divisions of the , originating from the and facilitating rapid impulse transmission to the ventricles. The right bundle branch (RBB) emerges as a single, thin, and elongated structure that courses along the endocardial surface of the right side of the , initially near the in its upper third, then penetrating deeper into the muscular septum in the middle third, before returning to the endocardial surface in the lower third, where it ramifies near the base of the right anterior . This discrete cord of receives its primary blood supply from septal perforator branches of the left anterior descending coronary artery, with potential collateral circulation from the right or left circumflex arteries depending on coronary dominance. In contrast, the left bundle branch (LBB) divides shortly after its origin into two main fascicles: the left anterior fascicle (LAF) and the left posterior fascicle (LPFB), forming a bifascicular arrangement on the left septal surface. The LAF, a narrow and elongated band, travels superiorly and anteriorly along the endocardial surface toward the , often crossing the as a subendocardial sheet or . The LPFB is wider and shorter, extending posteroinferiorly along the septal surface to the base of the posteromedial and distributing to the intermediate and posterior septal regions. Both fascicles derive their blood supply primarily from septal perforators of the , though the LPFB exhibits dual perfusion from both the anterior descending and posterior descending . Functionally, the RBB conducts electrical impulses to depolarize the right ventricle, ensuring synchronous activation with the left side. The LAF is responsible for activating the superior and anterolateral portions of the left ventricle, directing vectorial forces superiorly and to the left, while the LPFB governs the inferior and posterobasal left ventricular regions, with forces directed inferiorly and rightward. These divisions allow for independent conduction within the left ventricle, supported by interconnections via the Purkinje network. Anatomical variations include the proposed trifascicular system, where a midseptal or third fascicle emerges from the main LBB trunk or the anterior/posterior fascicles in most human hearts, covering the midseptal surface and contributing to early septal excitation. Additionally, age-related can affect these structures, with degenerative changes such as Lenègre's or Lev's disease leading to sclerodegenerative alterations in the conduction fibers, particularly in middle-aged and older individuals.

Definition and Pathophysiology

Definition

Bifascicular block is defined as a conduction delay or complete block affecting the right bundle branch (RBB) and one of the two major fascicles of the left bundle branch—either the left anterior fascicle (LAFB) or the left posterior fascicle (LPFB)—of the . The two primary patterns are thus RBB + LAFB and RBB + LPFB. This condition differs from trifascicular block, which involves conduction impairment in all three fascicles while maintaining intact atrioventricular (AV) conduction, often manifested as bifascicular block plus first-degree AV block (prolonged PR interval). In contrast, complete heart block (third-degree AV block) represents total dissociation between atrial and ventricular activity due to failure of impulse conduction through the AV node or His-Purkinje system, which bifascicular block does not inherently cause unless progression occurs. The concept of bifascicular block emerged in the late 1960s and 1970s through electrocardiographic (ECG) studies that delineated the trifascicular nature of the intraventricular conduction system, with key contributions from Rosenbaum et al. in 1968 describing hemiblocks. According to the 2018 //HRS Guideline on the Evaluation and Management of Patients With and Cardiac Conduction Delay (the most recent comprehensive update as of 2025), bifascicular block is classified as a chronic conduction abnormality associated with potential progression to higher-degree AV block. Bifascicular block has a prevalence of approximately 1-1.5% in the general adult population, with prevalence rising in those over 50 years due to age-related degenerative changes in the conduction system.

Causes and Risk Factors

Bifascicular block primarily arises from underlying structural heart disease, which is associated with 50-80% of cases, often involving extensive fibrosis of the cardiac conduction system. Ischemic heart disease, particularly coronary artery disease, accounts for 40-60% of instances, where acute myocardial infarction disrupts the septal blood supply to the bundle branches and fascicles. Degenerative processes due to aging, such as Lenegre's disease or Lev's disease, lead to idiopathic fibrosis and calcification of the conduction tissue, commonly affecting older individuals and resulting in progressive conduction delays. Additional etiologies include chronic conditions like and diabetes mellitus, which contribute to myocardial remodeling and fibrosis; , especially ; and congenital anomalies present from birth. Iatrogenic causes, such as post-cardiac complications, can also induce bifascicular block through direct or to the conduction pathways. Less commonly, or infiltrative diseases like may precipitate the condition by altering cellular excitability or causing tissue infiltration. Key risk factors include advanced age over 60 years, which accelerates natural degeneration of the conduction system; male sex; and comorbidities such as , , and that promote . Overweight status and elevated inflammatory markers further elevate risk by exacerbating underlying cardiac strain. Pathophysiologically, bifascicular block results from progressive sclerosis, ischemia, or that impairs intraventricular conduction along two of the three fascicles, leading to delayed ventricular without initially affecting atrioventricular synchrony. In ischemic cases, occlusion of vessels supplying the conduction system, such as the proximal , directly contributes to fascicular damage.

Clinical Features

Signs and Symptoms

Bifascicular block is frequently asymptomatic, with the majority of cases identified incidentally during routine (ECG) screening or evaluation for unrelated conditions. In such instances, the conduction abnormality does not produce noticeable effects on daily functioning, and patients remain unaware of its presence until detected on diagnostic testing. This lack of symptoms underscores the importance of ECG in populations at risk, such as those with known , where the block may coexist without direct clinical impact. When symptoms do occur, they often stem from intermittent progression to higher-degree atrioventricular (AV) block or associated bradyarrhythmias, rather than the bifascicular block itself. Common presentations include syncope or presyncope, particularly during exertion or postural changes, resulting from transient complete heart block. Additional manifestations may involve fatigue, dizziness, and exertional dyspnea, reflecting reduced cardiac output during episodes of slowed heart rate. Palpitations are rare but can arise from ventricular escape rhythms compensating for conduction delays. These symptoms are more likely in patients with underlying structural heart disease, which amplifies the conduction system's vulnerability. On , findings are typically nonspecific unless complicated by associated block. or an irregular pulse may be detected, indicating rate disturbances, while and generally reveal no distinctive abnormalities attributable to the block alone. Clinical observations emphasize heightened awareness of subtle presentations like in elderly patients with comorbidities, where multifactorial contributors can exacerbate conduction-related instability. This recognition highlights the need for comprehensive evaluation in older adults to distinguish conduction issues from overlapping age-related hemodynamic changes. As of 2025, advancements such as AI-enhanced ECG models have improved risk stratification for progression to complete in these patients.

Epidemiology

Bifascicular block has a reported prevalence of 1% to 1.5% in the general adult population. This rate rises significantly with age and is higher in males with a male-to-female ratio of approximately 2:1. The annual incidence of bifascicular block is low in the general population but higher among at-risk groups, such as patients recovering from myocardial infarction. Demographic trends indicate that bifascicular block is more common in Western populations burdened by higher rates of , with recent studies as of 2025 noting a slight increase attributable to aging demographics worldwide. It is identified in about 25% of syncope evaluations among elderly patients and is associated with structural heart disease in 50-80% of cases. Historically, recognition of bifascicular block has increased since the due to the widespread adoption of in clinical practice.

Diagnosis

Electrocardiogram Criteria

Bifascicular block is identified on the electrocardiogram (ECG) by patterns reflecting conduction delay in two of the three fascicles of the left and right bundle branches, without evidence of complete atrioventricular (AV) dissociation. According to the (AHA)/ Foundation (ACCF)/Heart Rhythm Society (HRS) recommendations, the term "bifascicular block" is not preferred due to variable anatomic correlations, but it conventionally describes specific combinations of (RBBB) with either (LAFB) or (LPFB), or LAFB with LPFB. The most common pattern, RBBB plus LAFB, features a prolonged QRS duration of ≥120 ms in adults, an in leads V1 or V2 with the terminal R' wave wider than the initial R wave, and a wide S wave exceeding the R wave amplitude in leads I and V6 for the RBBB component. The LAFB component is characterized by between -45° and -90° in the frontal plane, a qR pattern in lead aVL with R-peak time ≥45 ms, and small q waves or rS patterns in the inferior leads (, III, aVF), while QRS duration remains <120 ms for isolated LAFB. Slurred or notched s may appear in leads I and aVL due to delayed activation of the anterior superior left ventricle. In RBBB plus LPFB, the ECG similarly shows QRS duration ≥120 ms with RBBB features as described, but the LPFB manifests as right axis deviation of +90° to +180° in adults, an rS pattern in leads I and aVL, and a qR pattern in leads III and aVF, excluding causes like right ventricular hypertrophy. The rarer LAFB plus LPFB pattern approximates left bundle branch block, with QRS ≥120 ms, normal or near-normal frontal plane axis, broad monophasic R waves in leads I, aVL, V5, and V6, and deep S waves in V1-V3, but without the typical RBBB morphology. Diagnostic pitfalls include distinguishing bifascicular block from nonspecific intraventricular conduction delay, where QRS prolongation occurs without the characteristic bundle branch or fascicular morphologies, such as absent rsR' in V1 or axis shifts; in such cases, no specific fascicular block is diagnosed. These criteria align with established guidelines emphasizing precise lead-specific changes for accurate identification, as nonspecific delays do not indicate fascicular involvement.

Additional Tests

In patients with confirmed bifascicular block, supplementary diagnostic tests are employed to evaluate underlying etiology, assess the severity of conduction abnormalities, and stratify risk of progression to higher-grade atrioventricular block. These investigations complement the initial electrocardiogram by providing insights into structural, functional, and intermittent aspects of cardiac conduction disease. Echocardiography is routinely recommended to detect structural heart disease that may contribute to bifascicular block, including assessment of left ventricular ejection fraction, wall motion abnormalities, and valvular dysfunction. This noninvasive imaging modality helps identify conditions such as ischemic cardiomyopathy or dilated cardiomyopathy, which are common underlying causes, and guides further management by quantifying systolic function. Ambulatory monitoring with Holter devices or event recorders is indicated, particularly in symptomatic patients, to capture intermittent high-grade atrioventricular block, pauses, or associated arrhythmias over 24 to 48 hours or longer periods. These tools correlate symptoms like syncope or dizziness with rhythm disturbances, offering a higher diagnostic yield than standard electrocardiography for detecting paroxysmal events in bifascicular block. Invasive electrophysiology studies provide detailed evaluation of His-Purkinje system function, measuring the HV interval to assess infranodal conduction delay. A prolonged HV interval greater than 55 ms signifies increased risk of progression to complete heart block and is particularly useful in patients with unexplained syncope and bifascicular block, where noninvasive tests are inconclusive. Laboratory evaluations include B-type natriuretic peptide (BNP) levels to screen for concomitant heart failure and troponin assays to exclude acute myocardial ischemia as a precipitant of conduction abnormalities. According to 2025 expert consensus, genetic testing is advised for rare hereditary forms, targeting genes such as SCN5A or LMNA in cases of early-onset or familial progressive cardiac conduction disease, to identify actionable variants. Exercise testing is utilized to provoke symptoms or evaluate chronotropic response and conduction behavior under stress, revealing exercise-induced worsening of block that may indicate infranodal disease. This test is especially relevant in patients with exertional symptoms, though interpretation requires caution due to baseline conduction delays.

Management

Monitoring and Lifestyle Advice

For patients with asymptomatic bifascicular block or those at low risk, routine clinical follow-up is essential to detect progression of conduction abnormalities. According to the 2018 ACC/AHA/HRS guidelines, periodic electrocardiograms (ECGs) and clinical evaluations are recommended to assess for symptoms, changes in conduction, and overall cardiac status (Class IIa, Level of Evidence B-NR). Similarly, the 2021 ESC guidelines endorse regular clinical assessments and ECG monitoring to identify early signs of deterioration, particularly in stable cases without syncope (Class IIa, Level of Evidence C). More frequent monitoring, such as every 6 months, may be warranted if underlying conditions like hypertension or ischemic heart disease are present, as these can accelerate progression. Lifestyle modifications play a supportive role in preventing exacerbation of bifascicular block by addressing modifiable risk factors and maintaining optimal cardiac function. Patients should prioritize hydration to avoid dehydration, which can worsen electrolyte imbalances and conduction issues, and maintain balanced electrolyte levels through a diet rich in potassium and magnesium. Effective management of comorbidities, such as hypertension and diabetes, through adherence to evidence-based therapies and weight control, is advised to reduce the burden on the conduction system, as supported by general cardiovascular guidelines integrated into conduction disease care. Smoking cessation and moderate physical activity, tailored to individual tolerance, are also recommended to support overall heart health without straining the electrical system. Patient education is a cornerstone of non-invasive management, empowering individuals to recognize and respond to potential complications promptly. Education should cover warning signs such as dizziness, presyncope, or syncope, with instructions to seek immediate medical attention if these occur, per the 2018 ACC/AHA/HRS guidelines (Class I, Level of Evidence C-LD). Patients must be informed about medications to avoid, including beta-blockers, non-dihydropyridine calcium channel blockers, and certain antiarrhythmics, as these can prolong atrioventricular conduction and increase risk in the setting of bifascicular block (Class IIb, Level of Evidence C). The 2021 ESC guidelines similarly emphasize discussing these risks during shared decision-making to promote adherence (Class I, Level of Evidence C). Ambulatory monitoring tools, such as 24- to 48-hour Holter monitors or longer-term external loop recorders, are valuable for early detection of intermittent high-degree atrioventricular block in low-risk patients. The 2018 ACC/AHA/HRS guidelines recommend ambulatory ECG monitoring to correlate any emerging symptoms with rhythm disturbances or to screen for pathologic bradycardia (Class I, Level of Evidence B). Remote monitoring devices may be considered for ongoing surveillance in select cases, particularly if baseline ECG shows additional features like first-degree AV block. Routine anticoagulation is not indicated unless atrial fibrillation coexists, as bifascicular block alone does not confer a thromboembolic risk warranting therapy.

Interventions and Pacing

Permanent pacing is indicated for patients with bifascicular block who experience symptomatic bradycardia, alternating bundle branch block, or documented advanced atrioventricular (AV) block, as these represent class I recommendations in the 2018 ACC/AHA/HRS guidelines, supported by 2025 appropriate use criteria from medical benefits management. In such cases, implantation is recommended to prevent progression to complete heart block and associated symptoms like syncope, particularly when electrophysiologic testing or clinical presentation supports conduction system disease. For patients requiring pacing, dual-chamber pacemakers in DDD mode are preferred to preserve AV synchrony and reduce the risk of pacemaker syndrome, offering benefits in maintaining physiologic heart rates during bifascicular block. Emerging leadless pacemaker systems, including those capable of dual-chamber functionality, are gaining traction as of 2025 for select cases, such as patients with high infection risk or anatomical challenges, with first-in-human studies demonstrating feasibility for conduction system pacing. The 2025 EHRA/ESC consensus supports conduction system pacing (e.g., left bundle branch area pacing) as Class IIa for patients with AV block and reduced left ventricular ejection fraction ≤40%. In acute settings, such as during myocardial infarction (MI) complicated by high-degree AV block in the presence of bifascicular block, temporary transvenous pacing is employed to stabilize hemodynamics until permanent pacing can be arranged or the block resolves. This approach is prioritized when bradyarrhythmias cause instability, with guidelines classifying it as a class I indication for high-risk conduction disturbances post-MI. Beyond pacing, management focuses on addressing underlying etiologies; for instance, coronary revascularization is pursued in ischemic cases to potentially improve conduction and halt progression. Medications that prolong AV conduction, such as beta-blockers or calcium channel blockers, should be avoided or used cautiously to prevent exacerbation of block. Clinical outcomes following pacing are favorable, with dual-chamber devices reducing syncope recurrence by approximately 68% in patients with bifascicular block and unexplained syncope, as evidenced by the ISSUE-3 trial where primary endpoint event rates dropped from 33% in the monitoring arm to 14% with pacing over two years. This intervention also lowers major adverse cardiac events compared to implantable cardiac monitoring alone in high-risk cohorts.

Prognosis

Progression Risks

Bifascicular block carries a risk of progression to complete heart block, with an overall annual incidence estimated at 1-4% in affected patients. In asymptomatic individuals without additional risk factors, this rate is lower, approximately 1% per year, based on long-term follow-up studies. The risk escalates significantly in the presence of symptoms such as syncope, reaching up to 17% annually, or with electrophysiological evidence of prolonged HV interval (>55 ms), where cumulative incidence over 7 years can approach 28%. Key predictors of progression include alternating bundle branch block, which signals advanced conduction system instability and markedly increases the likelihood of complete ; , indicating potential trifascicular involvement; and underlying structural heart disease, such as ischemic , which amplifies vulnerability. These factors contribute to progression dynamics post-diagnosis. The underlying mechanism involves progressive fibrosis of the His-Purkinje system, leading to cumulative involvement of the remaining fascicle and eventual trifascicular disease. This degenerative process, often idiopathic or linked to ischemic damage, gradually impairs conduction, particularly in the context of structural abnormalities. The risk of sudden death attributable to conduction progression remains low at 1-2% per year but is elevated in ischemic settings, where exacerbates arrhythmic potential. To detect early signs of advancement, such as new fascicular delays, serial electrocardiograms are recommended for monitoring high-risk patients. In select cases with identifiable predictors, preventive pacing may be considered to mitigate progression.

Long-Term Outcomes

Patients with bifascicular block face a 5-year of approximately 20%, with rates up to 30% observed in cohorts with significant comorbidities, primarily driven by underlying heart disease such as or prior rather than the conduction disturbance itself. Sudden cardiac accounts for about 10% of cases within 2 years in recent analyses, underscoring the need for risk stratification in vulnerable populations. Common long-term complications include exacerbations of and episodes of ventricular arrhythmias, which contribute to the overall and may necessitate advanced therapies. In high-risk groups, such as those with syncope or reduced ventricular function, implantation of cardiac pacemakers has been shown to mitigate these risks by reducing compared to conservative monitoring strategies. Quality of life remains largely preserved in individuals, who exhibit a near-normal with low rates of progression to severe conduction issues over extended follow-up periods of up to 10 years. Symptomatic patients, however, experience improved outcomes and fewer recurrent events following interventions like pacing, which address hemodynamic instability and prevent . Key prognostic factors include left ventricular below 40%, which independently predicts higher total mortality and cardiac-specific death rates in multivariate analyses.

References

  1. [1]
    Bifascicular Block - ECG Library - LITFL
    Oct 8, 2024 · Bifascicular block involves conduction delay below the atrioventricular node in two of the three fascicles.Missing: cardiology | Show results with:cardiology
  2. [2]
    Bifascicular Block: Causes, Symptoms & Treatment - Cleveland Clinic
    A bifascicular block is a heart block in two of your heart's three bundle branches. It delays your heart's electrical signals, affecting its pumping action.
  3. [3]
    Bifascicular Block | Cardiology - Mercy Health
    Bifascicular block is a type of heart conduction disorder in which two of the three main branches of the heart's electrical conduction system (the fascicles) ...Missing: definition | Show results with:definition
  4. [4]
    Physiology, Sinoatrial Node - StatPearls - NCBI Bookshelf
    The main function of the SA node is to act as the heart's normal pacemaker. It initiates an action potential that results in an electrical impulse traveling ...
  5. [5]
    Cardiac Muscle and Electrical Activity – Anatomy & Physiology
    The components of the cardiac conduction system include the sinoatrial node, the atrioventricular node ... (AV) bundle of His, bundle branches, and Purkinje fibers ...
  6. [6]
    Atrioventricular Node - StatPearls - NCBI Bookshelf - NIH
    The atrioventricular (AV) node is a small structure in the heart, located in the Koch triangle,[1] near the coronary sinus on the interatrial septum.
  7. [7]
    Physiology, Bundle of His - StatPearls - NCBI Bookshelf
    May 1, 2023 · The bundle of His is an elongated segment connecting the AV Node and the left and right bundle branches of the septal crest. It is approximately ...Introduction · Cellular Level · Development · Pathophysiology
  8. [8]
    Anatomy, Thorax, Heart - StatPearls - NCBI Bookshelf
    ... Purkinje fibers. The His-Purkinje tree serves to rapidly conduct the electrical signal to all parts of both ventricles to produce a near-simultaneous ...
  9. [9]
    Cardiac conduction system - Health Video - MedlinePlus
    Oct 15, 2024 · The main parts of the system are the SA node, AV node, bundle of HIS, bundle branches, and Purkinje fibers. Let's follow a signal through ...
  10. [10]
    Physiology, Cardiac - StatPearls - NCBI Bookshelf
    The AV node is the second pacemaker, which takes over the rate if the SA node begins to fail; the AV node keeps the rate at 40 to 60 BPM. Other foci around the ...
  11. [11]
    Overview of Cardiac Conduction - Conduction System Tutorial
    The atrial depolarization spreads to the atrioventricular (AV) node, and passes through the bundle of His to the bundle branches/Purkinje fibers. Right: The ...
  12. [12]
    Right Bundle Branch Block: Current Considerations - PMC - NIH
    The right bundle branch receives most of its blood supply from the septal branches of the left anterior descending coronary artery, particularly during its ...7. Ecg Findings And... · 7.1. Complete Rbbb · 7.1. 1. Qrs Complex
  13. [13]
    Fascicular Blocks: Update 2019 - PMC - NIH
    The anatomy of the left bundle branch is also discussed to better understand the incidence, prevalence, clinical significance and main causes of left anterior ...2. The Bundle Branches And... · 3. The Hemiblocks · 9. A Reappraisal Of The...
  14. [14]
    Anatomy of Left Bundle Branch for Pacing Optimization
    Some researchers consider the LBB an exclusively bifascicular structure with an anterior and a posterior ramification (12). Early electrophysiological data from ...The Lbb System · Figure 1 · Figure 2
  15. [15]
    Arrhythmia - Cardiology Explained - NCBI Bookshelf
    The term "bifascicular block" refers to a block of any two of the three fascicles. Clearly, this should include LBBB (left anterior + left posterior); however, ...
  16. [16]
    Induced by Atrial Pacing inPatients - with Chronic Bifascicular Block
    Bifascicular block was defined as right bundle branch block with left anterior hemiblock, right bun- dle branch block with left posterior hemiblock or left.
  17. [17]
    Resolution of Trifascicular Heart Block with Effective Closure of ... - NIH
    Aug 15, 2023 · Trifascicular HB is the combination of a bifascicular block and a first-degree HB. The most important causes of trifascicular HB are ischemic ...
  18. [18]
    Prevention of Syncope Through Permanent Cardiac Pacing in ...
    Bifascicular block is a rhythm disturbance linked with increased mortality, with an uneven occurrence of syncopal episodes, often associated with severe patient ...
  19. [19]
    Cardiac pacing in left bundle branch/bifascicular block patients
    The primary concern in patients with bifascicular block is the increased risk of progression to complete heart block. Further, an additional first-degree ...
  20. [20]
    Hemiblocks Revisited | Circulation
    Mar 6, 2007 · The trifascicular nature of the intraventricular conduction system and the concept of trifascicular block and hemiblock were described by ...
  21. [21]
    2018 ACC/AHA/HRS Guideline on the Evaluation and Management ...
    Nov 6, 2018 · 2017 AHA/ACC/HRS guideline for ... bifascicular block or left bundle branch block and additional first-degree atrioventricular block.
  22. [22]
    Bifascicular Block - RCEMLearning
    Oct 26, 2023 · Bifascicular block is a conduction defect of two of three main fascicles of the His/Purkinje system located below the AV node.
  23. [23]
    Masquerading bundle branch block: an often missed ... - NIH
    Dec 28, 2023 · It is most commonly caused by ischaemic/coronary heart disease, cardiomyopathy, long-standing hypertension, Lenegre-Lev disease and Chagas ...
  24. [24]
    Lenègre-Lev disease • LITFL • Medical Eponym Library
    Jun 30, 2025 · Lenègre identified several ECG manifestations of bilateral bundle branch block: RBBB or LBBB complicated by complete or incomplete AV block ...Missing: bifascicular | Show results with:bifascicular
  25. [25]
    Lev's Disease - an overview | ScienceDirect Topics
    Lenègre's disease is a sclerodegenerative process that occurs in a younger population and involves the more distal portions of the bundle branches.
  26. [26]
    What Should Be Done With the Asymptomatic Patient With Right ...
    Sep 14, 2020 · Possible causes include trauma, structural changes, infiltrative diseases (eg, sarcoidosis), myocarditis, and myocardial infarction. Right ...
  27. [27]
    Incidence and risk factors associated with atrioventricular block in ...
    Sep 27, 2024 · Conclusion: To conclude, older age, male sex, white population, overweight, combined diabetes or chronic kidney disease, impaired FVC, elevated ...
  28. [28]
    Bifascicular Block | Cardiology - Bon Secours
    Bifascicular block is a heart conduction disorder where two of the three fascicles are blocked. It often occurs due to heart disease or structural damage to the ...Missing: definition | Show results with:definition<|control11|><|separator|>
  29. [29]
    Bifascicular Block - Causes, Symptoms, Diagnosis, and Treatment
    Apr 25, 2025 · Key Risk Factors · Age: The risk of developing Bifascicular Block increases with age, as the heart's electrical system may become less efficient ...
  30. [30]
    a challenging case of a rare cardiomyopathy with an unexpected twist
    A 59-year-old man presented with recurrent syncope and was found to have bifascicular block and severe concentric left ventricular hypertrophy.
  31. [31]
    What Should Be Done With the Asymptomatic Patient With Right ...
    Sep 14, 2020 · RBBB is caused by diseases that affect the right bundle branch or the myocardial region, where the right bundle branch is located. Possible ...
  32. [32]
    Bifascicular block in unexplained syncope is underrecognized ... - NIH
    Feb 28, 2022 · Bifascicular block is defined on electrocardiography as left bundle branch block, right-bundle branch block with left anterior fascicular block ...
  33. [33]
    Bundle branch block - Symptoms & causes - Mayo Clinic
    In bundle branch block, the pathway these impulses follow is delayed or blocked. The pathway includes two branches the left and the right bundles.
  34. [34]
    Syncope in the Elderly - PMC - NIH
    Bifascicular-block (LBBB or RBBB combined with ... Lower limb and abdominal compression bandages prevent progressive orthostatic hypotension in elderly ...
  35. [35]
    Bundle-Branch Block in a General Male Population | Circulation
    The prevalence of bundle-branch block increases from 1% at age 50 years to 17% at age 80 years, resulting in a cumulative incidence of 18%.
  36. [36]
    [Bifascicular block: long-term follow-up. Report of 40 cases] - PubMed
    The incidence of this intraventricular conduction defect was 0.0033 (3.3 per thousand). Males predominated over females at a rate of 2.4 to 1. This block was ...Missing: prevalence | Show results with:prevalence
  37. [37]
    Incidence of and Risk Factors for Bundle Branch Block in Adults ...
    The incidences in men and women were 0.08 (5/6,573) and 0.09% (7/7,967), respectively, in people older than 40 years.
  38. [38]
    Bundle Branch Block Market Size, Trends, Growth Outlook 2035
    The aging population worldwide is a significant factor influencing the Global Bundle Branch Block Market Industry. As individuals age, the risk of developing ...
  39. [39]
    Significance of chronic bifascicular block without apparent organic ...
    Eighty-six of 452 patients (19%) with chronic bifascicular block were found to have no clinically apparent associated organic heart disease (OHD)
  40. [40]
    AHA/ACCF/HRS Recommendations for the Standardization and ...
    Mar 17, 2009 · The terms atypical LBBB, bilateral bundle-branch block, bifascicular block, and trifascicular block are not recommended because of the great ...
  41. [41]
    Chronic bifascicular blocks - UpToDate
    Apr 2, 2025 · Bifascicular block – The term bifascicular block most commonly refers to conduction disturbances below the atrioventricular (AV) node in which ...Missing: often | Show results with:often
  42. [42]
    Bifascicular Block ECG Review - Healio
    A bifascicular block on ECG is defined by the combination of a right bundle branch block and either a left anterior fascicular block or left posterior ...
  43. [43]
    2018 ACC/AHA/HRS Guideline on the Evaluation and Management ...
    Nov 6, 2018 · 2018 ACC/AHA/HRS Guideline on the Evaluation and Management of Patients With Bradycardia and Cardiac Conduction Delay
  44. [44]
    Electrophysiologic evaluation of syncope in patients with bifascicular ...
    Thirteen patients with syncope and bifascicular block were evaluated by electrophysiologic study (EPS) including programmed stimulation.
  45. [45]
    Cardiac conduction disorders in young adults - Heart Rhythm
    Mar 8, 2024 · An expert consensus document states that targeted genetic testing is recommended in patients with early-onset CCD with or without concomitant ...
  46. [46]
    [PDF] Cardiomyopathy and Arrhythmia Genetic Testing - eviCore
    Single Gene Tests (Sequencing and Deletion/Duplication Analysis). • Genetic Counseling: ◦ Pre and post-test genetic counseling by an appropriate provider ...
  47. [47]
    Exercise-induced complete heart block in a patient with chronic ...
    Heart block induced by exercise or associated with symptomatic, chronic bifascicular block can progress to high-grade atrioventricular (AV) block and sudden ...
  48. [48]
    None
    Nothing is retrieved...<|control11|><|separator|>
  49. [49]
    [PDF] Appropriate Use Criteria: Permanent Implantable Pacemakers
    Jul 17, 2025 · Permanent pacemaker placement is considered medically necessary for bundle branch block or fascicular block. (with 1:1 atrioventricular ...
  50. [50]
    Permanent cardiac pacing: Overview - UpToDate
    Sep 26, 2025 · SUMMARY AND RECOMMENDATIONS · INTRODUCTION · INDICATIONS · Sinus node dysfunction · Acquired AV block · Less common indications · PERMANENT ...
  51. [51]
    https://www.droracle.ai/articles/501438/what-type-of-pacemaker-is-considered-in-patients-with
  52. [52]
    First-in-human study of a leadless pacemaker system for left bundle ...
    Apr 27, 2025 · Leadless pacemakers (LPs) are limited by the current inability to perform left bundle branch area pacing (LBBAP). Objective. The purpose of this ...
  53. [53]
    [PDF] Leadless cardiac pacemakers - Repository of AIHTA GmbH
    With the new leadless pacemakers (VDD or DDD pacemakers), the indications can be expanded to include patients with high-degree or complete AV block and normal ...
  54. [54]
    [PDF] Indications for temporary and permanent pacing in ACS
    Indications for temporary transvenous pacing in acute myocardial infarction. Page 18. Class IIb indications. 1 Bifascicular block of indeterminate age. 2 New ...
  55. [55]
    What is the diagnosis and treatment for bifascicular block (a type of ...
    Apr 6, 2025 · Regular cardiac follow-up with periodic ECGs is recommended to monitor for progression to higher-degree heart block, as suggested by the ...
  56. [56]
    https://www.droracle.ai/articles/61066/what-is-the-diagnosis-and-treatment-for-bifascicular-block-a-type-of-heart-block-characterized-by-impairment-of-two-of-the-three-main-fascicles-in-the-electrical-conduction-system-of-the-heart
  57. [57]
    Randomized Pragmatic Trial of Pacemaker Versus Implantable ...
    At least 29% of patients with syncope, bifascicular block, and no evidence of infra-Hisian block later develop complete heart block when implantable cardiac ...
  58. [58]
    Significance of the HV interval in 517 patients with chronic ...
    Studies by Narula and. Samet24 in a small number of cases with AV block tend to support the close relationship between HV prolongation and subsequent risk of AV ...<|control11|><|separator|>
  59. [59]
    alternating bundle branch block and its clinical implications - NIH
    The likelihood of complete AV block is higher in those who develop alternating bundle branch block at almost the same heart rates and with PR interval changes.
  60. [60]
    Cardiac pacing in left bundle branch/ bifascicular block patients
    The primary concern in patients with bifascicular or trifascicular block is that they are at an increased risk of progression to complete heart block.
  61. [61]
    Long‐term prognosis in patients with bifascicular block – the ...
    Apr 21, 2006 · Patients with BFB have a poor long-term prognosis. The predictive value of noninvasive and invasive investigations is limited.
  62. [62]
    Long-term mortality predictors in patients with chronic bifascicular ...
    After a median follow-up of 4.5 years (P25:2.16-P75:6.41), 53 patients (20.1%) died, 19 (7%) of whom due to cardiac aetiology. Independent total mortality ...
  63. [63]
    Prevalence, circumstances, mechanisms, and risk stratification of ...
    The highest incidence of sudden death was observed in patients with bifascicular and trifascicular bundle branch block. In this group, 35% of patients died ...Missing: per | Show results with:per
  64. [64]
    Long-term mortality predictors in patients with chronic bifascicular ...
    Jul 3, 2009 · Bifascicular block patients with low ejection fraction and structural heart disease may not be sufficiently represented in our study and might ...
  65. [65]
    Impact of bundle branch block morphology on outcomes of patients ...
    Bifascicular block is encountered in up to 25% of patients presenting with syncope, which may be caused by intermittent complete heart block. However, other ...<|control11|><|separator|>