Left bundle branch block pathophysiology

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Editor-In-Chief: C. Michael Gibson, M.S., M.D. [1]; Raviteja Guddeti, M.B.B.S. [2]; Aarti Narayan, M.B.B.S [3]

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Pathophysiology

Normal Conduction

  1. The normal cardiac conduction proceeds in a way so as to allow time for atrium to relax during atrial diastole.
  2. The electrical impulse generated in the SA node travels through the internodal pathways towards the AV node.
  3. The conduction through the AV node is slowed down as it travels through it. This decrease in velocity of conduction allows time for atrial to contract ahead of the ventricle so that the blood from the atria can fill up the ventricles through the atrio-ventricular valves.
  4. As the impulse flows through the compact AV node, it rapidly conducts through the ventricular myocardial cells. Once the depolarization is complete, the ventricle relaxes during the diastole in preparation for the next impulse.
Conduction system of the heart




























Anatomy

  • The conduction system of the heart consists of specialized cells designed to conduct electrical impulse faster than the surrounding myocardial cells.
  • Anatomically, the AV node is divided into three regions as follows:
  • The left bundle branch penetrates the membranous portion of the interventricular septum and divides into several branches. Parts of the left bundle branch include a pre-divisional segment, anterior fascicle/hemibundle and posterior fascicle/hemibundle. Rarely a median fascicle is present in some hearts.
    • The anterior fascicle supplies the anterior papillary muscle and the Purkinje network of the antero-lateral surface of the left ventricle.
    • The posterior fascicle supplies the posterior papillary muscle and the Purkinje network of the postero-inferior surface of the left ventricle.
    • Left bundle branch receives its blood supply from left anterior descending artery.
Structure of the heart's conduction system

















Pathophysiology

  • Unlike right bundle branch block (RBBB), left bundle branch block completely modifies the way of depolarization of the conduction system of the heart. In LBBB the activation of the interventricular septum is from right to left due to uninterrupted conduction in the RBB.
  • Then the electrical impulse propagates inferiorly to the left resulting in delayed depolarization and activation of the left ventricle especially the left lateral wall.
  • In LBBB, changes in myocardial activation affect only the left ventricle. Hence EKG changes are recorded only in the left sided leads rather than the right sided leads.[1]
  • In LBBB the right to left activation of the septum causes a small negative deflection (Q wave) in lead V1 and a positive deflection (R wave) in lead V6. Right ventricle depolarizes earlier than the left ventricle giving an R wave in lead V1 and an S wave in lead V6. Subsequent delayed depolarization of the left ventricle results in an S wave in lead V1 and another R wave in lead V6.

References

  1. Francia P, Balla C, Paneni F, Volpe M (2007). "Left bundle-branch block--pathophysiology, prognosis, and clinical management". Clinical Cardiology. 30 (3): 110–5. doi:10.1002/clc.20034. PMID 17385703. Unknown parameter |month= ignored (help)

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