Intraventricular Conduction Abnormalities




Abstract


Normally, the entire mass of ventricular myocardium is depolarized in about 80 to 100 milliseconds. The term intraventricular conduction disturbances (IVCDs) refers to abnormalities in the intraventricular propagation of supraven­tricular impulses resulting in changes in the morphology and/or dura­tion of the QRS complex. These changes in intraventricular conduction can be fixed and present at all heart rates, or they can be intermittent (transient).


The term aberration is used to describe transient bundle branch block (BBB) and usually does not include persistent QRS abnormalities caused by BBB, preexcitation, or the effect of drugs. Transient BBB can have several mechanisms, including acceleration-dependent block, pause-dependent block, and concealed conduction. Chronic IVCDs can result from either intrinsic conduction system degeneration or an extrinsic insult from a variety of cardiovascular diseases, and the prognosis of BBB is largely related to the presence, type, and severity of the underlying heart disease, and to the possible presence of other conduction disturbances.


The ECG pattern of BBB can represent either complete block or conduction delay (relative to the other fas­cicles) that produces asynchronous ventricular activation with­out necessarily implying complete failure of conduction in the diseased fascicle. Therefore an ECG pattern of complete BBB can have varying degrees or alternate with contralateral com­plete BBB pattern. In selected patients, invasive electrophysiological testing can be used to obtain information that could predict which patients are at risk for syncope, atrioventricular block, or sudden cardiac death from a ventricular tachyarrhythmia.




Keywords

intraventricular conduction disturbances, bundle branch block, Ashman phenomenon, phase 3 block, phase 4 block

 






  • Outline



  • Transient Bundle Branch Block, 286




    • Acceleration-Dependent Bundle Branch Block, 286



    • Pause-Dependent Bundle Branch Block, 289



    • Aberration Caused by Concealed Transseptal Conduction, 291




  • Chronic Bundle Branch Block, 293




    • Anatomy and Physiology of the His-Purkinje System, 293



    • Pathophysiology of His-Purkinje System Disease, 294



    • Clinical Significance, 295




  • Electrocardiographic Features, 295




    • Bundle Branch Block, 295



    • Fascicular Block, 298



    • Other Types of Intraventricular Conduction Abnormalities, 299




  • Electrophysiological Testing, 300




    • Baseline Intervals, 300



    • Diagnostic Maneuvers, 301



    • Role of Electrophysiological Testing, 303



Normally, the entire mass of ventricular myocardium is depolarized in about 80 to 100 milliseconds. This requires highly synchronous electrical activation of the ventricular myocardium, which can be achieved only through the rapidly conducting His-Purkinje system (HPS). The term intraventricular conduction disturbances (IVCDs) refers to abnormalities in the intraventricular propagation of supraventricular impulses resulting in changes in the morphology and/or duration of the QRS complex. These changes in intraventricular conduction can be fixed and present at all heart rates, or they can be intermittent (transient). They can be caused by structural abnormalities in the HPS or ventricular myocardium, functional refractoriness in a portion of the conduction system (i.e., aberrant ventricular conduction), or ventricular preexcitation over a bypass tract.




Transient Bundle Branch Block


The term aberration is used to describe transient bundle branch block (BBB) and usually does not include persistent QRS abnormalities caused by persistent BBB, preexcitation, or the effect of drugs. Transient BBB can have several mechanisms, including acceleration-dependent block, pause-dependent block, and concealed conduction. These mechanisms of aberration can occur anywhere in the HPS and, unlike in chronic BBB, the site of block during aberration can shift. Right bundle branch block (RBBB) is the most common pattern of aberration, perhaps in part due to the thin nature of its anatomy, occurring in 80% of patients with aberration and in up to 100% of cases of aberration in normal hearts.


Acceleration-Dependent Bundle Branch Block


Conduction velocity depends, in part, on the rate of rise of phase 0 (dV/dt) of the action potential and the height to which it rises. These factors, in turn, depend on the membrane potential at the time of stimulation. The more negative the membrane potential, the more sodium (Na + ) channels are available for activation, allowing for a greater influx of Na + into the cell during phase 0 and, hence, larger action potential amplitude, fast depolarizing Na + current, and faster conduction velocity.


On the other hand, when stimulation occurs during phase 3 of the action potential, before full voltage recovery and at less negative transmembrane potentials, a portion of Na + channels is still refractory and unavailable for activation. Consequently, the Na + current and phase 0 of the action potential are reduced, and the resulting action potential has slower conduction properties and is more susceptible to conduction block ( Fig. 10.1 ).




Fig. 10.1


Mechanisms of Transient Bundle Branch Block.

Diagrammatic illustration of the responses of a normal ventricular myocyte action potential (AP, top ) and a depressed AP (bottom) to premature stimulation. Top , So-called phase 3 or voltage-dependent refractoriness. The first stimulus (arrow) falls on an early phase 3 and fails to elicit a response. The second stimulus falls in late phase 3 and results in an abbreviated, slowly rising AP of low amplitude. The third stimulus that falls at the end of repolarization results in a full AP. The bottom recording illustrates postrepolarization refractoriness (arrows) in a depressed fiber. Because of delayed recovery of excitability, despite full repolarization after the second action potential, a depolarizing stimulus applied very early in diastole is incapable of bringing the cell to the threshold potential (broken horizontal line) . Thus the stimulus fails, and only a subthreshold depolarization is seen. When a similar stimulus is applied later in diastole, the cell is activated after a substantial delay.

(From El-Sherif N, Jalife J. Paroxysmal atrioventricular block: are phase 3 and phase 4 block mechanisms or misnomers? Heart Rhythm . 2009;6:1514–1521.)


“Phase 3 block” (also called “voltage-dependent block”) occurs when an impulse arrives at tissues that are still refractory due to incomplete repolarization. Functional or physiological phase 3 aberration can occur in normal fibers if the impulse is sufficiently premature to encroach on the physiological refractory period of the preceding beat. This is commonly seen with a premature atrial complex (PAC) with a very short coupling interval that attempts to depolarize the HPS during phase 3 of the action potential and, hence, is conducted aberrantly, most often with RBBB.


Manifestations of phase 3 block include BBB and fascicular block, as well as complete atrioventricular (AV) block. Transient left bundle branch block (LBBB) is less common than RBBB (only 25% of phase 3 aberration is of the LBBB type). The block usually occurs in the very proximal portion of the right bundle (RB). Phase 3 block constitutes the physiological explanation of several phenomena, including aberration caused by premature excitation, Ashman phenomenon, and acceleration-dependent aberration.


Importantly, in the presence of HPS disease, the mechanism of acceleration-dependent aberration may no longer be related to phase 3 block. In this setting, aberration can be precipitated by premature or shorter-coupled impulses occurring well after completion of phase 3 of the action potential. This type of block or aberrancy is usually a sign of conduction system disease. In normal myocardial cells, recovery of electrical excitability coincides in time with voltage recovery, that is, the end of the action potential. The resting membrane potential remains polarized throughout diastole. In contrast, under pathological conditions (e.g., ischemia, hyperkalemia, hypoxemia, acidosis), cardiomyocytes can have a less negative resting membrane potential. Hence, a portion of Na + channels remains closed and unavailable for activation throughout diastole. This results in reduced upstroke velocity and smaller amplitude of the action potential. At more depolarized resting potentials, the Na + current cannot be activated, though a strong stimulus can still induce a “slow response” action potential carried out by the slowly depolarizing calcium current. The “slow response” is characterized by slow conduction properties and refractoriness that can extend beyond the end of the action potential, a phenomenon known as “post-repolarization refractoriness.” As a result, a premature stimulus occurring during the early phase of diastole may fail to trigger a propagating action potential and, hence, manifest as block or aberration. Furthermore, the diseased HPS cells with depressed resting membrane potential are vulnerable to the phenomenon of concealed conduction and rate-dependent repetitive conduction block (see below), which can also mediate, at least in part, acceleration-dependent block.


Aberration Caused By Premature Excitation


Premature excitation can cause aberration by encroaching on the refractory period of the bundle branch prior to full recovery of the action potential, namely during so-called voltage-dependent refractoriness ( see Fig. 4.28 ). In normal hearts, this type of aberration is almost always in the form of RBBB ( Fig. 10.2 ), whereas such aberration in the abnormal heart can be that of RBBB or LBBB.




Fig. 10.2


Aberrantly Conducted Premature Atrial Complexes.

Sinus rhythm with atrial couplets. Note that the premature atrial complexes are conducted with right bundle branch block aberrancy (phase 3 block).


At normal heart rates, the effective refractory period (ERP) of the RB exceeds that of the atrioventricular node (AVN), His bundle (HB), and left bundle (LB). At faster heart rates, the ERP of both bundle branches shortens. However, RB ERP shortens to a greater degree than LB ERP, so that the duration of the refractory periods of the two bundles crosses over, and LB ERP becomes longer than that of the RB. This explains the tendency of aberration to be in the form of RBBB when premature excitation occurs during normal heart rates and in the form of LBBB when it occurs during fast heart rates.


Ashman Phenomenon


The Ashman phenomenon refers to aberration occurring when a short cycle follows a long one (long-short cycle sequence) ( Fig. 10.3 ). Aberrancy is caused by the physiological changes of the conduction system refractory periods associated with the R-R interval. Normally, the refractory period of the HPS lengthens as the heart rate slows and shortens as the heart rate increases, even when heart rate changes are abrupt. Thus, aberrant conduction can result when a short cycle follows a long R-R interval. In this scenario, the QRS complex that ends the long pause (i.e., long R-R interval) is conducted normally but creates a prolonged ERP of the bundle branches. If the next supraventricular impulse approaches the bundle branches after a short coupling interval, it may be conducted aberrantly because one of the bundles is still refractory as a result of a lengthening of the refractory period following the immediately preceding QRS (phase 3 block) ( eFig. 10.1 ). RBBB aberration is more common than LBBB in this setting because at heart rates usually present, the RB has a longer ERP than the LB.




Fig. 10.3


Ashman Phenomenon.

A premature atrial complex (PAC, red arrow ) during sinus rhythm induces atrial fibrillation (AF). Note that the PAC is conducted with right bundle branch block (RBBB) aberrancy (phase 3 block). During AF, long-short cycle sequences occur repeatedly and are associated with RBBB aberrancy (Ashman phenomenon, phase 3 block). Note that the aberrantly conducted complex (blue arrows) during AF occurs at variable coupling intervals to the preceding beats.





eFig. 10.1


Atrial Tachycardia With Variable Atrioventricular Conduction and Intermittent Aberrancy.

Left, atrial tachycardia (AT) with 2 : 1 atrioventricular (AV) conduction and normal QRS morphology is observed. Once 1 : 1 AV conduction occurs (QRS 3), left bundle branch block (LBBB) aberration develops (caused by long-short cycle sequence, phase 3 block). LBBB aberration is also observed during QRS 4, likely secondary to concealed transseptal conduction causing perpetuation of aberration. After a pause, both bundle branches recover from refractoriness producing a normal QRS 5. Ashman phenomenon (long-short cycle sequence) explains phase 3 block during QRS 6, but this time it manifests as a right bundle branch block (RBBB) pattern. This is because activation during QRS 4 propagated down the right bundle branch (RB) and across the septum, thus activating the left bundle branch (LB) retrogradely after some delay (concealed transseptal conduction), so that the LB-LB interval (between QRS 4 and QRS 5) resulted in a shorter effective refractory period (ERP) of the LB following QRS 5. Conversely, the RB-RB interval (between QRS 4 and QRS 5) was longer and, consequently, the ERP of the RB was still prolonged following QRS 5, thereby setting the stage for a long-short cycle sequence of the RB but not the LB. Therefore, RBBB (rather than LBBB) aberration develops. RBBB aberration during QRS complexes 7 and 8 is secondary to either concealed transseptal conduction or rate-dependent aberration. However, because LBBB (rather than RBBB) was observed during QRS 4 (although QRS 4 occurred following a similar cycle length to that of QRS 8), concealed transseptal conduction is more likely to be the mechanism of aberration. After a pause, both bundle branches recover from refractoriness to produce a normal QRS 9. Long-short cycle sequence explains phase 3 block during QRS 10, but this time it manifests as LBBB. This is because activation during QRS 8 propagated down the LB and across the septum, thus activating the RB after some delay (concealed transseptal conduction). The result is that the RB-RB interval (following QRS 8) and ERP of the RB became shorter, whereas the LB-LB interval (following QRS 8) was longer. Consequently, the ERP of the LB was still prolonged following QRS 9, thereby setting the stage for a long-short cycle sequence and LBBB aberration. LBBB aberration during QRS 11 is caused by concealed transseptal conduction. The Ashman phenomenon (long-short cycle sequence) underlies RBBB aberration during QRS 14. HRA, High right atrium.


The Ashman phenomenon can occur during second-degree AV block ( see eFig. 9.3 ), but it is most common during atrial fibrillation (AF), in which it was originally described, whereby the irregularity of the ventricular response results in frequently occurring long-short cycle sequences. Of note, aberration caused by the Ashman phenomenon can persist for several cycles. The persistence of aberration can reflect a time-dependent adjustment of refractoriness of the bundle branch to the abrupt change in cycle length (CL), or it can be the result of concealed transseptal activation (see later).


The aberrancy can be present for one beat and have a morphology resembling a premature ventricular complex (PVC), or it can involve several sequential complexes, mimicking ventricular tachycardia (VT). In the setting of aberrancy during AF, the mere “long-short cycle sequence” characteristic of the Ashman phenomenon may not be helpful in differentiating aberration from ventricular ectopy. Although a long cycle (pause) sets the stage for the Ashman phenomenon, it also tends to precipitate ventricular ectopy. Furthermore, concealed conduction occurs frequently during AF and therefore it is never possible to know from the surface electrocardiogram (ECG) exactly when a bundle branch is activated. Thus, if an aberrant beat does end a long-short cycle sequence during AF, it can be because of refractoriness of a bundle branch secondary to concealed conduction into it, rather than because of changes in the length of the ventricular cycle.


Nevertheless, there are several features of ventricular ectopy that can help distinguish a PVC from an aberrantly conducted “Ashman beat” during AF ( Table 10.1 ). PVCs are usually followed by a longer R-R cycle, indicating the occurrence of a compensatory pause, the result of retrograde conduction into the AVN and anterograde block of the impulse originating in the atrium. Hence, the presence of consistently long R-R cycles after the aberrated beats is suggestive of PVCs. A ventricular origin is also likely when there is a fixed coupling cycle between the normal and aberrant QRS complexes. Additionally, the absence of aberrancy despite the presence of comparable long-short cycle sequences elsewhere in the rhythm recording argues against aberrancy and is more consistent with ventricular ectopy. Finally, QRS morphology inconsistent with LBBB or RBBB aberrancy argues against aberration and is consistent with ventricular origin of the QRS complex ( eFig. 10.2 ).



TABLE 10.1

Distinguishing Aberrantly Conducted Complexes from Premature Ventricular Complexes During Atrial Fibrillation




























Aberration Premature Ventricular Complexes
Onset sequence Long-short Short-long
Rate parity between periods of wide versus narrow QRS complexes Similar rates Different rates
Coupling intervals from prior narrow QRS complexes Variable over several occurrences Same or similar over several occurrences
Regularity of consecutive wide QRS complexes Irregular Relatively regular
Fusion complexes Absent May be present





eFig. 10.2


Premature Ventricular Complexes During Atrial Fibrillation.

Several features suggest that the wide QRS complexes are caused by ventricular ectopy rather than aberration. QRS morphology is inconsistent with either left bundle branch block or right bundle branch block aberrancy. Additionally, there is a fixed coupling interval between the normal and aberrant QRS complex. The absence of a long-short cycle sequence associated with the wide QRS complex and the absence of aberrancy despite the presence of R-R cycle length combinations elsewhere in the tracing that are longer and shorter than those associated with the wide QRS complex also suggest ventricular ectopy.


Aberration Caused by Heart Rate Acceleration


As the heart rate accelerates, the HPS refractory period shortens allowing for normal 1 : 1 conduction at the faster atrial rate. However, refractoriness of the HPS eventually reaches a critical value beyond which it can no longer shorten in response to a further increase in the atrial rate; at this point, BBB or AV block can occur. Acceleration-dependent BBB is a result of failure of the action potential of the bundle branches to shorten in response to acceleration of the heart rate ( Fig. 10.4 ). As noted previously, the ERP of the RB normally shortens at faster heart rates to a greater degree than that of the LB; this finding explains the more frequent RBBB aberration at longer CLs (i.e., at slower heart rates) and LBBB aberration at shorter CLs.




Fig. 10.4


Tachycardia-dependent (Phase 3) Block.

The tracing shows sustained supraventricular tachycardia. Initially, the QRS is of normal morphology. Tachycardia-dependent (phase 3) right bundle branch block develops in the middle of the tracing and is sustained for a few beats. Delivery of a late ventricular extrastimulus (arrow) during the tachycardia preexcites the right bundle branch (and either peels back or shortens its refractoriness) and restores normal conduction.


Notably, during slowing of the heart rate, intraventricular conduction often fails to normalize at the critical CL, and aberration persists at cycles longer than the critical cycle that initiated the aberration. Once acceleration-dependent BBB is established, the actual cycle for the blocked bundle does not begin until approximately halfway through the QRS complex because of concealed transseptal conduction (see later); thus, it is necessary for the heart rate to slow down more than would be expected to reestablish normal conduction.


Occasionally, with increasing heart rate or persistence of fast heart rate, acceleration-dependent aberration can disappear. The normalization of a previously aberrant QRS complex can be explained by shortening of the ERP of the bundle branches to a greater degree than that of the AVN, by a time-dependent gradual shortening of the refractory period of the affected bundle branch (a phenomenon occasionally referred to as “restitution”), or by the loss of transseptal concealed conduction.


Importantly, acceleration-dependent aberration is a marker of a diseased HPS when it (1) appears at relatively slow heart rates (less than 70 beats/min); (2) displays LBBB ( Fig. 10.5 ); (3) appears after several cycles of accelerated but regular rate; or (4) appears with gradual rather than abrupt acceleration of the heart rate.




Fig. 10.5


Acceleration-dependent Aberration.

The lead II continuous rhythm strip demonstrates sinus rhythm with rate-related left bundle branch block (LBBB). Note that small changes in rate can result in acceleration-dependent aberration. LBBB develops at a sinus rate faster than 70 beats/min, and normal QRS complexes are observed at slower sinus rates. The LBBB and the slow rate at which aberration develops strongly suggest an abnormality in the left bundle branch (LB), rather than physiological aberration, which is often associated with underlying structural heart disease such as cardiomyopathy. Interestingly, the onset and offset of the LBBB demonstrate hysteresis in that the cycle length (CL) required to initiate the LBBB is shorter than the CL required to maintain it, probably because of retrograde concealed penetration of the LB.


Pause-Dependent Bundle Branch Block


Pause-dependent (or bradycardia-dependent) block occurs when conduction of an impulse is blocked in tissues well after their normal refractory periods have ended. Phase 4 aberration is one explanation for the development of aberration at the end of a long cycle (i.e., after a pause). Phase 4 block is governed by the same physiological principles as those for phase 3 block. Membrane responsiveness is determined by the relationship of the membrane potential at excitation with the maximum rate of rise of phase 0. The availability of the Na + channels is reduced at less negative membrane potentials, and activation at a reduced membrane potential is likely to cause aberration or block. The cause of membrane depolarization (i.e., reduction of membrane potential) in the setting of phase 4 block, however, is different from that in phase 3 block.


Phase 4 or diastolic depolarization is a property of pacemaker cells of the heart; normal His-Purkinje fibers do not possess this property at rates faster than 40 beats/min; however, diseased Purkinje cells can acquire the property of phase 4 depolarization at more rapid rates. Enhanced phase 4 depolarization within the bundle branches can be caused by enhanced automaticity or partial depolarization of injured myocardial tissue. In this setting, the maximum diastolic potential immediately follows repolarization, from which point the membrane potential steadily depolarizes (becomes less negative). This reduction in membrane potential, in turn, causes inactivation of some Na + channels. Thus, an action potential initiated early in the cycle (immediately after repolarization) would have a steeper and higher phase 0 and consequently better conduction than would an action potential initiated later in the cycle when the membrane potential at the time of the stimulus is reduced, with resulting slower upstroke velocity and smaller amplitude of the action potential and, hence, slower conduction or block ( Fig. 10.6 ). Phase 4 aberration is “pause-dependent” because the pause allows for spontaneous depolarization and, hence, the cell is activated from a less negative potential, and the result is impaired conduction ( Fig. 10.7 ). The critical prolongation of the input stimulus is typically initiated by a compensatory pause after a PAC or PVC, spontaneous slowing of the sinus rate, or overdrive suppression of sinus rhythm upon termination of a fast supraventricular rhythm. Once such critical diastolic membrane potential is reached (at which Na + channel inactivation occurs), subsequent conduction may no longer resume until a well-timed escape beat or premature beat (sinus or ectopic) resets the transmembrane potential to its excitable state. The extent of depolarization has to be significant because lesser amounts of depolarization improves excitability (membrane voltage closer to the threshold voltage) and should improve conduction.




Fig. 10.6


Action Potentials in Normal (A) and Diseased (B) Conduction Systems Showing Phase 4 Block.

Spontaneous diastolic depolarization during phase 4 in the diseased His-Purkinje system results in reduced availability of sodium channels during the next depolarization, and the resulting action potential cannot propagate the impulse.

(From Divakara Menon SM, Ribas CS, Ribas Meneclier CA, Morillo CA. Intermittent atrioventricular block: what is the mechanism? Heart Rhythm . 2012;9:154–155, with permission.)



Fig. 10.7


Bradycardia-dependent Block.

Normal intraventricular conduction is observed during sinus rhythm. Premature atrial complexes (hidden within the T waves) are not conducted to the ventricles, resulting in pauses. The sinus complex following the pause is conducted with left bundle branch block pattern (arrows) presumably secondary to phase 4 block.


Despite the fact that bradycardia is common and cells with phase 4 depolarization are abundant, phase 4 block is not commonly seen in normal myocardial tissue. In fact, most reported cases are associated with structural heart disease. One explanation for this phenomenon is that in normal fibers, conduction is well maintained at membrane potentials more negative than −70 to −75 mV. Significant conduction disturbances are first manifested when the membrane potential is less negative than −70 mV at the time of stimulation; local block appears at −65 to −60 mV. Because the threshold potential for normal His-Purkinje fibers is −70 mV, spontaneous firing occurs before the membrane can actually be reduced to the potential necessary for conduction impairment or block. In fact, in the latter setting, mild membrane depolarization can actually improve conduction because the membrane potential is moved closer to threshold potential. Phase 4 block is therefore pathological when it does occur, and it requires one or more of the following: (1) the presence of slow diastolic depolarization, which needs to be enhanced (i.e., occurring at rates faster than these cells normally spontaneously depolarize); (2) a decrease in excitability (a shift in threshold potential toward zero) so that, in the presence of significant bradycardia, sufficient time elapses before a new stimulus arrives, thus enabling the bundle branch fibers to reach a potential at which conduction is impaired; and (3) a deterioration in membrane responsiveness so that significant conduction impairment develops at −75 mV instead of −65 mV; this occurrence would also negate the necessity for such a long cycle before conduction fails. Also, it is important to recognize that, in some cases, pause-dependent aberrancy may be caused by other mechanisms (e.g., source-to-sink mismatch) that may not be related to phase 4 depolarization.


Pause-dependent or phase 4 block almost always manifests an LBBB pattern, likely because the left ventricle (LV) conduction system is more susceptible to ischemic damage and has a higher rate of spontaneous phase 4 depolarization than the right ventricular (RV). Both acceleration-dependent and pause-dependent aberrancy can be seen in the same patient with an intermediate range of CLs associated with normal conduction. The prognosis of rate-dependent BBB largely depends on the presence and severity of the underlying heart disease. Its clinical implications are not clear, and it usually occurs in diseased tissue and in the setting of myocardial infarction (MI), especially inferior wall MI.


Aberration Caused by Concealed Transseptal Conduction


Concealed transseptal conduction is the underlying mechanism of aberration occurring in several situations, including perpetuation of aberrant conduction during tachyarrhythmias, unexpected persistence of acceleration-dependent aberration, and alternation of aberration during atrial bigeminal rhythm.


Perpetuation of Aberrant Conduction During Tachyarrhythmias


During a supraventricular tachycardia (SVT) with normal ventricular activation, a PVC originating from the RV can retrogradely activate the RB early, whereas retrograde activation of the LB occurs later, following transseptal conduction of the PVC. Consequently, although the RB ERP expires in time for the next SVT impulse, the LB remains refractory because its actual cycle began later than the RB. Therefore the next SVT impulse traveling down the HB encounters an excitable RB and a refractory LB; thus it propagates to the RV over the RB (with an LBBB pattern, phase 3 aberration). Conduction subsequently propagates from the RV across the septum to the LV. By this time, the distal LB has recovered, allowing for retrograde penetration of the LB by the SVT impulse propagating transseptally, thereby rendering the LB refractory to each subsequent SVT impulse ( Fig. 10.8 ). This process is repeated, and the LBBB pattern continues until another well-timed PVC preexcites the LB (and either “peels back” or shortens its refractoriness), so that the next impulse from above finds the LB fully recovered (see Fig. 10.4 ).




Fig. 10.8


Perpetuation of aberrant conduction during supraventricular tachycardia secondary to concealed transseptal conduction. At left, supraventricular tachycardia is associated with normal ventricular activation and narrow QRS complexes. Critically timed ventricular extrastimulus delivered from the right ventricle (arrow) precipitates left bundle branch block aberrancy during the tachycardia.


More commonly, a PAC blocks anterogradely in the proximal portion of the RB to cause RBBB, conducts down the LB to activate the ventricle, crosses the septum to excite the RB retrogradely and make it refractory for the next supraventricular complex, thus perpetuating the RBBB (see below).


Unexpected Persistence of Acceleration-Dependent Aberration


Acceleration-dependent BBB develops at a critical rate faster than the rate at which it disappears ( Fig. 10.9 ). This paradox is most commonly ascribed to concealed conduction from the contralateral conducting bundle branch across the septum with delayed activation of the blocked bundle. Such concealed transseptal activation results in a bundle branch–to–bundle (RB-RB or LB-LB) interval shorter than the manifest R-R cycle. The reason is that the actual cycle for the blocked bundle does not begin until approximately halfway through the QRS complex because it takes 60 to 100 milliseconds for the impulse to propagate down the RB and transseptally reach the blocked LB. Consequently, for normal conduction to resume, the cycle (R-R interval) during deceleration must be longer than the critical cycle during acceleration by at least 60 to 100 milliseconds.




Fig. 10.9


Unexpected Persistence of Acceleration-dependent Aberration.

During incremental-rate atrial pacing from the coronary sinus (CS) , acceleration-dependent bundle branch block develops at a cycle length (CL) of up to 370 milliseconds. Aberrancy continues despite progressively increasing the pacing CL and disappears only when pacing at a CL of more than 600 milliseconds.


However, unexpected delay of normalization of conduction cannot always be explained by concealed conduction. Conduction sometimes normalizes with slowing of the heart rate, only to recur at cycles that are still longer than the critical cycle. Such a sequence excludes transseptal concealment as the mechanism of recurrence of the aberration. Similarly, when the discrepancy between the critical cycle and the cycle at which normalization finally occurs is longer than the expected transseptal activation time (approximately 60 milliseconds in the normal heart and 100 milliseconds in the diseased states), transseptal concealment alone cannot explain the delay (see Fig. 10.9 ). Fatigue and overdrive suppression have been suggested as possible mechanisms of the delayed normalization of conduction.


Alternation of Aberration During Atrial Bigeminal Rhythm


A bigeminal rhythm can be caused by atrial bigeminy, 3 : 2 AV block, or atrial flutter with alternating 2 : 1 and 4 : 1 AV conduction. The alternation can be between a normal QRS complex and BBB or between RBBB and LBBB.


When alternation occurs between a normal QRS complex and RBBB during atrial bigeminy, the ERP of both RB and LB starts simultaneously following the normally conducted PAC, and the ERP of both branches is relatively short because of the preceding short cycle. After the pause, the sinus beat conducts normally, and the ERP of both bundle branches starts simultaneously but is relatively long because of the preceding long cycle. However, because the RB ERP is relatively longer than that of the LB, the next PAC encroaches on the RB refractoriness and conducts with an RBBB pattern (phase 3 block). Subsequently, that PAC is conducted down the LB and across the septum. The PAC activates the RB retrogradely after some delay (concealed transseptal conduction), so that the RB-RB interval (during the following pause) and the RB ERP become shorter. As a result, by the time the next PAC reaches the RB, the RB is fully recovered because of its abbreviated ERP (reflecting the shorter preceding RB-RB interval, which is shorter than the manifest R-R interval during the preceding pause), and normal conduction occurs (see eFig. 10.1 ).


The same phenomenon (concealed transseptal conduction) explains alternating RBBB and LBBB during bigeminal rhythms. In the presence of RBBB, transseptal concealed conduction from the LB to the RB shortens the RB-RB interval relative to the now longer LB-LB interval. As a result, the ERP of the LB is longer and conduction in the LB fails. In the presence of a refractory LB, conduction propagates through the RB. The delayed transseptal activation of the LB shortens the LB-LB interval. The ERP of the RB is now relatively longer because RB conduction is blocked.

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Jun 17, 2019 | Posted by in CARDIOLOGY | Comments Off on Intraventricular Conduction Abnormalities

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