|Change in cycle length during narrow complex tachycardia: what is the mechanism?|
|Jump to Full Text|
|PMID: 20376187 Owner: NLM Status: PubMed-not-MEDLINE|
|Major spontaneous variation in cycle length during supraventricular tachycardia is quite an uncommon phenomenon, which sometimes can mislead a correct diagnosis. We describe a patient who developed spontaneous variation in cycle length during electrophysiologic study in whom the coronary sinus cannulation was extremely difficult. In this situation, careful inspection of the mechanisms associated with this variation and classic pacing maneuvers are important to make a correct diagnosis of the supraventricular tachycardia.|
|Diego Chemello; Anandaraja Subramanian; Douglas Ing|
Related Documents :
|3229437 - Value of post-operative programmed ventricular stimulation after map-guided surgery for...
8364947 - Proarrhythmic effects of class ic drugs.
3414487 - Significant variability in the mode of ventricular tachycardia induction and its implic...
2872017 - Solitary beta-blocker therapy for idiopathic life-threatening ventricular tachyarrhythm...
15096997 - Predictors of death during 10 years after coronary artery bypass grafting with particul...
24882547 - Ventricular sympathetic innervation in patients with transposition of the great arterie...
|Type: Journal Article Date: 2010-04-01|
|Title: Indian pacing and electrophysiology journal Volume: 10 ISSN: 0972-6292 ISO Abbreviation: Indian Pacing Electrophysiol J Publication Date: 2010|
|Created Date: 2010-04-08 Completed Date: 2010-05-24 Revised Date: 2013-05-29|
Medline Journal Info:
|Nlm Unique ID: 101157207 Medline TA: Indian Pacing Electrophysiol J Country: India|
|Languages: eng Pagination: 190-4 Citation Subset: -|
|Toronto General Hospital, University Health Network.|
|APA/MLA Format Download EndNote Download BibTex|
Journal ID (nlm-ta): Indian Pacing Electrophysiol J
Journal ID (publisher-id): Indian Pacing Electrophysiol J
Publisher: Indian Heart Rhythm Society
Copyright: ? 2010 Chemello et al.
collection publication date: Year: 2010
Electronic publication date: Day: 01 Month: 4 Year: 2010
Volume: 10 Issue: 4
First Page: 190 Last Page: 194
PubMed Id: 20376187
Publisher Id: ipej100190-00
|Change In Cycle Length During Narrow Complex Tachycardia: What Is The Mechanism?|
|Diego Chemello, MD|
|Anandaraja Subramanian, MD|
|Douglas Ing, MD, FRCPC, FACC|
|Toronto General Hospital, University Health Network
|Correspondence: Address for correspondence: Douglas Ing, Toronto General Hospital - Peter Munk Cardiac Centre, 200 Elizabeth Street, 3rd floor, room 503A. Toronto, ON. Canada, M5G 2C4. E-mail: firstname.lastname@example.org
Funding and conflict of interest disclosure: Diego Chemello, MD is partially funded by Coordenacao de Aperfeicoamento de Pessoal de Ensino Superior (CAPES), Brazil.
Major cycle length (CL) variations are unusual in supraventricular tachycardia. These variations can occur due to several mechanisms, which are not always obvious . In patients with dual atrioventricular (AV) nodal physiology and accessory pathway, more than one circuit can be responsible for the generation and maintenance of the arrhythmia . The electrophysiologic study (EPS) is a fundamental diagnostic test to help differentiate tachycardia mechanisms. We present a case of orthodromic atrioventricular tachycardia (ORT) in a patient with dual AV physiology, in which a sudden variation in CL was observed. The challenges and difficulties during EPS are reported.
A 20-year-old man underwent EPS for evaluation of recurrent palpitations. Baseline 12-lead electrocardiogram was normal. Catheter positioning induced a sustained narrow QRS complex tachycardia with 1:1 ventriculo-atrial (VA) relationship. Coronary sinus (CS) cannulation was extremely difficult due to anatomical reasons and could not be performed in the beginning of the study. During the tachycardia, there was a spontaneous change in CL from 346 to 265 ms. A significant QRS voltage alternans was also observed (Figure 1). What are the possible mechanisms associated with this spontaneous change in CL? Is it possible to make a correct diagnosis of the tachycardia without the CS catheter appropriately positioned?
Minor CL variations are frequently seen during supraventricular tachycardia, but oscillations above 15 ms are unusual. These changes can occur by a variety of mechanisms, particularly due to autonomic influences. In a re-entrant mechanism, a shift in either the antegrade or the retrograde limb, or a change in the conduction time along these limbs can contribute to the CL change. In tachycardias due to enhanced automaticity, either a shift in the automatic focus or varying degrees of exit block from the focus can contribute to the change in CL [3-5].
Figure 1 shows a narrow complex tachycardia at a CL of 346 ms, changing to a CL of 265 ms. There is 1:1 VA association with VA interval of 105 ms. The differential diagnoses of the tachycardia include atrioventricular nodal re-entry tachycardia (AVNRT), ORT and atrial tachycardia (AT). During the change in CL, atrial CL variation is predicted by changes in the preceding ventricular CL. This makes a diagnosis of AT unlikely and supports a diagnosis of either typical (slow-fast) AVNRT or ORT. In these arrhythmias the antegrade limb of the circuit (AV node) is highly dependent on autonomic tone. Conversely, the retrograde limb (fast AV nodal pathway or concealed bypass tract, respectively) is stable during the entire tachycardia. In AT, however, variations in CL are associated with the atrium and do not depend on the AV node. In this situation, AA interval determines the subsequent VV interval .
In the beginning of tachycardia (CL 346 ms), the AH, HA and VA intervals are 198 ms, 175 ms and 107 ms respectively. When the tachycardia CL changes (265 ms), the intervals are 118 ms, 150 ms and 105 ms respectively. So, it is possible to conclude that the change in tachycardia CL is predominantly due to change in conduction along the antegrade limb, which is in this case the AV node. Additionally, retrograde atrial activation sequence remains the same during the CL change. These findings are highly suggestive of a change in the antegrade conduction through the AV node. Overdrive ventricular pacing was done to entrain the tachycardia and the response on stopping the entrainment was VAV: further evidence against AT. The post pacing interval minus tachycardia cycle length (PPI-TCL) was 126 ms and the difference (corrected for the AV nodal delay during entrainment) was 96 ms. Also there is evidence of progressive fusion during tachycardia entrainment by ventricular pacing. These findings are in favour of a pathway as the tachycardia mechanism. (Figure 2) [6,7]. With a strong evidence of a concealed accessory pathway (AP), tricuspid annulus and right septal region were initially mapped during tachycardia. However there was no area of early atrial activation identified along these areas. Coronary sinus cannulation was reattempted and a 10-pole catheter was successfully positioned into the coronary sinus. The EP study was continued. There was evidence of dual AV nodal physiology during programmed atrial stimulation. The VA conduction during ventricular pacing was eccentric, with earliest activation in distal pole of the CS catheter, which typically occurs with left sided concealed accessory pathways. Then, a 4mm ablation catheter was positioned in the mitral annulus region via retrograde transaortic approach. Left lateral accessory pathway was successfully mapped and ablated (Figure 3). Post ablation, despite dual AV nodal physiology, there was no inducible tachycardia.
The present case illustrates an ORT using a concealed left lateral bypass in a patient with dual AV node physiology, which has been previously reported . The incidence of AVNRT in patients with bypass tract is relatively common (8-10%). This may be related to the high incidence of dual AV nodal physiology observed in such patients. Also, though the presence of QRS alternans has been reported to occur more commonly with ORT, it can also occur in AVNRT [3,8].
The challenging component of this case was the significant delay in CS cannulation, which can make the diagnosis difficult. The tachycardia was successfully terminated by accessory pathway ablation. Moreover, AV nodal slow pathway ablation strategy could be considered even in patients with no inducible AVNRT in special populations (elderly patients, for example) in order to reduce the risks due to multiple EPS for recurrent arrhythmias .
Although the exact mechanism associated with change in tachycardia CL is unknown, it is suggestive that antegrade conduction modification through the AV node was the causal factor. AV node accommodation is possible, but not the most probable explanation for the change in CL, since a gradual increase in heart rate would be expected . Thus, a shift in conduction from AV nodal slow pathway (AH=198 ms) to a fast pathway (AH=118 ms) is the most probable mechanism associated with CL in this case. In many patients, there appear to be at least two discrete inputs from the atria to the AV node, which are commonly termed fast and slow pathways. In sinus rhythm, the fast pathway constitutes the normal entry of the atrial impulse to the compact AV node. During tachycardia, the autonomic state can change the refractory properties of the slow and fast pathway resulting in shifting of conduction from one pathway to another as seen in our patient. If there is random shift in the antegrade conduction between fast and slow pathway, then the rhythm can get irregular and mimic atrial tachycardia and atrial fibrillation. This case emphasizes the importance of pacing maneuvers to help the electrophysiologist to suspect and confirm the presence of an accessory pathway, even when coronary sinus cannulation is not possible.
|Murgatroyd FD,et al. Handbook of cardiac electrophysiology : a practical guide to invasive EP studies and catheter ablationYear: 2002LondonReMEDICA Pub250|
|Pritchett EL,et al. Dual atrioventricular nodal pathways in patients with Wolff-Parkinson-White syndromeBr Heart JYear: 19804377356864|
|Amasyali B,et al. Atrioventricular nodal re-entrant tachycardia with QRS voltage and cycle length alternation and aberrant conduction due to two distinct antegrade slow pathwaysEuropaceYear: 2006813416627425|
|Belz MK,et al. Effects of enhanced parasympathetic tone on atrioventricular nodal conduction during atrioventricular nodal reentrant tachycardiaAm J CardiolYear: 1997808789382001|
|Crawford TC,et al. Utility of atrial and ventricular cycle length variability in determining the mechanism of paroxysmal supraventricular tachycardiaJ Cardiovasc ElectrophysiolYear: 20071869817537206|
|Gonzalez-Torrecilla E,et al. First postpacing interval after tachycardia entrainment with correction for atrioventricular node delay: a simple maneuver for differential diagnosis of atrioventricular nodal reentrant tachycardias versus orthodromic reciprocating tachycardiasHeart RhythmYear: 2006367416731468|
|Veenhuyzen GD,et al. Principles of entrainment: diagnostic utility for supraventricular tachycardia Indian Pacing Electrophysiol JYear: 2008 85118270602|
|Green M,et al. Value of QRS alteration in determining the site of origin of narrow QRS supraventricular tachycardiaCirculationYear: 1983683686861312|
|Di Biase L,et al. Ablation of atrioventricular nodal slow pathway for simultaneous treatment of coexisting atrioventricular and nodal reciprocating tachycardiasJ Interv Card ElectrophysiolYear: 20071914317668304|
Keywords: supraventricular tachycardia, atrioventricular nodal re-entry tachycardia, orthodromic reciprocating tachycardia, RF ablation, cycle length variation.
Previous Document: Polymorphic ventricular tachycardia due to acute coronary ischemia: a case report.
Next Document: Development of malignant ventricular arrhythmias in a young male with WPW pattern.