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CLINICAL RESEARCH: HEART RHYTHM DISORDER

Predictive Value of Ventricular Arrhythmia Inducibility for Subsequent Ventricular Tachycardia or Ventricular Fibrillation in Multicenter Automatic Defibrillator Implantation Trial (MADIT) II Patients

James P. Daubert, MD^_*,_*, Wojciech Zareba, MD, PhD^_*, W. Jackson Hall, PhD, Claudio Schuger, MD, Andrew Corsello, MD, Angel R. Leon, MD^||, Mark L. Andrews, MS^_*, Scott McNitt, MS^_*, David T. Huang, MD^_*, Arthur J. Moss, MD^_* for the MADIT II Study Investigators

^_* Cardiology Unit, Department of Medicine, University of Rochester Medical Center, Rochester, New York
Department of Biostatistics and Computational Biology, University of Rochester Medical Center, Rochester, New York
Department of Medicine, Henry Ford Health System, Detroit, Michigan
Maine Medical Center, Portland, Maine
^|| Department of Medicine, Emory University/Crawford Long Hospital, Atlanta, Georgia

Manuscript received January 8, 2005; revised manuscript received April 13, 2005, accepted August 1, 2005.

^_* Reprint requests and correspondence: Dr. James P. Daubert, Box 679-Cardiology, University of Rochester Medical Center, Rochester, New York 14642. (Email: James_Daubert{at}URMC.Rochester.edu).

	Abstract

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OBJECTIVES: We correlated electrophysiologic inducibility with spontaneous ventricular tachycardia (VT) or ventricular fibrillation (VF) in the Multicenter Automatic Defibrillator Implantation Trial (MADIT) II.

BACKGROUND: In the MADIT II study, 593 (82%) of 720 implantable cardioverter-defibrillator (ICD) randomized patients underwent electrophysiologic testing. Patients received an ICD whether they were inducible or not.

METHODS: A "standard" inducibility definition included sustained monomorphic or polymorphic VT induced with three or fewer extrastimuli or VF induced with two or fewer extrastimuli. We compared a narrow inducibility definition (only monomorphic VT) and a broad definition (standard definition plus VF with three extrastimuli). We used ICD-stored electrograms to categorize spontaneous VT or VF.

RESULTS: Inducible patients (standard definition) had a greater likelihood of experiencing ICD therapy for VT than noninducible patients (p = 0.023). Unexpectedly, ICD therapy for spontaneous VF was less common (p = 0.021) in inducible patients than in noninducible patients. The two-year Kaplan-Meier event rate for VT or VF was 29.4% for inducible patients and 25.5% for noninducible patients. Standard inducibility did not predict the combined end point of VT or VF (p = 0.280, by log-rank analysis). The narrow inducibility definition outperformed the standard definition, whereas the broad definition appeared inferior to the standard definition.

CONCLUSIONS: In the MADIT II study patients, inducibility was associated with an increased likelihood of VT. Noninducible MADIT II study subjects using this electrophysiologic protocol had a considerable VT event rate and a higher VF event rate than inducible patients. Induction of polymorphic VT or VF, even with double extrastimuli, appears less relevant than induction of monomorphic VT.

Abbreviations and Acronyms   ATP = anti-tachycardia pacing   EP = electrophysiologic   HR = hazard ratio   ICD = implantable cardioverter-defibrillator   MADIT = Multicenter Automatic Defibrillator Implantation Trial   MI = myocardial infarction   RV = right ventricular   VF = ventricular fibrillation   VT = ventricular tachycardia

The evaluation of inducibility as a predictor of arrhythmic events was a prespecified secondary objective of the MADIT II study. Thus, the MADIT II study protocol strongly encouraged patients randomly assigned to the ICD arm of the MADIT II study to undergo EP inducibility testing but for ICD implantation to be performed regardless of inducibility status. To maximize statistical power to address the role of EP testing, ICD to conventional randomization was 3:2 (1,6). Arrhythmia end points, i.e., ventricular tachycardia (VT) or ventricular fibrillation (VF), were determined using ICD interrogation data. We then evaluated the association between EP inducibility and subsequent ventricular arrhythmia and also with mortality. We evaluated whether classification of patients by inducibility status and baseline QRS duration (7–10) would predict arrhythmic events as well. Therefore, this study addressed whether ICD implantation in post-MI patients with an ejection fraction of 0.30 or less should be limited to those found to be inducible or whether otherwise-similar but noninducible patients also are at significant risk of life-threatening ventricular arrhythmia.

	Methods

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The MADIT II study (1) prospectively enrolled 1,232 patients with a previous MI and an ejection fraction of 0.30 or less. Of the 742 patients randomized to the ICD arm of the trial, 720 subjects actually received an implanted defibrillator. Electrophysiologic testing for ventricular tachycardia inducibility was recommended before the implantation of the ICD but was not a mandatory protocol requirement. Of the 720 ICD implant patients, 593 underwent EP testing, and this latter group is the cohort used in the present study.

EP testing and inducibility definitions.   The EP testing protocol used 400-ms and 600-ms drive trains followed by one to three ventricular extrastimuli that were 2 ms in duration at twice the diastolic threshold (1,6,11). Extrastimuli were decremented down to a coupling interval no shorter than 180 ms. Stimulation was performed at one right ventricular (RV) site and then repeated at a second RV site. Rapid burst pacing was not used for induction. A catheter-based EP testing study was recommended, but inducibility was determined through the ICD in 13% of the group. The EP study end point included the induction of a sustained monomorphic VT, polymorphic VT, or VF episode or completion of the protocol. A sustained ventricular arrhythmia was defined as one lasting 30 s or requiring termination sooner because of hemodynamic compromise.

Monomorphic VT was defined as a VT with a uniform beat-to-beat surface QRS morphology. Polymorphic VT had a variable surface QRS morphology, and VF was defined as a rapid, disorganized rhythm without consistently identifiable complexes. A prespecified definition, i.e., standard inducibility, included sustained monomorphic VT induced with three or fewer extrastimuli, polymorphic VT induced with three or fewer extrastimuli, and VF induced with two or fewer ventricular extrastimuli. We also evaluated two alternative inducibility definitions, narrow inducibility (also prespecified), which included only sustained monomorphic VT, and a broad definition, which included the standard inducibility criteria plus VF induced with three extrastimuli.

Analysis of ICD therapy.   Patients in the MADIT II ICD study arm underwent quarterly ICD interrogation as well as interim visits if their symptoms dictated (1). Centers completed ICD follow-up data forms describing each ICD therapy (anti-tachycardia pacing [ATP] or shock) and downloaded ICD interrogation to discs. All ICD interrogation data were reviewed by an ICD end point committee composed of three of the authors (J.P.D., W.Z., and A.C.), who adjudicated each ICD event. The ICD end point committee was blinded to the results of the EP study results. We classified ICD therapy occurring for VT or VF as appropriate. Inappropriate therapy, due to atrial fibrillation, supraventricular tachycardia, or abnormal sensing, amounting to 35.4% of ICD events or therapy events that could not be classified (2.3% of total ICD events), was not included in this analysis.

The ICD end point committee reviewed all available information, including the ICD episode summary, stored intracardiac electrograms, and the enrollment center’s rhythm classification. If applicable, the event was considered in the context of other episodes for the same patient. The triggering arrhythmia was characterized as VT if the rate was between 140 and 250 beats/min and the complexes were uniform and regular. The arrhythmia was characterized as VF if the rate was >200 beats/min, if the rhythm was irregular, and if the electrogram complexes were indistinct. Polymorphic VT was included with VT when <200 beats/min and with VF if the rate was >200 beats/min. Ventricular tachycardia was differentiated from supraventricular tachycardia using standard criteria, including a change in electrogram morphology, sudden onset, and the atrial-ventricular relationship if atrial electrograms were available.

Statistical analysis.   The primary end point for this study was the incidence of spontaneous VT or fibrillation requiring treatment by the ICD in relationship to EP inducibility at electrophysiologic testing. Clinical characteristics of the inducible and noninducible groups were compared using the t test or F test, chi-square method, or Wilcoxon/Kruskal-Wallis rank sum test where appropriate. Kaplan-Meier survival curves with log-rank test evaluated univariate associations between EP inducibility and outcome events (12). To test the combined predictive value of inducibility plus QRS width, QRS duration was dichotomized into <0.12 s (n = 286) and QRS 0.12 s (n = 307). We used Cox proportional hazards modeling to analyze the association between inducibility and outcome after adjustment for clinical covariates (13). Significance was evaluated by p < 0.05.

	Results

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Clinical characteristics and inducibility findings.   Patients in the MADIT II ICD study arm who underwent electrophysiologic testing (n = 593) were very similar in measured clinical characteristics to those patients who did not undergo electrophysiologic testing (n = 126). Statistical differences present included more patients with a history of New York Heart Association functional class II to IV heart failure in the patients not undergoing an EP study (77% vs. 64%, p = 0.006) and more patients being on angiotensin receptor blockers (19% vs. 12%, p = 0.03). We compared the event rates in patients undergoing an EP study versus those who did not undergo an EP study. Twenty-four percent of patients undergoing an EP study versus 22% of those not undergoing an EP study reached the end point of VT or VF in follow-up. In addition, the EP study and no EP study groups did not differ in the subsequent occurrence of hospitalization for CHF, recurrent MI, cardiac death, sudden death, or total mortality.

Sustained monomorphic VT was induced in 169 (29%) patients, sustained polymorphic VT in 26 (4%) patients, VF with single or double extrastimuli in 16 (3%) patients, and VF with triple extrastimuli in 32 (5%) of patients. Thus, 29% of patients met narrow inducibility, 36% of patients met the standard inducibility definition, and 41% of patients had broadly defined inducibility.

The clinical characteristics for the noninducible and inducible patients by the type of arrhythmia induced are shown in Table 1. Sesselberg et al. (14) have previously shown that inducible patients, defined by the standard definition (Table 1, columns two and three), bore similar clinical characteristics to the noninducible patients (Table 1, columns four and five). They found that the inducible group had a slightly slower heart rate, a tendency towards lower New York Heart Association functional class status, a slightly higher percent of patients on angiotensin-converting enzyme inhibitor therapy and a slightly longer time from most recent MI to date of EP study as compared with the noninducible group (14). Using the more detailed breakdown of inducibility, i.e., Table 1, differences in clinical characteristics between the four subgroups regarding inducibility were similar to the previous analysis (14) and included interval after infarction, heart rate at enrollment, frequency of previous non-coronary artery bypass grafting revascularization, and treatment with angiotensin-converting enzyme inhibitors (Table 1).

View larger version (17K): [in this window] [in a new window]   Figure 1 Cumulative probability of first appropriate therapy for (A) ventricular tachycardia (VT) or ventricular fibrillation (VF); (B) VT only; and (C) VF only in patients with and without inducible arrhythmias according to standard definition of inducibility. Determination of p values was from the log rank test.

Unexpectedly, the noninducible group had a significantly higher cumulative likelihood of ICD treatment for a VF episode than the inducible group by log-rank analysis (p = 0.021) (Fig. 1C). The two-year Kaplan-Meier event rate for a first therapy for VF was 3.2% for the inducible patients and 8.6% for the noninducible patients.

The aforementioned univariate associations were tested in the multivariate Cox model adjusting for relevant clinical covariates (Table 2). According to this proportional hazards analysis, EP inducibility by the standard definition was not associated with the combined end point of VT or VF (hazard ratio [HR] 1.34; p = 0.094). However, ICD therapy for VT only was predicted by EP inducibility with a HR of 1.66 (p = 0.007), whereas inducibility was associated with a trend toward a decreased risk of therapy for VF (HR 0.41; p = 0.073) after adjusting for the same clinical variables.

View larger version (17K): [in this window] [in a new window]   Figure 2 Cumulative probability of first appropriate therapy for (A) ventricular tachycardia (VT) or ventricular fibrillation (VF); (B) VT only; and (C) VF only in patients with and without inducible arrhythmias according to narrow definition of inducibility. Determination of p values was from the log rank test.

Table 2 also shows results of multivariate Cox analyses testing the association between alternative definitions of EP inducibility and outcome. Therapy for VT or VF was significantly predicted by inducibility per the narrow definition (HR 1.56; p = 0.012), which was mainly the result of better performance of narrow inducibility for predicting ICD therapy for VT (HR 1.89; p = 0.001).

The relationship between the broad definition of inducibility and outcome (Table 2) did not show a significant association for the composite end point of VT plus VF. Broad inducibility was associated with VT (HR 1.63; p = 0.009) but not as strongly as narrow or even standard inducibility. Broad inducibility was associated with a lower risk of VF (HR 0.40; p = 0.049).

Analogous to refining the definition of inducibility, we examined whether the cycle length of the induced VT impacts on the subsequent likelihood for the occurrence of VT. Previous studies in the early post-MI period (15–17) have suggested that inducible monomorphic VT with a very short cycle length may be less likely to predict subsequent VT. We subdivided the arrhythmias categorized as inducible by cycle length of the induced arrhythmia. Figure 3 demonstrates that the induction of extremely rapid VT (<240 ms) did not predict the subsequent occurrence of VT better than noninducibility, whereas induction of VT with a CL 240 ms led to a higher chance of subsequent VT (p = 0.001).

View larger version (18K): [in this window] [in a new window]   Figure 3 Cumulative probability of first therapy for ventricular tachycardia (VT) in relationship to cycle length of induced VT. The cycle length of induced VT is divided at median value of 240 ms. The induction of a slower VT (240 ms) was more predictive of the subsequent clinical occurrence of VT than the induction of rapid VT (<240 ms), or noninducibility (solid line).

View larger version (21K): [in this window] [in a new window]   Figure 4 The cumulative probability of (A) mortality and (B) combined end point of ventricular tachycardia or ventricular fibrillation or death in patients with and without inducible tachyarrhythmias according to standard definition of inducibility.

View larger version (22K): [in this window] [in a new window]   Figure 5 The cumulative probability of the composite end point of appropriate implantable cardioverter-defibrillator (ICD) therapy for ventricular tachycardia (VT), appropriate ICD therapy for ventricular fibrillation (VF), or sudden death for inducible versus noinducible patients using (A) the standard definition and (B) the narrow definition.

View larger version (22K): [in this window] [in a new window]   Figure 6 Cumulative probability of first appropriate therapy for either ventricular tachycardia (VT) or ventricular fibrillation (VF) in patients with and without inducible arrhythmias according to standard definition of inducibility in (A) patients with QRS <0.12 s and (B) patients with QRS 0.12 s. Determination of p values was from the log rank test.

	Discussion

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Previous studies have found that EP inducibility is best defined by the induction of sustained monomorphic VT, as opposed to VF (4,18–20). Thus, our finding that VT inducibility predicts the occurrence of VT but not VF is not entirely unexpected. In fact, restricting the definition of inducibility to only include induction of monomorphic VT (the narrow definition) improves the correlation of inducibility with the subsequent occurrence of VT (Fig. 2B vs. Fig. 1B). Conversely, the broad definition was least strongly associated with subsequent VT episodes. It appears, therefore, that future studies seeking to predict VT events should use this "narrow" definition of inducibility. Moreover, induction of ventricular arrhythmia with a cycle length 240 ms was associated with a higher incidence of VT events in follow-up (Fig. 3) than induction of ventricular arrhythmia with a cycle length shorter than 240 ms. Although inducibility correlates with subsequent VT, only 39% of inducible patients were estimated to experience a clinical VT episode by three years, compared with 25% of noninducible patients.

Inducible MADIT II study patients tended toward a lower likelihood of experiencing a spontaneous clinical ventricular fibrillation episode requiring ICD intervention (Figs. 1C and 2C). However, using multivariate analysis, we discovered that inducibility was not significantly associated with a reduced incidence of VF except by the broad definition (Table 2). At three years, 9% of noninducible patients required treatment for at least one episode of clinical ventricular fibrillation by their defibrillator compared with 5% of inducible patients, using the standard inducibility definition. Although this inverse relationship or trend is seemingly paradoxical, EP inducibility relates best to the stable, reentrant arrhythmia monomorphic VT and less well to VF. Ventricular fibrillation, especially in the setting of advanced congestive heart failure, may rely on focal or triggered mechanisms in addition to re-entry (21–24). Ischemia is very likely to be implicated in spontaneous VF episodes in patients with coronary artery disease (25).

Indeed, a recent paper from the MADIT II study database found that patients who experienced VF in follow-up were more likely than VT patients or patients without ICD therapy to be hospitalized for congestive heart failure (26). Such arrhythmias brought on by advanced congestive heart failure are perhaps more likely in patients having an ejection fraction 0.30. Thus, the presence of advanced congestive heart failure predicted VF as opposed to VT in multivariate analysis whereas inducibility was inversely related to subsequent VF. Electrophysiologic inducibility evaluates the substrate for a reentrant arrhythmia, which is one contributor to the risk for sudden death, along with triggering factors, such as premature beats, autonomic tone and other factors. This inverse relation between inducibility and occurrence of clinical ventricular fibrillation in a way is not paradoxical when seen in this context. Thus, patients who have a triggering event and go on to have a clinical ventricular arrhythmia are more likely to have VT as their arrhythmia if they are found to have a substrate for VT at EP study, whereas those without such a demonstrated substrate would be more likely to have clinical VF if a triggering event initiated an arrhythmia.

Recent work has ascribed VF to a two-part process involving VT (spiral wave) initiation, and then spiral wave disorganization dependent upon the slope of the action potential duration-diastolic interval relationship, also called the restitution slope (24,27,28), although this concept is controversial (29–32). One could speculate that if stable monomorphic VT were induced in the EP laboratory, and did not degenerate to VF in that setting, that a spontaneous ventricular arrhythmia might be less likely to (rapidly) degenerate into VF. Patients who maintain a stable rotor or reentry circuit in the EP laboratory could conceivably have a different restitution slope than those who do not exhibit inducible monomorphic VT. Inducibility of a monomorphic VT might identify a patient whose arrhythmia is less likely to deteriorate into VF (at least early after onset).

Although these data demonstrate shortcomings of EP inducibility, recent data from the MUSTT study are in fact quite concordant (5). In the MUSTT study (5), the two-year total mortality in patients with an ejection fraction <0.30 was 33% in inducible patients and 26% in noninducible patients, yielding an unadjusted risk ratio of 1.27, which is very similar to the HR of 1.34 for the combined VT and VF end point we found (Table 2). Using the MUSTT study data on arrhythmic death or cardiac arrest also yields a similar unadjusted risk ratio of 1.4 for inducibility in the low ejection fraction subgroup (5). In the MUSTT study, EP inducibility was less predictive of mortality or arrhythmic death in the lower ejection fraction strata, the MADIT II-like subset of the MUSTT study, than in the patients whose ejection fraction was between 0.30 and 0.40. Unlike the MADIT II study, the relative contribution of VT as opposed to VF to sudden death mortality could not be differentiated in the MUSTT study because noninducible patients and nontreatment arm patients did not receive an ICD. Unlike the data in this MADIT II substudy or those from the MUSTT study, many earlier publications supporting the role of EP testing suffer one or more limitations, including the use of sudden death as opposed to total mortality as an end point, inhomogeneous populations with varying severity of structural heart disease, and differing treatments for inducible and noninducible patients at a time before recognition of the proarrhythmic effects of pharmacologic agents (11,15–18,33).

In the MADIT II study, inducibility did not correlate with increased mortality; in fact inducible patients tended to have a lower mortality rate (Fig. 4A), although this finding was of only borderline significance using multivariate analysis (Table 2). The (slightly) reduced, as opposed to increased mortality associated with inducibility in this study, is not paradoxical because both inducible and noninducible MADIT II study groups were treated with an ICD as opposed to the MUSTT study. Electrophysiologic testing did predict a greater occurrence of VT, but VT is virtually always successfully treated by the ICD and, thus, inducibility was not associated with increased mortality. Likewise, in the AVID study inducibility did not predict an inferior survival (34).

The imperfect predictability of EP testing shown in this study is not attributable to differences with previously used EP protocols. The Electrophysiologic Study Versus Electrocardiographic Monitoring (ESVEM) trial, which found EP inducibility poorly predictive, was criticized for the EP protocol being insufficiently aggressive. In the MADIT II study, however, a rigorous induction protocol consisting of triple extrastimuli at two RV sites and two cycle lengths was used. Attesting to the aggressive nature of the protocol, the MADIT II study investigators found a relatively high inducibility rate of 36% (211 of 593), similar to the 35% inducibility reported in the MUSTT study. Nevertheless, noninducible patients had 64% as great a chance of experiencing VT by three years as did inducible patients (Fig. 1B), suggesting that this well-validated protocol is relatively insensitive in patients with an ejection fraction <0.30.

Study limitations.   This report has several possible limitations, one of which is the lack of availability of ICD programming details, which was left to investigator preference in the MADIT II study. Theoretically, this could affect the degree of detection of VT. For instance, if a slow VT were induced at EP study, this could have encouraged the investigator to program a slow detection rate, which could increase the yield of VT events in follow-up. This could conceivably increase the correlation between VT inducibility and VT events. It appears that this would have been a very infrequent occurrence, because only five patients had inducible VT at a rate <170 beats/min. On the other hand, alterations in programming would be very unlikely to have affected the detection of VF events, leading to the inverse relation between inducibility and VF events. Varying the lower zone detection rate would not effect detection of VF. The detection time for VF is not programmable for the ICD devices used in this study. A self-terminating arrhythmia that did not lead to ICD therapy was not classified as either VT or VF in this study.

A second potential limitation is that not all patients underwent an EP study. As noted previously, the clinical characteristics of patients having an EP study versus those not having an EP study did not differ in clinically relevant characteristics. Moreover, patients undergoing an EP study had similar event rates for VT or VF, CHF hospitalization or death, in follow-up to those patients not undergoing an EP study. Third, the findings concerning the predictive value of the EP test for VT or VF are specific to the EP testing protocol used. Protocols using more than three extrastimuli, which may induce VT in a greater proportion of patients (35–37) or other variations could possibly have led to different findings. As noted previously, the MUSTT study, the largest other study prospectively after patients with remote MI, used a virtually identical protocol to the MADIT II study protocol. In addition, we found that the induction of VT tended to be inversely related to the occurrence of VF in follow-up, no matter which inducibility definition was used. Fourth, concerning the tendency of noninducible patients to have an increased likelihood of VF, the classification of events as VT or as VF relies on arbitrary definitions and does involve potentially subjective electrogram data interpretation. Thus, one should not overinterpret the tendency toward more VF in the noninducible group, a trend that was not statistically significant by multivariate analysis. Finally, these data pertain to the relationship between inducibility and subsequent VT or VF episodes. The occurrence of VT or VF treatment by an ICD should not be equated with a mortal event because some episodes undoubtedly would have terminated spontaneously if the ICD had not intervened. The magnitude of this effect is observed when comparing the incidence of a first ICD therapy for VT or VF, 27% at two years (26), with the difference in total mortality between ICD and conventional groups, 6% at two years (38).

Conclusions.   We found a limited predictive value of EP testing using a stimulation protocol using up to three extrastimuli at two sites for ruling out subsequent VT or VF events. Although noninducible patients in the MADIT II study population do have a slightly lower risk of the combined arrhythmic end point of VT or VF, their risk of VF tended to be higher than in inducible patients. Thus, for postinfarction patients with an ejection fraction of 0.30, noninducibility at EP testing does not equate with a low arrhythmic risk. This study does not support excluding noninducible patients from ICD therapy.

	Acknowledgments

 
We acknowledge the assistance provided by Ms. Jodie Palma, Tariq Salam, MD, and Yong-Keun Cho, MD, with ICD interrogation analysis; Mr. Thomas Ross for assistance with preparation of the manuscript; and Ms. Hongyue Wang for statistical support. The authors especially acknowledge the MADIT II study patients, coordinators, and investigators and the members of the MADIT II Executive Committee.

	Footnotes

 
Supported by a research grant from Guidant Corporation, St. Paul, Minnesota, to the University of Rochester School of Medicine and Dentistry.

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