Portal de Periódicos da CAPES

Diagnostic Utility of a Novel Leadless Arrhythmia Monitoring Device

2013; Elsevier BV; Volume: 112; Issue: 4 Linguagem: Inglês

10.1016/j.amjcard.2013.04.017

1879-1913

Mintu P. Turakhia, Donald D. Hoang, Peter Zimetbaum, Jared D. Miller, Victor F. Froelicher, Uday Kumar, Xiangyan Xu, Felix Yang, Paul A. Heidenreich,

Heart Rate Variability and Autonomic Control

Although extending the duration of ambulatory electrocardiographic monitoring beyond 24 to 48 hours can improve the detection of arrhythmias, lead-based (Holter) monitors might be limited by patient compliance and other factors. We, therefore, evaluated compliance, analyzable signal time, interval to arrhythmia detection, and diagnostic yield of the Zio Patch, a novel leadless, electrocardiographic monitoring device in 26,751 consecutive patients. The mean wear time was 7.6 ± 3.6 days, and the median analyzable time was 99% of the total wear time. Among the patients with detected arrhythmias (60.3% of all patients), 29.9% had their first arrhythmia and 51.1% had their first symptom-triggered arrhythmia occur after the initial 48-hour period. Compared with the first 48 hours of monitoring, the overall diagnostic yield was greater when data from the entire Zio Patch wear duration were included for any arrhythmia (62.2% vs 43.9%, p <0.0001) and for any symptomatic arrhythmia (9.7% vs 4.4%, p <0.0001). For paroxysmal atrial fibrillation (AF), the mean interval to the first detection of AF was inversely proportional to the total AF burden, with an increasing proportion occurring after 48 hours (11.2%, 10.5%, 20.8%, and 38.0% for an AF burden of 51% to 75%, 26% to 50%, 1% to 25%, and <1%, respectively). In conclusion, extended monitoring with the Zio Patch for ≤14 days is feasible, with high patient compliance, a high analyzable signal time, and an incremental diagnostic yield beyond 48 hours for all arrhythmia types. These findings could have significant implications for device selection, monitoring duration, and care pathways for arrhythmia evaluation and AF surveillance. Although extending the duration of ambulatory electrocardiographic monitoring beyond 24 to 48 hours can improve the detection of arrhythmias, lead-based (Holter) monitors might be limited by patient compliance and other factors. We, therefore, evaluated compliance, analyzable signal time, interval to arrhythmia detection, and diagnostic yield of the Zio Patch, a novel leadless, electrocardiographic monitoring device in 26,751 consecutive patients. The mean wear time was 7.6 ± 3.6 days, and the median analyzable time was 99% of the total wear time. Among the patients with detected arrhythmias (60.3% of all patients), 29.9% had their first arrhythmia and 51.1% had their first symptom-triggered arrhythmia occur after the initial 48-hour period. Compared with the first 48 hours of monitoring, the overall diagnostic yield was greater when data from the entire Zio Patch wear duration were included for any arrhythmia (62.2% vs 43.9%, p <0.0001) and for any symptomatic arrhythmia (9.7% vs 4.4%, p <0.0001). For paroxysmal atrial fibrillation (AF), the mean interval to the first detection of AF was inversely proportional to the total AF burden, with an increasing proportion occurring after 48 hours (11.2%, 10.5%, 20.8%, and 38.0% for an AF burden of 51% to 75%, 26% to 50%, 1% to 25%, and 1 clinical indication, all indications were retained for analysis.Arrhythmia adjudication was performed and coded using a 2-step process. First, the servicer applied a digital signal processing algorithm to continuously recorded ECG data to identify potential arrhythmia episodes. The algorithm, cleared using the 510(k) method by the Food and Drug Administration for clinical use, detects potential arrhythmias by detection of the heart rate, irregularity, and morphology. The algorithm then uses the heart rate increase from the preceding portion of heart rate regularity (sinus rhythm) to confirm a candidate episode. Next, trained and certified cardiovascular technicians employed by the servicer re-examined the detected arrhythmia episodes to confirm the diagnoses and to classify the arrhythmia where appropriate. Because the algorithm assigns an arrhythmia classification to every portion of the continuous recording, a second detected rhythm (including artifact) occurring in the middle of an arrhythmia event can cause the event to be classified as multiple discrete episodes. These episodes are reclassified on review by technicians to a single arrhythmia event, when appropriate. Arrhythmia adjudication was performed for clinical findings by technicians with no knowledge of the present study.The episodes were classified into 3 categories according to the type of arrhythmia: first occurrence, first symptomatic occurrence (if occurring 45 seconds before or after patient triggering), and longest duration. The arrhythmias were classified into the following independent, but not mutually exclusive, categories: atrial fibrillation (AF), pause >3 seconds, second-degree Mobitz II or complete atrioventricular block, SVT, VT, and symptomatic bradycardia. The AF burden was further calculated as the percentage of analyzable time. We segmented the AF burden into the following categories of paroxysmal AF (<1%, 1% to 25%, 26% to 50%, 51% to 75%, and 76% to 99%) and chronic AF (100%). For analytical purposes, we did not count chronic AF as an arrhythmia event or toward the diagnostic yield. This method has been shown to have excellent agreement with simultaneously acquired Holter recordings for the detection of AF (κ = 1.0) and quantification of AF burden (r = 0.96).10Rosenberg M.A. Samuel M. Thosani A. Zimetbaum P.J. Use of a noninvasive continuous monitoring device in the management of atrial fibrillation: a pilot study.Pacing Clin Electrophysiol. 2013; 36: 328-333Crossref PubMed Scopus (109) Google ScholarThe total wear time was calculated from the point of activation to the point of the last recorded analyzable signal. Wear time end points of 2, ≥6, and ≥13 days were used to mark the comparison points of the typical 48 hours (Holter), 1 week, and 2 weeks of ECG monitoring. The device analyzable time fraction was defined as the proportion of the total wear time that the ECG signal is interpretable (sufficiently free of noise) by the arrhythmia detection algorithm.Descriptive statistics were performed using STATA, version 11 (StataCorp, College Station, Texas) for analysis. Continuous variables and proportions were compared using the t test and chi-square test, respectively, and p 48 hours, 74.3% wore the device ≥6 days, and 16.1% wore the device ≥13 days. The median analyzable time, expressed as a percentage of the total wear time, was 99% (interquartile range 94% to 99%); 87.1% of the patients had an analyzable time the equivalent of ≥22 hr/day. No significant difference was found in age or wear time between the genders.The provider-reported clinical indications are listed in Table 1; the most prevalent indications were palpitations, atrial fibrillation, and syncope or presyncope.Table 1Provider-reported clinical indicationsVariablePatients (n)Palpitations10,786 (40.3)AF6,493 (24.3)Syncope or presyncope4,029 (15.1)Bradycardia964 (3.6)SVT570 (2.1)Unspecified tachycardia547 (2.1)VT187 (0.7)Pause48 (0.2)AV block∗Second-degree Mobitz II or third-degree AV block.44 (0.2)Polymorphic VT, torsade de pointes, VF6 (0.0)Other indications†Providers reported unspecified arrhythmias, nonarrhythmic cardiovascular indications, or no indication, exclusive of indications listed.3,557 (13.4)Data in parentheses are percentages.Clinical indications for ambulatory electrocardiography monitoring were ascertained from a free-text variable provided by the ordering provider; patients could have >1 clinical indication for cardiac monitoring.AV = atrioventricular; VF = ventricular fibrillation.∗ Second-degree Mobitz II or third-degree AV block.† Providers reported unspecified arrhythmias, nonarrhythmic cardiovascular indications, or no indication, exclusive of indications listed. Open table in a new tab The overall prevalence of single and multiple arrhythmias is listed in Table 2. Arrhythmias, not counting chronic AF, were detected in 16,142 patients (60.3%). Of all the patients, 12,298 (46.0%) had a single arrhythmia and 3,083 (11.5%) had multiple arrhythmias (not including chronic AF). Chronic AF was present in 2,003 patients (7.5%), and 761 of these patients (2.8%) had other arrhythmias, in addition to chronic AF.Table 2Detected arrhythmiasVariablePatients (n)All Patients With Arrhythmia (%)Women (%)Detected arrhythmias (excluding chronic AF)16,142 (60.3)100.052.0Single arrhythmias (excluding chronic AF)12,298 (46.0)76.256.5Multiple arrhythmias (excluding chronic AF)3,083 (11.5)19.139.7Chronic AF2,003 (7.5)—39.4 No other arrhythmias1,242 (4.6)—45.2 ≥1 Other arrhythmias761 (2.8)4.730.0No arrhythmia10,609 (39.7)—58.3Data in parentheses are percentages.Arrhythmias, excluding chronic AF, were detected in 60.3% of patients; men were more likely than women to have chronic AF, ≥1 arrhythmias in addition to chronic AF, or multiple arrhythmias (excluding chronic AF). Open table in a new tab The distribution and time to the detection of each category of asymptomatic arrhythmias are listed in Table 3. Overall, the mean and median time to the first arrhythmia was 1.7 ± 2.2 days and 0.8 day (interquartile range 0.2 to 2.4), and the mean and median time to the first symptom-triggered arrhythmia was 3.0 ± 2.9 days and 2.1 days (interquartile range 0.8 to 4.4), respectively. Among the patients with arrhythmias, the most common was SVT.Table 3Prevalence of detected arrhythmiasVariableAll Patients (%)All Patients With Arrhythmia (%)Women (%)Time to First ArrhythmiaTime to First Symptomatic ArrhythmiaMean ± SD (days)Median (IQR)Occurring After 48 hrs (%)Mean ± SD (days)Median (IQR)Occurring After 48 hrs (%)Any arrhythmia60.3100.052.01.7 ± 2.20.8 (0.2–2.4)29.93.0 ± 2.92.1 (0.8–4.4)51.1Atrial fibrillation burden (%)17.328.741.01.4 ± 2.10.4 (0.1–1.8)23.42.7 ± 2.81.8 (0.6–4.0)47.2 <12.94.846.22.2 ± 2.71.2 (0.3–3.3)38.03.8 ± 3.62.7 (0.9–5.7)57.4 1–254.87.941.11.2 ± 1.80.4 (0.1–1.5)20.83.2 ± 2.92.3 (0.9–4.7)56.5 26–501.32.140.40.7 ± 1.30.1 (0–0.6)10.52.6 ± 2.81.5 (0.4–3.9)40.4 51–750.61.035.40.6 ± 1.2<0.1 (0–0.6)11.22.2 ± 2.21.6 (0.6–3.3)39.3 76–990.30.443.00.2 ± 0.4 3 s3.76.138.92.8 ± 2.91.7 (0.6–4.0)46.63.0 ± 3.11.8 (0.8–5.1)42.9Mobitz II or complete AV block1.42.337.32.2 ± 2.91.0 (0.3–2.7)34.12.3 ± 2.81.0 (0.6–3.1)36.6SVT (beats) ≥445.976.156.11.9 ± 2.31.0 (0.3–2.6)32.33.4 ± 3.02.5 (1.1–5.1)59.1 ≥830.851.157.11.4 ± 1.90.6 (0.2–1.8)23.33.3 ± 2.92.3 (1.0–4.9)58.0VT (beats) ≥412.320.436.13.4 ± 3.22.6 (0.9–5.2)58.33.7 ± 3.13.0 (1.1–5.6)63.3 ≥84.77.834.73.0 ± 3.02.1 (0.5–4.6)51.23.6 ± 3.22.7 (1.0–5.6)61.0Excluding chronic AF, the mean time to first arrhythmia and first symptom-triggered arrhythmia was 1.7 ± 2.2 days and 3.0 ± 2.9 days, respectively; the median time to first arrhythmia and first symptom-triggered arrhythmia was 0.8 day (IQR 0.2–2.4) and 2.1 days (IQR 0.8–4.4), respectively; 29.9% of first arrhythmias and 51.1% of first symptom-triggered arrhythmias occurred >48 hours after the start of monitoring; patients with a low AF burden had a longer time to detection; 27.4% of patients with an AF burden ≤25% had their first AF episode beyond 48 hours, and 56.8% of patients with an AF burden of ≤25% had their first symptomatic AF episode beyond 48 hours.AV = atrioventricular; IQR = interquartile range. Open table in a new tab The distribution of the time to the first arrhythmia and first symptom-triggered arrhythmia is listed in Table 3. Overall, the variation in the time to the first event for all arrhythmias types was wide. Among the patients with arrhythmias, 29.9% had their first arrhythmia occur >48 hours from the start of monitoring. Among the patients with symptom-triggered arrhythmias (Table 3), 51.1% occurred >48 hours from the start of monitoring (Table 3). The diagnostic yield of pauses, Mobitz II or complete atrioventricular block, SVT, and VT all improved with extended monitoring (Table 3).Excluding chronic AF, the time to the detection of the first AF was 2.7 ± 2.8 days. The time to AF detection was inversely proportional to the total AF burden. As the burden of AF decreased, the mean time to the first detection increased, with an increasing proportion occurring after 48 hours, ranging from 0.2 ± 0.4 days for an AF burden of 76% to 99% (1.4% after 48 hours) to 2.2 ± 2.7 days for an AF burden <1% (38.0% after 48 hours; Figure 2). The findings were similar for the time to the first symptom-triggered AF episode.Figure 2Time to first AF and first symptomatic AF stratified by AF burden. The bottom, middle, and top lines of each box correspond to the 25th, 50th (median), and 75th percentile, respectively. The whisker caps mark 1.5 times the interquartile range below the 25th percentile and 1.5 times the interquartile range above the 75th percentile. For all nonchronic AF, the time to first detection was 2.7 ± 2.8 days. The smaller the AF burden, the longer the mean time to first detection. The mean time to the first diagnosis of AF ranged from 0.2 ± 0.4 day for an AF burden of 76% to 99% (1.4% after 48 hours) to 2.2 ± 2.7 days for an AF burden <1% (38.0% after 48 hours). Likewise, a longer time to the first symptomatic episode of AF was associated with a decreased AF burden. The mean time to the first diagnosis of symptomatic AF ranged from 1.8 ± 2.9 days for an AF burden of 76% to 99% (23.1% after 48 hours) to 3.8 ± 3.6 days for an AF burden 13 days). The reasons for this were multifactorial, including a shift in the manufacturer's recommendations from 7 days of monitoring to 14 days during the study period and variations in provider preferences or instructions. The mean wear time increased from 7 to 9 days during the study period. The Zio Patch's small size, absence of wired leads, and water resistance could have contributed to the patient compliance and signal quality.For all arrhythmia types, the diagnostic yield increased with monitoring beyond 48 hours. Among patients with paroxysmal AF, the time to the detection of the first AF episode increased as the total AF burden decreased. Our findings are consistent with those from a small, single-center study of patients with known AF who concurrently wore Zio Patches and 24-hour Holter monitors.10Rosenberg M.A. Samuel M. Thosani A. Zimetbaum P.J. Use of a noninvasive continuous monitoring device in the management of atrial fibrillation: a pilot study.Pacing Clin Electrophysiol. 2013; 36: 328-333Crossref PubMed Scopus (109) Google Scholar They found that compared with 24-hour Holter monitoring, AF events were identified in 18 of 70 subjects after Zio Patch monitoring; 21 patients had a change in clinical management because of reclassification by the Zio results. Therefore, these findings could have significant implications for minimizing repeat testing, assessing treatment response, and expediting appropriate therapy, such as anticoagulation.Previous studies have also shown that continuous monitoring with implantable loop recorders increase the diagnostic yield for AF recurrence after catheter ablation, cardioversion, or initiation of antiarrhythmic drug therapy.14Hanke T. Charitos E.I. Stierle U. Karluss A. Kraatz E. Graf B. Hagemann A. Misfeld M. Sievers H.H. Twenty-four-hour Holter monitor follow-up does not provide accurate heart rhythm status after surgical atrial fibrillation ablation therapy: up to 12 months experience with a novel permanently implantable heart rhythm monitor device.Circulation. 2009; 120: S177-S184Crossref PubMed Scopus (104) Google Scholar, 15Charitos E.I. Stierle U. Ziegler P.D. Baldewig M. Robinson D.R. Sievers H.H. Hanke T. A comprehensive evaluation of rhythm monitoring strategies for the detection of atrial fibrillation recurrence: insights from 647 continuously monitored patients and implications for monitoring after therapeutic interventions.Circulation. 2012; 126: 806-814Crossref PubMed Scopus (140) Google Scholar However, our data have indicated that ≤14 days of monitoring can substantially improve AF detection in paroxysmal AF, even when the observed AF burden was <15%. Therefore, cutaneous patch-based monitoring should be investigated further as a potential alternative before implantation of an implantable loop recorder or mobile cardiac outpatient telemetry, particularly if real-time transmission, which is not available with the Zio Patch, is not required.Our study had several limitations. First, our retrospective study of patients who received a Zio Patch for clinical indications might not reflect the epidemiology of all patients presenting for ECG monitoring, because clinical suspicion of arrhythmia frequency could have informed the device selection at certain sites. Second, arrhythmia episodes of relatively short duration were included in our SVT and VT categorizations. It is possible that the identification of some of these episodes, even if detected with extended monitoring, might not be clinically important. However, the findings for symptom-triggered arrhythmias of short duration were significant and consistent with the overall results. Finally, although previous studies have shown excellent agreement between simultaneous Zio and Holter recordings for AF,10Rosenberg M.A. Samuel M. Thosani A. Zimetbaum P.J. Use of a noninvasive continuous monitoring device in the management of atrial fibrillation: a pilot study.Pacing Clin Electrophysiol. 2013; 36: 328-333Crossref PubMed Scopus (109) Google Scholar differences in signal processing and detection algorithms could have led to variation in the agreement of arrhythmia detection and classification across the Zio Patch and other monitoring devices, although the variation would be expected to be low.DisclosuresDr. Kumar is the founder and former chief medical officer of iRhythm Technologies, Inc. (San Francisco) and retains a significant equity share in the company. The remaining authors have no conflicts of interest to disclose. Ambulatory electrocardiography is a widely used diagnostic tool to detect arrhythmias for a variety of symptoms and conditions.1Crawford M.H. Bernstein S.J. Deedwania P.C. DiMarco J.P. Ferrick K.J. Garson Jr., A. Green L.A. Greene H.L. Silka M.J. Stone P.H. Tracy C.M. Gibbons R.J. Alpert J.S. Eagle K.A. Gardner T.J. Gregoratos G. Russell R.O. Ryan T.H. Smith Jr., S.C. ACC/AHA guidelines for ambulatory electrocardiography: a report of the American College of Cardiology/American Heart Association Task Force on Practice Guidelin