1-s2.0-S1547527117312407-main
.pdfAccepted Manuscript
A novel algorithm increases the delivery of effective cardiac resynchronization therapy during atrial fibrillation: The CRTee randomized cross-over trial
Christopher J. Plummer, PhD, FRCP, Christopher M. Frank, MD, Zsolt Bári, MD, Yahya S. Al Hebaishi, MD, Ruth Nicholson Klepfer, PhD, Robert W. Stadler, PhD, Subham Ghosh, PhD, Shufeng Liu, MS, Suneet Mittal, MD
PII: |
S1547-5271(17)31240-7 |
DOI: |
10.1016/j.hrthm.2017.10.026 |
Reference: |
HRTHM 7359 |
To appear in: |
Heart Rhythm |
Received Date: 3 May 2017
Please cite this article as: Plummer CJ, Frank CM, Bári Z, Al Hebaishi YS, Klepfer RN, Stadler RW, Ghosh S, Liu S, Mittal S, A novel algorithm increases the delivery of effective cardiac resynchronization therapy during atrial fibrillation: The CRTee randomized cross-over trial, Heart Rhythm (2017), doi: 10.1016/j.hrthm.2017.10.026.
This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final form. Please
note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain.
ACCEPTED MANUSCRIPT
1A novel algorithm increases the delivery of effective cardiac resynchronization therapy during
2atrial fibrillation: The CRTee randomized cross-over trial
3Short Title: New Algorithm Increases CRT During AF
4 Christopher J. Plummer, PhD, FRCP1*; Christopher M. Frank, MD2; Zsolt Bári, MD3; Yahya S. Al
5 Hebaishi, MD4; Ruth Nicholson Klepfer, PhD5; Robert W. Stadler, PhD5; Subham Ghosh, PhDT5;
6Shufeng Liu, MS5; Suneet Mittal, MD6
|
CRIP |
7 |
1Freeman Hospital, Newcastle upon Tyne, UK; 2Mount Carmel Clinical Cardiovascular Specialists, |
8 |
Westerville, Ohio; 3Clinical Electrophysiology, Department of Cardiology, Medical Centre, Hungarian |
9 |
Defense Forces, Budapest, Hungary; 4 Adult Cardiology Department, Prince Sultan Cardiac Centre |
10(PSCC), Prince Sultan Military Medical City, Riyadh, Saudi Arabia; 5Medtronic, plc, Mounds View,
11Minnesota; 6Valley Health System, Ridgewood, New Jersey
12 |
|
13 |
*Address for Correspondence: |
14 |
Christopher J. Plummer, PhD, FRCP |
|
ACCEPTED |
15 |
Freeman Hospital |
16 |
Newcastle upon Tyne, United Kingdom |
17 |
Telephone: +44 191 2336161 |
18 |
E-mail: Chris.Plummer@nuth.nhs.uk |
19 |
|
20Word Count: 4515
21Disclosures: CJP: Compensation for services: Medtronic, CMF: Nothing to disclose, ZB: Nothing to
22disclose, YAH: Nothing to disclose, RNK: Employment: Medtronic, RS: Employment: Medtronic, SG:
23Employment: Medtronic, SL: Employment: Medtronic, SM: Compensation for services: Medtronic
24
25 Funding: The CRTee study was funded by Medtronic plc, ClinicalTrials.gov Identifier: NCT02222818.
26
Page 1 of 21
ACCEPTED MANUSCRIPT
27Abstract
28Background:
29Cardiac resynchronization therapy (CRT) requires a high % of ventricular pacing (%Vp) to maximize
30its clinical benefits. Atrial fibrillation (AF) has been shown to reduce %Vp in CRT due to competition
31with irregular intrinsic atrio-ventricular (AV) conduction. We report the results of a prospectiveT
32randomized cross-over trial evaluating the amount of effective CRT deliveredCRIPduring AF with a novel
33algorithm (eCRTAF).
34Objective:
35To determine whether eCRTAF increases the amountMANUSof effective CRT delivered during AF when
36compared to a currently available rate regularization algorithm.
37Methods: Patients previously implanted with a CRT-D device, with a history of AF and intact AV
38conduction, received up to 4 weeks of control (Conducted AF Response) and up to 4 weeks of
39eCRTAF in a randomized sequence. The % effective CRT (eCRT) pacing, which excludes beats without
40LV capture, %VpACCEPTEDand mean heart rate (HR) were recorded during AF and sinus rhythm.
41Results:
42The eCRTAF algorithm resulted in a significantly higher %eCRT during AF than Control (87.8±7.8 % vs
4380.8±14.3%, p < 0.001) and %Vp during AF than Control (90.0±5.9% vs 83.2±11.9%, p<0.001) with a
44small but statistically significant increase in mean HR of 2.5 bpm (79.5±9.7 vs 77.0±9.9 bpm,
45p<0.001).
46Conclusions:
47In a cohort of CRT patients with a history of AF, eCRTAF significantly increased the %eCRT pacing and
48%Vp during AF with a small increase in mean HR. This algorithm may represent a novel non-invasive
49method of significantly increasing effective CRT delivery during AF, potentially improving CRT
50response.
51Key Words: Biventricular pacing, Cardiac Resynchronization Therapy, Heart Failure, Effective Pacing,
52Atrial Fibrillation
Page 2 of 21
ACCEPTED MANUSCRIPT
53
54Introduction
55Cardiac resynchronization therapy (CRT) provides significant benefits in both morbidity and mortality
56for heart failure patients with reduced ejection fraction and a wide QRS. Achieving these benefits
57requires a high % of ventricular pacing (%Vp) - retrospective analyses have shown that evenTsmall
58reductions in CRT pacing are associated with increased morbidity and mortality.CRIP1-3 The reduced
59efficacy of CRT in some patients with atrial fibrillation (AF) has been attributed to reduced %Vp due
60to competition with irregular intrinsic atrio-ventricular (AV) conduction which can lead to pacing
61refractory myocardium. Some CRT devices employMANUSrate regularization algorithms during AF
62(Conducted AF Response – Medtronic plc; Ventricular Rate Regulation – Boston Scientific) to
63modulate pacing rate in an attempt to reduce the loss of %Vp.4 However, the performance of these
64algorithms has not been evaluated in a CRT patient population.
65Accurately determining the amount of CRT being delivered is made even more difficult because
66standard deviceACCEPTEDpacing counters cannot distinguish left ventricular (LV) pacing that is delivered to
67refractory myocardium (i.e., pseudofusion) from LV pacing that succeeds in depolarizing a significant
68portion of the left ventricle (i.e., effective CRT pacing). A new device-based diagnostic, % effective
69CRT (%eCRT) pacing, quantifies actual CRT delivery using beat-to-beat analysis of the paced
70morphology of the unipolar LV electrogram. This diagnostic has been validated against the 12-lead
71ECG and was shown to accurately identify 98.2% of effectively paced beats.5 When applied to a
72general CRT patient population in an observational study (N=57), the diagnostic demonstrated that
73%Vp over-estimated the %eCRT pacing by an average of 7.3 ± 22.2% (p<0.05).6
74A novel algorithm has been developed to increase the amount of effective CRT delivered during AF
75(eCRTAF). Using the %eCRT diagnostic, it monitors beat-to-beat LV capture during AF and adjusts
76pacing rate to maximize % effective CRT pacing while minimizing any increase in pacing rate. We
77report the results of a prospective randomized cross-over trial evaluating the amount of effective
78CRT delivered during AF with this new algorithm.
Page 3 of 21
ACCEPTED MANUSCRIPT
79
80Methods
81The CRTee download study was a prospective randomized cross-over study enrolling CRT patients
82with a history of atrial fibrillation. The study compared a commercially available algorithm
83(Conducted AF Response, CAFR) with a novel algorithm (EffectivCRT During AF, eCRTAF).TThe primary
84end-point was %eCRT during AF with additional endpoints of %Vp during AFCRIPand mean heart rate
85(HR) during AF. Cardiovascular adverse events were also recorded. An additional acute comparison
86of no algorithm, CAFR and eCRTAF was performed in those subjects who were in AF at the time of
87the office visit. MANUS
88Subjects
89Participants provided fully informed written consent and were enrolled by site personnel trained in
90the study and designated for this task.
91The study recruited patients with a previously implanted Medtronic Viva or Brava CRT-D device. The
92inclusion/exclusionACCEPTEDcriteria included:
93Inclusion
94∙ A Viva or Brava device had been implanted for at least 30 days.
95∙ AF Burden: At least 6 days with at least 4 hours of AF during a 4 week period occurring
96within 90 days OR clinical diagnosis of permanent AF (when no device data were available).
97∙ Demonstrated history of being able to complete the Left Ventricular Capture Management
98nightly test.
99∙ Less than or equal to 97% Vp during AF.
100Exclusion
101∙ AV node ablation
102∙ Complete or 3rd degree heart block
103∙ Myocardial infarction within 30 days
Page 4 of 21
ACCEPTED MANUSCRIPT
104Study Design
105The study outline is shown in Figure 1. Baseline data were collected at the phase 1 visit, and the
106eCRTAF algorithm and the ambulatory diagnostics of %eCRT pacing were downloaded to the CRT-D
107devices using a modified Model 2090 programmer. The patient was then randomized 1:1 to either
108Control (i.e., CAFR algorithm) or eCRTAF first. Randomization allocations were stratified Tby site and
109generated by the study sponsor. Each week, the subject completed a remoteCRIPtransmission. The
110phase 2 visit was scheduled when the programmed algorithm had been active for at least two hours
111or 4 weeks had passed, whichever came first. At the phase 2 visit, the patient was crossed-over to
112the alternative algorithm and the transmission processMANUSwas repeated. After collecting at least two
113hours of data under the programmed algorithm (or 4 weeks had passed), the phase 3 visit was
114scheduled. The phase 3 visit could have been the exit visit, or, if desired, the eCRTAF algorithm could
115have remained on for up to 4 months post-randomization. This additional time of algorithm
116operation outside of the randomized phases was not included in the primary analysis of the trial.
117CAFR (Control)ACCEPTED
118Conducted AF Response or CAFR is an algorithm that was designed to regularize the ventricular
119response to AF. Medtronic CRT devices have this algorithm programmed on by default because it
120tends to increase pacing. When the device is not trying to track the atrium, the algorithm measures
121the variability of the intervals between ventricular events (both paced and sensed) and dynamically
122adjusts the pacing rate. The algorithm is not able to distinguish between paces that were delivered
123but did not capture and those that did capture. This was used as Control because it is active by
124default in the CRT-D devices used in the study.
125EffectivCRT During AF (eCRTAF)
126The EffectivCRT During AF (eCRTAF) algorithm is designed to maximize % LV capture while
127minimizing the increase in pacing rate. It operates only during mode-switch or VVIR pacing mode,
128and consists of 3 phases: initiation, maintenance and evaluation (Figure 2).
Page 5 of 21
ACCEPTED MANUSCRIPT
129During the initiation phase, the algorithm evaluates eCRT on 30 consecutive beats, adjusting the
130pacing rate after each beat to achieve the minimum pacing rate which maximizes eCRT pacing as
131quickly as possible. Ventricular sensed events or ineffective LV pacing, result in small increases in the
132pacing rate, while effectively paced ventricular events result in small decreases in pacing rate. After
133the initiation phase, the algorithm enters a maintenance phase during which the pacing Trate is
134maintained for 30 seconds. Following the maintenance phase, while continuingCRIPat the current pacing
135rate the algorithm moves to a brief evaluation phase of 10 beats. Each beat is assessed for
136effectiveness and, at the end of the evaluation phase, a pacing rate is determined based on the
137number of ventricular sensed events, effective and ineffective paced beats. Following the evaluation
138phase, the algorithm returns to the maintenance phaseMANUSand then continues to cycle between
139evaluation and maintenance phases until the end of the AF episode.
140The eCRTAF algorithm includes four safety features to limit increases in HR. First, there is a
141programmable maximum pacing rate. Second, during a daily test, the device confirms that it can
142deliver effective CRT pacing with a short SAV/PAV or an accelerated rate during a non-tracking
143mode, in bothACCEPTEDBiV and LV-only modes. If effective CRT pacing cannot be achieved, the algorithm is
144disabled for the day. Third, the algorithm is suspended if the pacing rate reaches the programmed
145maximum rate and the device still detects ineffective capture in 4 out of 5 paced beats. Finally, the
146proportion of sensed or ineffective CRT paced beats required to increase pacing rate increases as the
147pacing rate rises. This makes the algorithm progressively less aggressive as the pacing rate
148increases.
149Data collection
150During each phase of the study, eCRT pacing was evaluated continuously during AF (or while the
151device was in VVIR mode). If the subject was in normal sinus rhythm (NSR), eCRT pacing was
152evaluated every hour for 100 consecutive beats at 25 minutes past the hour. The accumulated
153%eCRT pacing was defined as:
Page 6 of 21
ACCEPTED MANUSCRIPT
154%eCRT =
155Ventricular sense response beats were treated as sensed beats. Separate metrics of %eCRT pacing
156and %Vp were maintained for time spent in AF and sinus rhythm. Device counters and diagnostics
157were downloaded at each clinic visit. %Vp and mean HR since last interrogation were recorded.
158During the phase 1 office visits, if the subject was in AF, %eCRT pacing and pacing rate wereTassessed
159over three-minute periods with no algorithm, with CAFR and with eCRTAF.CRIPThe order of CAFR and
160eCRTAF were randomized and each algorithm had its own control period with no algorithm.
161Study Oversight
162The study was approved by the local Institutional ReviewMANUSBoard or Medical Ethics Committee and
163the national regulatory body for each country in which the study was conducted.
164Adverse events were adjudicated by the Adverse Event Adjudication Committee. The committee
165consisted of three physicians not involved in the study. All adverse events and deaths were reviewed
166by the committee and evaluated for relatedness to the algorithm as well as category, such as
167cardiovascularACCEPTEDor non-cardiovascular.
168Data Analysis and Statistics
169The primary objective of the study was to demonstrate that, during AF, %eCRT with eCRTAF applied
170was non-inferior to when CAFR was applied. If this objective was met, the superiority objective could
171be evaluated to determine if, during AF, %eCRT with eCRTAF applied was greater than when CAFR
172was applied. The lower confidence limit for the difference between treatment and control had to
173exceed the non-inferiority margin of -2% in order to meet the primary objective. To meet the
174superiority objective, the lower confidence limit for the difference had to exceed 0%. For both
175objectives, the one-side type I error rate was controlled at the 0.025 level. Sample size was driven by
176the more stringent superiority objective; with 80% power, assumed true difference of 6% and
177standard deviation of 15%, and a planned interim analysis at 60% of accrual, a total sample size of 54
178subjects with paired data was required.
Page 7 of 21
ACCEPTED MANUSCRIPT
179For continuous variables, mean and standard deviation are reported. For categorical variables,
180frequency and percentage are reported. The %Vp, %eCRT pacing, and mean HR during AF were
181compared between eCRTAF and Control (CAFR) using paired t-tests. P-values < 0.05 were considered
182statistically significant. Each subject needed to have at least 2 hours of data in each phase of the
183study (eCRTAF and Control) to be considered a complete data set included in the final analysis.T
184A multivariate regression analysis was performed to identify factors whichCRIPmight be associated with
185greater increases in %eCRT pacing. The factors that were explored included: age, gender, HF
186etiology, NYHA class, AF classification, AF medications, programmed lower pacing rate and
187programmed upper tracking rate at baseline, heart rate during AF under Control, and % pacing
188during AF under Control. The final model was selectedMANUSusing a backward elimination method keeping
189all factors with a p-value < 0.2 in the model.
190All analyses were conducted using SAS software version 9.4 (SAS Institute).191
192Results
193Seventy-one subjects were enrolled in the study from 22 centers in the United States, Europe and
194Middle East between October 2014 and January 2016. Follow-up was completed in January 2016. Of
195the 66 subjects randomized, 63 completed all study visits, and 54 had sufficient data (≥2 hours in
196each phase) available for analysis (Figure 3).
197The characteristics at the time of enrollment of the 54 subjects included in the analysis are shown in
198Table 1. Twenty-eight (52%) were in permanent AF, defined as a clinical diagnosis of permanent AF
199and continuous AF in the 7 most recent days of device trend data for subjects with an atrial lead
200(N=20) or as a clinical diagnosis of permanent AF for subjects with no atrial lead (N=8). Subjects with
201at least 24 hours of AF for at least 7 consecutive days but did not meet the criteria for permanent AF,
202were categorized as persistent. Subjects with paroxysmal AF were those who had AF but not for 7
203consecutive days at any time. All subjects were on at least one of the following categories of drugs
Page 8 of 21
ACCEPTED MANUSCRIPT
204for rate or rhythm control: beta blockers, Ca++ channel blockers, cardiac glycosides, class III anti-
205arrhythmic drugs.
206Primary results
207During AF, the eCRTAF algorithm resulted in a significantly higher %eCRT than Control (87.8±7.8 % vs
20880.8±14.3%, p<0.001) meeting both the primary objective of non-inferiority and the secondaryT
209objective of superiority. %Vp was also significantly higher during AF (90.0±5.9%CRIPvs 83.2±11.9%,
210p<0.001) and there was a small but statistically significant increase in mean HR of 2.5 bpm (79.5±9.7
211vs 77.0±9.9 bpm, p<0.001) (Figure 4). As expected, there were negative correlations between mean
212heart rate and %eCRT and between mean heart rateMANUSand %VP (Pearson correlation coefficient -0.75
213and -0.68 respectively). In addition, 5 subjects went from <90% eCRT during Control to >90% eCRT
214during eCRTAF. Five more subjects improved from <95% eCRT during Control to >95% eCRT during
215eCRTAF. Of 54 patients, 42 showed an increase in %eCRT with eCRTAF. Of the remaining 12 patients,
2164 had a decrease in eCRT of <1%, in a further 6 it was ≤3% and the remaining two had reductions of
2173.3 and 7.6%. ACCEPTED
218Subgroup analyses
219Subjects with lower %Vp during the Control (CAFR) phase showed a greater increase in %eCRT with
220eCRTAF than those who were already achieving a high %Vp (Figure 5). Subjects who received <
22180%Vp during Control showed the greatest increase in both %Vp (14.9±5.5% p<0.001) and %eCRT
222(15.7±6.9% p<0.001) with eCRTAF compared to Control. There was also an increase in mean HR of
2232bpm from 82 to 84bpm (p<0.01) in these subjects from Control to eCRTAF. Subjects with %Vp
224between 80 and 95% during Control showed a 2.2±4.2 point increase in %eCRT with eCRTAF (p <
2250.05). There was no significant difference in %eCRT or HR with eCRTAF in subjects with >95%Vp
226during Control.
227In a multivariate analysis, lower %Vp during Control continued to result in a greater impact of the
228algorithm (p<0.001). This is consistent with the univariate analysis shown in Figure 5. In addition, a
Page 9 of 21