Clinical Trial Details
— Status: Active, not recruiting
Administrative data
| NCT number |
NCT05870306 |
| Other study ID # |
SCA-AF 1230-N-20 |
| Secondary ID |
|
| Status |
Active, not recruiting |
| Phase |
N/A
|
| First received |
|
| Last updated |
|
| Start date |
January 1, 2021 |
| Est. completion date |
January 1, 2024 |
Study information
| Verified date |
May 2023 |
| Source |
Instituto de investigación e innovación biomédica de Cádiz |
| Contact |
n/a |
| Is FDA regulated |
No |
| Health authority |
|
| Study type |
Interventional
|
Clinical Trial Summary
The problem addressed in this proposal is related to the success rate in treating one of the
most common arrhythmias in the Western population, atrial fibrillation (AF). Specifically,
the success rate is particularly low in persistent atrial fibrillation, being up to 40% lower
than the success rate for paroxysmal atrial fibrillation.
Atrial fibrillation is associated with increased mortality and morbidity (stroke, heart
failure, dementia, etc.). The most effective treatment is electrical isolation of the
pulmonary veins (PVI) by catheter ablation using radiofrequency or cryoablation of the atrial
myocardial tissue. This ablation allows the elimination of the main initiators of the
arrhythmia but may not address its maintainers, which play a significant role in persistent
atrial fibrillation.
This project proposes a new approach in studying the atrial myocardial substrate for
persistent fibrillation ablation. Until now, maintainers of the arrhythmia have been sought
by conducting studies during atrial fibrillation. In this project, we will use short-coupled
stimulation techniques during sinus rhythm and analyze the response of the atrial myocardium,
attempting to unmask areas where the impulse propagates abnormally/slowly. These areas of the
atrial muscle with hidden slow conduction (HSC) could generate short circuits that maintain
atrial fibrillation. It would be expected that these areas would show fragmented electrograms
in response to rapid electrical stimuli not visible in basal rhythm.
The study is divided into two sub-studies to be carried out over the 3-year project.
1. This study aims to test the feasibility of this new arrhythmic substrate
characterization strategy, as well as observe differences between patients with
paroxysmal and persistent AF and compare it with conventional fragmented electrogram
analysis during AF.
2. The second sub-study will apply the knowledge acquired during the first phase regarding
the characterization of electrograms-HSC, allowing for radiofrequency ablation
procedures to be performed using a new substrate ablation technique consisting of the
elimination of these electrograms and comparing the results with those patients who
undergo conventional pulmonary vein ablation techniques.
The ultimate goal, from a global point of view, is to demonstrate that it is possible to
improve the results of arrhythmia treatment by identifying and eliminating these
electrograms-HSC.
Description:
STUDY PURPOSE The aims of the current study are
- To investigate the presence, characteristics and location of complex electrograms
suggestive of slow conduction zones elucidated by triple atria extrastimuli during sinus
rhythm in paroxysmal and persistent Atrial Fibrillation (AF)
- Correlate atrial HSC- electrograms during sinus with continuously fractionated
electrograms during AF in patients with persistent AF
- Test the hypothesis that elimination of atrial HSC-Electrograms(EGM) in addition to PVI
would improve ablation outcomes in PersistentAF(PsAF) patients versus PVI alone in a
randomized study.
Sub-study 1 (ANALYSIS OF HIDDEN SLOW CONDUCTION ELECTROGRAMS IN PAROXISMAL AND PERSISTENT
ATRIAL FIBRILLATION. HSC-AF STUDY):
1.1. OBJETIVES HYPOTHESIS Left atrial EGM showing HSC elucidated by atria extrastimuli should
be more manifest in persistent versus paroxysmal AF and should de more spatially and
temporarily reproducible compared to fractionated EGM during AF STUDY OBJETIVES 1.1 Describe
the method to elucidate HSC using a triple atrial extrastimuli 1.2 Analyze the
characteristics and location of HSC-EGMs 1.3 Compare the presence, burden, characteristics
and location of HSC-EGMs in paroxysmal versus persistent AF 1.4 Compare the presence and
location of HSC-ECGs with fractionated EGM during AF
1.2. METHODS Summary of methods: 10 patients with paroxysmal AF and 10 patients with PsAF who
undergoing a first-time ablation procedure for AF will be consecutively included to describe
the complex electrograms (presence, distribution, number of deflections, amplitude, duration,
delta of EGM width) elucidated by triple atria extrastimuli during sinus rhythm.
1.2.3 PREPROCEDURAL INTERVENTIONS The usual clinical protocol for preparation for AF ablation
will be followed. This includes as complementary tests: blood tests, echocardiography and
cardiac CT. CT images will be analyzed with ADAS-3TM (Galgo Medical, Barcelona, Spain) to
obtain 3D wall thickness maps.
1.2.4 ELECTROPHYSIOLOGIC STUDY High-density voltage mapping using a multipolar catheter
(PentaRay, Biosense Webster, Diamond Bar, CA, USA) will be performed during sinus rhythm in
ParoxysmalAF(PxAF) patients. During mapping, manual points after a triple extrastimulus from
LA appendage will be acquired to fill all color gaps on the LA map using Carto3 with an
interpolation of 6 mm for the color threshold. Triple extrastimulus will be delivered at
atrial effective refractory period (AERP)+60ms plus AERP + 60 ms plus AERP +40-20ms. Adequate
endocardial contact will be confirmed by stable electrograms, the distance to the geometry
surface.
In PsAF patients starting the procedure in AF, a high-density map will be acquired during AF.
Visually detected Comlex Fractionated Atrial Electrograms(CFAE) will be annotated with pink
dots. In this subgroup of patients (10 PsAF cases) a second map will be acquired to confirm
the reproducibility of this methodology and compare the location and morphology of the
complex electrograms between the two acquisitions. After this second map electrical
cardioversion (≤3 external biphasic shock 200-360J) will be performed to restore sinus
rhythm. During sinus rhythm two consecutive high-density maps with triple extrastimuli will
be constructed as previously described.
1.2.5 RADIOFREQUENCY ABLATION The CARTO3® system (Biosense Webster, Diamond Bar, CA, USA)
will be used for ablation. An open irrigated, 3.5-mm tip, ablation catheter (ThermoCool®
SmartTouchTM, Biosense Webster, Diamond Bar, CA, USA) Will be used for mapping and ablation.
First of all, a fast-anatomical map (FAM) of the PVs and the left atrium Will be acquired.
PVI is performed by point-by-point RadioFrequency(RF) applications guided with ablation index
(350-450 f) to create a RF circle around the PV ostia (nephroid shape). In case of a common
ipsilateral vein ostium, the line was drawn around the trunk. Acute PVI was confirmed after
first pass with the usual local method by demonstrating entry and exit block with the
ablation catheter placed sequentially in each of the PVs. A 10-minute waiting period after
isolation of each ipsilateral PV pair was applied to assess for acute reconnections.
Additional RF applications were performed if needed at reconnection sites until PVI was
achieved.
1.2.6 SUBSTRATE MAPS AND ATRIAL ELECTROGRAM ANALYSIS
Low-voltage areas will be defined as sites of 3 adjacent low voltage (<0.5 mV) points, which
were <5 mm apart from each other.20
- Scar tissue < 0.05mV
- Healthy tissue > 0.5mV
- 0.05mV < Border Zone < 0.5mV EGMs with high electrical noise, or poor signal quality
reducing accurate assessment of abnormal EGMs were discarded
The signals during sinus rhythm will be divided into 3 types according to their electrogram
waveforms:
- Normal (sharp electrograms with <=3 positive or negative distinct peaks or electrogram
duration <40 ms).21, 22
- Complex EGM during SR:
- Fractionated (with >4 positive or negative distinct peaks and electrogram duration >=40
ms). Highly fragmented with ≥5 peaks ±63 ms.
- Double potential: 2 or more separate deflections separate by an isoelectric interval.21,
22
- HSC-EGM: sites that show highly fragmented or double electrograms in response to triple
extrastimuli, presenting normal or fractionated electrogram in sinus rhythm (see
figure). Sites will be determined by visual analysis during electroanatomical
mapping(EAM) acquisition and will be analyzed offline after the procedure. Delta of
duration of the bipolar EGM (third stimulated atrial EGM duration - atrial EGM duration
of the sinus beat prior to triple extrastimuli) in milliseconds will be recorded.
Electroanatomical maps acquired during AF will be used to draw automatic CFAE maps using the
CFAE-CARTO® module with the nominal setting of SCI CFAE maps.
After the first descriptive part of the study, all patients who fulfill the inclusion
criteria will be consecutively enrolled and randomized on a 1:1 basis to PVI alone vs PVI
plus slow conduction ablation.
Sub-study 2 PULMONARY VEIN ISOLATION PLUS SLOW CONDUCTION ABLATION ELUCIDATED BY TRIPLE ATRIA
EXTRASTIMULI VS PULMONARY VEIN ISOLATION ALONE IN PERSISTENT ATRIAL FIBRILLATION (HSC-AF
TRIAL)
2.1 OBJETIVES
HYPOTHESIS Elimination of atrial HSC-EGM in addition to PVI would improve ablation outcomes
in PsAF patients versus PVI alone
2.2 METHODS Summary of methods: 105 patients with PsAF who undergoing a first-time ablation
procedure for AF and fulfill inclusion criteria will be consecutively enrolled and randomized
on a 1:1 basis to PVI alone vs PVI plus HSC ablation.
2.2.1 ENDPOINTS PRIMARY ENDPOINT The primary end point of the study (efficacy) will be
freedom from any atrial arrhythmia (other than isthmus dependent atrial flutter) without the
use of antiarrhythmic drugs at 12 months after a single ablation procedure. Patients with AF
that occur in the first 3 months after the ablation (blanking period) will be censored. Each
episode that lasted >30s is regarded as a recurrence.
SECONDARY ENDPOINTS The following secondary endpoints will be considered: time to first
persistent AF (more than 7 days) after blanking period (efficacy), any atrial arrhythmia
(other than isthmus dependent atrial flutter) on antiarrhythmic drugs at 12 months after a
single ablation procedure after blanking period (efficacy), AF burden (% time AF in 24h
Holter) (efficacy), incidence of periprocedural complications (safety), procedure time
(feasibility), fluoroscopy time (feasibility), number of RF applications (efficiency), RF
delivery time (efficiency).
2.2.4 STUDY SIZE AND DURATION 105 patients undergoing a first-time ablation procedure for AF
will be consecutively enrolled and randomized on a 1:1 basis to PVI alone vs PVI plus slow
conduction ablation.
An enrollment log with all the patients included in the study, even drops out, will be
collected. Data will be collected at enrollment, baseline and at three, six and 12-month
follow-up visit.
2.3.1 BASELINE VISIT The baseline visit must be performed after the patient has signed the
informed consent form and prior to the AF ablation procedure.
2.3.2 PREPROCEDURAL INTERVENTIONS The standard clinical protocol for preparation for AF
ablation will be followed. This includes as complementary tests: blood tests,
echocardiography and cardiac CT. CT images will be analyzed with ADAS-3TM (Galgo Medical,
Barcelona, Spain) to obtain 3D wall thickness maps.
2.3.3 RANDOMIZATION Patients will be randomly assigned to each of the ablation procedures
(PVI plus HSC ablation vs. PVI alone) on a 1:1 basis before the procedure
ABLATION PROTOCOL IN THE PVI PLUS HSC ABLATION GROUP:
Cardioversion will be delivered to restore SR (≤3 synchronized, biphasic direct current
shocks (150 J, 200 J, and 200 J). High-density voltage mapping using a multipolar catheter
(PentaRay or OctaRay, Biosense Webster, Diamond Bar, CA, USA) will be performed. During
mapping, manual points after a triple extrastimulus from LA appendage will be acquired to
fill all color gaps on the LA map using Carto3 with an interpolation of 6 mm for the color
threshold. Triple extrastimulus will be delivered at atrial effective refractory period
(AERP)+60ms plus AERP + 60 ms plus AERP +40-20ms. Adequate endocardial contact will be
confirmed by stable electrograms, the distance to the geometry surface. The bandpass filter
will be set at 30-500 Hz. HSC-EGM are represented with green dots and highly fragmented EGM
with pink dots, double potentials in blue.
Then, PVI will be performed with the standard protocol, using entrance and exit block as the
electrophysiological end point. An open irrigated, 3.5-mm tip, ablation catheter (ThermoCool®
SmartTouchTM or QDot Micro™, Biosense Webster, Diamond Bar, CA, USA) was used for mapping and
ablation. First of all, a fast-anatomical map (FAM) of the PVs and the left atrium was
acquired. PVI is performed by point-by-point RF applications guided with ablation index
(350-450 f) to create a RF circle around the PV ostia (nephroid shape). In case of a common
ipsilateral vein ostium, the line was drawn around the trunk. Acute PVI was confirmed after
first pass with the usual local method by demonstrating entry and exit block with the
ablation catheter placed sequentially in each of the PVs. A 10-minute waiting period after
isolation of each ipsilateral PV pair was applied to assess for acute reconnections.
Additional RF applications were performed if needed at reconnection sites until PVI was
achieved.
After PVI isolation point-by point ablation targeting HSC-EGMs will be performed. HSC-EGMs
with a distance less than 5 mm between them will be addressed with a single application. The
ablation index will be defined based on the LA wall thickness (LAWT) at the location of the
HSC-EGM: LAWT < 1mm: 300 f, LAWT 1-2 mm: 350 f, LAWT 2-3 mm: 400 f and LAWT >3 mm: 450 f.
This is the experimental intervention added to pulmonary veins isolation. This intervention,
in terms of risks, is superimposable to the ablation of CFAEs or rotational activity, which
are stablished techniques for PsAF catheter ablation.24
Substrate maps and atrial electrogram analysis will be performed as described in sub-study 1
ABLATION PROTOCOL IN THE PVI GROUP:
High-density voltage mapping using a multipolar catheter will be performed during AF. PVI
will be performed with the standard protocol (previously described). If needed electrical
cardioversion will be performed after PVI ablation. A 10-minute waiting period after
isolation of each ipsilateral PV pair was applied to assess for acute reconnections.
Additional RF applications were performed if needed at reconnection sites until PVI was
achieved.
