Impact of Catheter Stability on the Outcomes With Very High Power Short Duration Ablation

NCT ID: NCT06721221

Last Updated: 2024-12-11

Basic Information

• Recruitment Status: ACTIVE_NOT_RECRUITING
• Clinical Phase: NA
• Total Enrollment: 100 participants
• Study Classification: INTERVENTIONAL
• Study Start Date: 2024-08-01
• Study Completion Date: 2026-12-31

Brief Summary

Background: Atrial fibrillation (AF), the most common cardiac rhythm disorder can be treated with pulmonary vein isolation (PVI). One technique for PVI is point-by-point radiofrequency ablation. Very high power short duration ablation is one of the most advanced technologies for radiofrequency ablation. However, acute efficacy results with this technology vary in a wide range. Improvements in automated tagging modules, incorporating tracking of cardiac and respiratory motion and enhanced stability algorithms, may allow for a better assessment of lesion quality and location and may improve the so called first-pass isolation rate (an indicator for acute procedural efficacy).

Objective: To assess the acute procedural outcomes of very high power short duration PVI with the new enhanced stability software.

Methods: Investigator-initiated, prospective, single-arm study on one hundred symptomatic patients with paroxysmal AF will undergo PVI with the QDOT catheter using a power setting of 90W(QMODE+). The inter-tag distance will be 6 mm posteriorly and 4 mm anteriorly, and the enhanced stability algorithm will be used in all cases. After creating the isolation circle, the presence or absence of first-pass isolation will be assessed on each side by the presence of entrance block. Primary endpoint will be first-pass isolation rate. Secondary outcomes are as follows: procedure time, left atrial dwell time, RF time, number of RF tags, use of a steerable sheath, occurrence of serious adverse events.

Hypothesis: Very high power short duration PVI using the new stability software results in a higher rate of first-pass isolation than previously published.

Detailed Description

Background Atrial fibrillation (AF) is the most common sustained cardiac arrhythmia in adults. Its prevalence increases with age, affecting 3/100 people, and its incidence is also correlated with age, affecting 30/100.000 people per year. Its clinical significance stems from common complications (stroke, heart failure) and concomitant higher mortality. The most effective rhythm control treatment method for atrial fibrillation is catheter ablation, which seeks to maintain sinus rhythm. Isolation of the triggering pulmonary veins (PVI) from the left atrium is the cornerstone of AF ablation. PVI has undergone significant technical development over the past decade; however, the chances of arrhythmia recurrence and the occurrence of procedural complications are not negligible. Experiments have shown that lesions with a slightly smaller surface diameter and less depth develop during high power short duration (HPSD) ablation. The shorter ablation time might result in more consistent lesion creation if the catheter stability is good during the radiofrequency (RF) application. On the other hand, if the catheter position is unstable during the RF application, a huge variety might occur between the created lesion sizes. Regarding the safety aspects, the shallower lesions might cause less damage to the surrounding tissues. The latest application of HPSD technology is the so-called "very high power short duration" (vHPSD) ablation with application of 90W power for 3-4 seconds. The ablation index does not work for such a short ablation time; thus, other lesion-predicting parameters should be used, such as impedance drop and catheter stability. At the moment, there are two software products for ablation point visualization. The commercially available legacy software was originally built to assess catheter stability over a long ablation period (e.g. with the ablation index), but the system is unable to differentiate between poor and good catheter stability during a 4 seconds time frame. Conversely, the new SVTAG software is adapted to assess catheter stability over a 4-second period; thus, the operator might get better feedback on the actual lesion creation. This might result in a more optimized lesion set and a more effective PVI, but this hypothesis has not been tested yet.

Objective: To evaluate the acute efficacy of radiofrequency PVI performed with 90W, using the new stability software version.

Primary hypothesis: Pulmonary vein isolation is effective with the Svtag software that gives proper feedback on catheter stability, resulting in short procedures, high first-pass isolation rate, and few acute reconnections.

Study Design: Multicenter, prospective, single-arm study.

Research period: The planned research period starts in the first quarter of 2023 until December 2025.

Study subjects: Planned number of included subjects: 150. Inclusion criteria: Symptomatic paroxysmal or persistent AF, Age >18 years, Willingness to sign the informed consent form.

Exclusion criteria: Contraindication to ablation, Contraindication of long-term anticoagulation, Long-standing persistent AF, History of PVI, History of cardiac surgery, Pregnancy, Active malignancy, Life expectancy <1 year, Valvular AF, Reversible cause of AF (e.g. hyperthyroidism).

Study procedure: PVI will be performed via femoral access after transseptal puncture, guided by fluoroscopy pressure monitoring, intracardiac echocardiography (ICE) or transesophageal echocardiography (TEE). A fast anatomical left atrial map will be created; then, point-by- point PVI will be performed with QDot Micro catheter in QMODE plus with the Svtag software. Inter-tag distance should be ≤ 6 mm on the posterior wall and ≤ 4 mm on the anterior wall. All applications' duration should be 4 seconds. After creating the isolation circle, the presence or absence of first-pass isolation will be assessed on each side by the presence of entrance block. If PVI is complete, this is defined as first-pass isolation. If PVI is not complete at this point, touch-up lesions will be delivered to reach the isolation of all pulmonary veins. After that, acute PV reconnections will be evaluated during a 20 minutes waiting period. In case of acute reconnection, additional applications will be delivered to complete the PVI. No further waiting is necessary after that.

Primary endpoint: First-pass isolation rate.Secondary endpoints: Occurrence of any adverse events related to the procedure during the hospital stay and 1 month after the procedure. Acute reconnection: pulmonary vein reconnection during the 20 minutes waiting period. Impact of scar burden in the on the FPI rate assessed by EA mapping (during the waiting period). 12-month AF-free survival

Nature of the study: Investigator-initiated clinical trial, there is no commissioning company. The study is not for commercial gain. Not a drug test. Subjects will not undergo any additional procedures in connection to the study. The study protocol is in compliance with routine clinical practice, no additional radiation is applied.

Adverse events: PVI is a routinely used, safe procedure these days. During the current clinical trial, for the participating patients, there is no additional intervention that is different from the everyday routine, except for the 20-minute waiting period after the PVI. During the procedure, patients are exposed to the following potential complications, which in total occur in 1% of cases: Complications involving the vascular access site: femoral pseudoaneurysm / arterio- venous fistula / hematoma with bleeding requiring blood transfusion, Pericardial fluid, Pericardial tamponade, Stroke / TIA, Esophageal injury / perforation / fistula, Myocardial infarction, Phrenic nerve paresis, Pulmonary vein stenosis, Conduction system damage requiring pacemaker implantation, Death. The participating centers' Electrophysiology Laboratories are prepared and capable of providing fast and adequate care for these complications.

Statistical analysis: Continuous variables are expressed as means and standard deviations, or medians and interquartile ranges, depending on the normal or non-normal distribution. Categorical variables are expressed in numbers and percentages. Continuous variables are compared by parametric or non-parametric tests, depending on the distribution, while categorical variables are compared by Chi-square test or Fisher's exact test. A two-tailed p-value of <0.05 is considered statistically significant. Statistical analyses will be performed using IBM SPSS 25 (Apache Software Foundation, USA) and GraphPad Prism 7.1 (GraphPad Softwares Inc., USA) software, or other statistical software products.

Data management: All study patient data is entered into an electronic database (REDCap) in a coded and unique manner, with a unique identifier, to which project staff has a password-protected, defined level of access. Each person involved in the study is given a unique identification code, and the data stored in the database is linked to that unique identifier. Thus, a data set will be incomprehensible and unusable for an external (unauthorized) user. The data belonging to the unique identification code, with which the patient's identity can be clearly indicated (name, place and date of birth, clinical reference number, identification number, identity card number, etc.) are not available from the database and are stored separately from it. Access to personal data will be limited to authorized staff (both clinical and research) at the local hospital site.

Funding: A research grant is provided by the Johnson and Johnson Company.

Ethics approval: An ethics approval application is submitted separately in case of all participating centers to their national or local ethics committee.

Conditions

Atrial Fibrillation (AF); Atrial Fibrillation Ablation; Pulmonary Vein Isolation

Keywords

pulmonary vein isolation; catheter stability; first-pass isolation

Study Design

• Allocation Method: NA
• Intervention Model: SINGLE_GROUP
• Primary Study Purpose: TREATMENT
• Blinding Strategy: NONE

Study Groups

SVtag arm. Point-by-point PVI with the Svtag software

PVI will be performed with QDot Micro catheter in QMODE plus with the Svtag software.

Group Type: EXPERIMENTAL

Point-by-point PVI with the QDot Micro catheter in QMODE+ setting with the Svtag software

Intervention Type: DEVICE

PVI will be performed via femoral access after transseptal puncture, guided by fluoroscopy pressure monitoring, intracardiac echocardiography (ICE) or transesophageal echocardiography (TEE). A fast anatomical left atrial map will be created; then, point-by-point PVI will be performed with QDot Micro catheter in QMODE plus with the Svtag software. Inter-tag distance should be ≤ 6 mm on the posterior wall and ≤ 4 mm on the anterior wall. All applications' duration should be 4 seconds. After creating the isolation circle, the presence or absence of first-pass isolation will be assessed on each side by the presence of entrance block. If PVI is complete, this is defined as first-pass isolation. If PVI is not complete at this point, touch-up lesions will be delivered to reach the isolation of all pulmonary veins. After that, acute PV reconnections will be evaluated during a 20 minutes waiting period.

Interventions

Point-by-point PVI with the QDot Micro catheter in QMODE+ setting with the Svtag software

PVI will be performed via femoral access after transseptal puncture, guided by fluoroscopy pressure monitoring, intracardiac echocardiography (ICE) or transesophageal echocardiography (TEE). A fast anatomical left atrial map will be created; then, point-by-point PVI will be performed with QDot Micro catheter in QMODE plus with the Svtag software. Inter-tag distance should be ≤ 6 mm on the posterior wall and ≤ 4 mm on the anterior wall. All applications' duration should be 4 seconds. After creating the isolation circle, the presence or absence of first-pass isolation will be assessed on each side by the presence of entrance block. If PVI is complete, this is defined as first-pass isolation. If PVI is not complete at this point, touch-up lesions will be delivered to reach the isolation of all pulmonary veins. After that, acute PV reconnections will be evaluated during a 20 minutes waiting period.

Intervention Type: DEVICE

Eligibility Criteria

Inclusion Criteria

• Symptomatic paroxysmal or persistent AF
• Age >18 years
• Willingness to sign the informed consent form

Exclusion Criteria

• Contraindication to ablation
• Contraindication of long-term anticoagulation
• Long-standing persistent AF
• History of PVI
• History of cardiac surgery
• Pregnancy
• Active malignancy
• Life expectancy &lt;1 year
• Valvular AF
• Reversible cause of AF (e.g. hyperthyroidism).

• Minimum Eligible Age: 18 Years
• Eligible Sex: ALL
• Accepts Healthy Volunteers: No

Sponsors

Semmelweis University

OTHER

Sponsor Role: lead

Responsible Party

Responsibility Role: SPONSOR

Locations

Heart and Vascular Center, Semmelweis University

Budapest, , Hungary

Countries

Hungary

References

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Other Identifiers

BWI-IIS-688

Identifier Type: OTHER_GRANT

Identifier Source: secondary_id

BM/8942-1/2023

Identifier Type: -

Identifier Source: org_study_id