Pulsed-field ablation could be the next big EP technology trend

 

The new cardiac electrophysiology technology of pulsed field ablation may be a safer option that the current standard of care using cryoablation and radiofrequency ablation techniques, according to the late-breaking PULSED-AF trial presented at ACC.23. The technology is widely expected to replace current technologies ablation technologies in the treatment at atrial fibrillation (AFib).

The PULSED-AF trial looking at the Medtronic pulsed field ablation system was the first big pivotal trial to report results. Biosense Webster announced in early March the first cases with its investigational Dual Energy Catheter for cardiac ablation, which uses both pulsed field ablation (PFA) and radiofrequency (RF) ablation. Boston Scientific is also conducting the ADVENT trial for its Farapulse pulsed ablation technology.

Atul Verma, MD, director of cardiology with the McGill University Health Centre in Montreal, presented the late-breaking trial data on Medtronic’s pulsed-field ablation technology in patients with paroxysmal or persistent AFib. He spoke with Cardiovascular Business at ACC about the PULSED-AF trial results and what it takes to use this new technology. 

The new technology delivers short-duration electrical pulses to the cardiac tissue that causes pores, or holes, to form in the cellular walls of the myocytes. This irreversible electroporation process kills the cells without excess heat or cold, which can adversely effect healthy underlying tissues. This has a lot of appeal for electrophysiologists, because existing technologies can damage the esophagus, phrenic nerve, or cause pulmonary vein stenosis. Verma said anatomical structures around the right atrium are much more resistant to damage from electroporation. This fact alone makes it very appealing to electrophysiology to help avoid these major adverse events. 

PULSED-AF clinical trial outcomes

The PULSED-AF trial treated both paroxysmal AFib and persistent AFib patients, and all of the patients were resistant to anti-arrhythmic drugs. The success rates were 66% among paroxysmal patients and about 55% in the persistent AFib cohort. Verma noted that this was using a very rigid definition of treatment endpoints. This included very rigorous monitoring and a definition of freedom or 30 seconds or more of atrial arrhythmia, no further ablation and no adjustment in anti-arrhythmic drugs.

"If we look at more traditional endpoints, which is freedom from any atrial arrhythmia of more than 30 seconds, the success was about 70% paroxysmal group and 62% in the persistent group," Verma said. 

It was the efficiency and the safety of the technology that really had the most impact. 

"What was really impressive was efficiency and the safety," Verma explained. "The overall safety event rate was less than 1%. It was just 0.7%, which is one of the lowest complication rates of any AFib ablation trial."

In terms of efficiency, he said the dwell time in the right atrium was about 60 minutes. This is a far cry from the usually dwell time of a couple hours in traditional AFib ablation procedures.

"If you take out the mandatory 20-minute waiting period, these procedures were being done within about 40 minutes or so," Verma said. "And most of these operators had only used the catheter once before they started enrolling in the trial, so it is pretty impressive."

Comparison of success of pulsed field vs. cryo and RF ablation

Overall, Verma said the success rate of pulsed field ablation was about the same at traditional thermal ablation. So about a third of patients did not have their AFib resolved by the therapy during the first attempt procedure. But, he said the number of repeats procedures were very low. 

"The biggest advance here is a the speed and safety," Verma stressed. "Over time, I think we are going to see even better outcomes in terms of efficacy." 

How does pulsed-field ablation work?

The investigational Medtronic PulseSelect pulsed field ablation system is a round catheter with nine electrodes that create pulsed fields. It was designed to be placed around the ostium of the pulmonary veins. An operator can rotate the catheter two or three times to apply energy to create a a pulmonary vein isolation. 

"That was part of the instructions for use we gave to operators to overlap the leasing. We told operators to not worry too much about over applying the energy because it is a very safe energy source, so we actually encouraged the use of repetitive applications to make sure we got lesions as deep as possible," Verma explained. 

Each treatment takes a fraction of a second. Unlike tradition catheter ablation, which requires a certain amount of pressure or force to be applied to ensure a good scar in the tissue, Verma said you just need to have contact with the tissue and contact force is not a factor. 

Then the operator rotates the catheter and repeats the therapy to create a lesion that isolates any electrical activity from the pulmonary vein to the rest of the heart. The total application of energy for a full treatment in these patients was less than 30 seconds, Verma said. 

"As long as you can visualize that contact with the catheter and the tissue on X-ray or intra-cardiac ultrasound, that is good enough," Verma explained. 

What is the future of pulsed-field ablation?

Based on the results on the PULSED-AF trial, Verma said he believes there will be a rapid adoption rate of the technology once it gains U.S. FDA clearance. 

"I think over the next five years, we are really going to see pulsed field take up a lot of there thermal ablation space, especially for AFib," he explained. "And I think this being one of the first global, pivotal trial results, it certainly is baring out in that direction."

He expects to see pulsed field on a variety of platforms in the near future, including different types of catheter configurations.

Read more about the PULSED-AF trial

Find more ACC news and video

Dave Fornell is a digital editor with Cardiovascular Business and Radiology Business magazines. He has been covering healthcare for more than 16 years.

Dave Fornell has covered healthcare for more than 17 years, with a focus in cardiology and radiology. Fornell is a 5-time winner of a Jesse H. Neal Award, the most prestigious editorial honors in the field of specialized journalism. The wins included best technical content, best use of social media and best COVID-19 coverage. Fornell was also a three-time Neal finalist for best range of work by a single author. He produces more than 100 editorial videos each year, most of them interviews with key opinion leaders in medicine. He also writes technical articles, covers key trends, conducts video hospital site visits, and is very involved with social media. E-mail: dfornell@innovatehealthcare.com

Around the web

Ron Blankstein, MD, professor of radiology, Harvard Medical School, explains the use of artificial intelligence to detect heart disease in non-cardiac CT exams.

Eleven medical societies have signed on to a consensus statement aimed at standardizing imaging for suspected cardiovascular infections.

Kate Hanneman, MD, explains why many vendors and hospitals want to lower radiology's impact on the environment. "Taking steps to reduce the carbon footprint in healthcare isn’t just an opportunity," she said. "It’s also a responsibility."