Mechanisms of action behind the protective effects of proactive esophageal cooling during radiofrequency catheter ablation in the left atrium
González-Suárez, Ana
González-Suárez, Ana
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Publication Date
2024-06-20
Type
journal article
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Omotoye, Samuel, Singleton, Matthew J., Zagrodzky, Jason, Clark, Bradley, Sharma, Dinesh, Metzl, Mark D., Gallagher, Mark M., Meininghaus, Dirk Grosse, Leung, Lisa, Garg, Jalaj, Warrier, Nikhil, Panico, Ambrose, Tamirisa, Kamala, Sanchez, Javier, Mickelsen, Steven, Sardana, Mayank, Shah, Dipak, Athill, Charles, Hayat, Jamal, Silva, Rogelio, Clark,, Audra T., Gray, Maria, Levi, Benjamin, Kulstad, Erik, Girouard, Steven, Zagrodzky, Will, Montoya, Marcela Mercado, Bustamante, Tatiana Gomez, Berjano, Enrique, González-Suárez, Ana, Daniels, James. (2024). Mechanisms of action behind the protective effects of proactive esophageal cooling during radiofrequency catheter ablation in the left atrium. Heart Rhythm O2, 5(6), 403-416. doi: https://doi.org/10.1016/j.hroo.2024.05.002
Abstract
Proactive esophageal cooling for the purpose of reducing the likelihood of ablation-related esophageal injury resulting from radiofrequency (RF) cardiac ablation procedures is increasingly being used and has been Food and Drug Administration cleared as a protective strategy during left atrial RF ablation for the treatment of atrial fibrillation. In this review, we examine the evidence supporting the use of proactive esophageal cooling and the potential mechanisms of action that reduce the likelihood of atrioesophageal fistula (AEF) formation. Although the pathophysiology behind AEF formation after thermal injury from RF ablation is not well studied, a robust literature on fistula formation in other conditions (eg, Crohn disease, cancer, and trauma) exists and the relationship to AEF formation is investigated in this review. Likewise, we examine the abundant data in the surgical literature on burn and thermal injury progression as well as the acute and chronic mitigating effects of cooling. We discuss the relationship of these data and maladaptive healing mechanisms to the well-recognized postablation pathophysiological effects after RF ablation. Finally, we review additional important considerations such as patient selection, clinical workflow, and implementation strategies for proactive esophageal cooling.
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Publisher
Elsevier
Publisher DOI
10.1016/j.hroo.2024.05.002
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Attribution 4.0 International