A novel percutaneous stabilizing sheath for minimal invasive epicardial echocardiography and ablation

Alan Sugrue, Vaibhav R. Vaidya, Deepak Padmanabhan, Omar Yasin, Anas Abudan, Ameesh Isath, Ammar M. Killu, Niyada Naksuk, Brad Bolon, Paul Andrew Friedman, Samuel J Asirvatham

Research output: Contribution to journalArticle

Abstract

Purpose: Epicardial ablation and mapping are critical adjuncts to the electrophysiologist’s approach to arrhythmias; however, ablation within the epicardial space requires the avoidance of coronary arteries (CA). We aimed to evaluate the feasibility and performance of a novel-stabilizing ablation sheath housing an intracardiac echocardiography (ICE) catheter to (1) obtain Epicardial Echocardiography (EE) images, (2) visualize CAs, and (3) enable targeted delivery of radiofrequency energy away from visualized CAs. Methods: We designed a sheath that could enclose a regular ICE catheter. This sheath has flanges and a balloon, with three interspersed windows surrounded by an electrode. In an acute canine model (N = 6), the sheath was manipulated within the pericardial space to visualize cardiac structures and CAs. Visualization of CAs was confirmed with angiography. Ablation was then performed through the window either proximal or distal to the CA. Results: The novel sheath was successfully deployed in six canines, with no acute procedural complications. Images with an excellent spatial resolution of cardiac structures were obtained including the right ventricular outflow tract; aortic, pulmonary, and mitral valves; and left atrial appendage. CAs were successfully visualized, and ablation from a sheath window either proximal or distal to the CA did not produce angiographic or histopathological evidence of CA damage despite evidence of acute injury to the adjacent ablated myocardium. Conclusions: This novel percutaneous stabilizing sheath was able to successfully obtain high-quality EE images as well as provide a non-fluoroscopic intra-procedural means to visualize CAs. Use of this sheath enabled successful delivery of energy to avoided CA damage.

Original languageEnglish (US)
JournalJournal of Interventional Cardiac Electrophysiology
DOIs
StatePublished - Jan 1 2019

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Echocardiography
Coronary Vessels
Cardiac Catheters
Canidae
Epicardial Mapping
Pulmonary Valve
Atrial Appendage
Pericardium
Aortic Valve
Mitral Valve
Cardiac Arrhythmias
Myocardium
Angiography
Electrodes
Wounds and Injuries

Keywords

  • Coronary artery
  • Epicardial ablation
  • Epicardial access
  • Epicardial echocardiography

ASJC Scopus subject areas

  • Cardiology and Cardiovascular Medicine
  • Physiology (medical)

Cite this

A novel percutaneous stabilizing sheath for minimal invasive epicardial echocardiography and ablation. / Sugrue, Alan; Vaidya, Vaibhav R.; Padmanabhan, Deepak; Yasin, Omar; Abudan, Anas; Isath, Ameesh; Killu, Ammar M.; Naksuk, Niyada; Bolon, Brad; Friedman, Paul Andrew; Asirvatham, Samuel J.

In: Journal of Interventional Cardiac Electrophysiology, 01.01.2019.

Research output: Contribution to journalArticle

Sugrue, Alan ; Vaidya, Vaibhav R. ; Padmanabhan, Deepak ; Yasin, Omar ; Abudan, Anas ; Isath, Ameesh ; Killu, Ammar M. ; Naksuk, Niyada ; Bolon, Brad ; Friedman, Paul Andrew ; Asirvatham, Samuel J. / A novel percutaneous stabilizing sheath for minimal invasive epicardial echocardiography and ablation. In: Journal of Interventional Cardiac Electrophysiology. 2019.
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abstract = "Purpose: Epicardial ablation and mapping are critical adjuncts to the electrophysiologist’s approach to arrhythmias; however, ablation within the epicardial space requires the avoidance of coronary arteries (CA). We aimed to evaluate the feasibility and performance of a novel-stabilizing ablation sheath housing an intracardiac echocardiography (ICE) catheter to (1) obtain Epicardial Echocardiography (EE) images, (2) visualize CAs, and (3) enable targeted delivery of radiofrequency energy away from visualized CAs. Methods: We designed a sheath that could enclose a regular ICE catheter. This sheath has flanges and a balloon, with three interspersed windows surrounded by an electrode. In an acute canine model (N = 6), the sheath was manipulated within the pericardial space to visualize cardiac structures and CAs. Visualization of CAs was confirmed with angiography. Ablation was then performed through the window either proximal or distal to the CA. Results: The novel sheath was successfully deployed in six canines, with no acute procedural complications. Images with an excellent spatial resolution of cardiac structures were obtained including the right ventricular outflow tract; aortic, pulmonary, and mitral valves; and left atrial appendage. CAs were successfully visualized, and ablation from a sheath window either proximal or distal to the CA did not produce angiographic or histopathological evidence of CA damage despite evidence of acute injury to the adjacent ablated myocardium. Conclusions: This novel percutaneous stabilizing sheath was able to successfully obtain high-quality EE images as well as provide a non-fluoroscopic intra-procedural means to visualize CAs. Use of this sheath enabled successful delivery of energy to avoided CA damage.",
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AU - Sugrue, Alan

AU - Vaidya, Vaibhav R.

AU - Padmanabhan, Deepak

AU - Yasin, Omar

AU - Abudan, Anas

AU - Isath, Ameesh

AU - Killu, Ammar M.

AU - Naksuk, Niyada

AU - Bolon, Brad

AU - Friedman, Paul Andrew

AU - Asirvatham, Samuel J

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N2 - Purpose: Epicardial ablation and mapping are critical adjuncts to the electrophysiologist’s approach to arrhythmias; however, ablation within the epicardial space requires the avoidance of coronary arteries (CA). We aimed to evaluate the feasibility and performance of a novel-stabilizing ablation sheath housing an intracardiac echocardiography (ICE) catheter to (1) obtain Epicardial Echocardiography (EE) images, (2) visualize CAs, and (3) enable targeted delivery of radiofrequency energy away from visualized CAs. Methods: We designed a sheath that could enclose a regular ICE catheter. This sheath has flanges and a balloon, with three interspersed windows surrounded by an electrode. In an acute canine model (N = 6), the sheath was manipulated within the pericardial space to visualize cardiac structures and CAs. Visualization of CAs was confirmed with angiography. Ablation was then performed through the window either proximal or distal to the CA. Results: The novel sheath was successfully deployed in six canines, with no acute procedural complications. Images with an excellent spatial resolution of cardiac structures were obtained including the right ventricular outflow tract; aortic, pulmonary, and mitral valves; and left atrial appendage. CAs were successfully visualized, and ablation from a sheath window either proximal or distal to the CA did not produce angiographic or histopathological evidence of CA damage despite evidence of acute injury to the adjacent ablated myocardium. Conclusions: This novel percutaneous stabilizing sheath was able to successfully obtain high-quality EE images as well as provide a non-fluoroscopic intra-procedural means to visualize CAs. Use of this sheath enabled successful delivery of energy to avoided CA damage.

AB - Purpose: Epicardial ablation and mapping are critical adjuncts to the electrophysiologist’s approach to arrhythmias; however, ablation within the epicardial space requires the avoidance of coronary arteries (CA). We aimed to evaluate the feasibility and performance of a novel-stabilizing ablation sheath housing an intracardiac echocardiography (ICE) catheter to (1) obtain Epicardial Echocardiography (EE) images, (2) visualize CAs, and (3) enable targeted delivery of radiofrequency energy away from visualized CAs. Methods: We designed a sheath that could enclose a regular ICE catheter. This sheath has flanges and a balloon, with three interspersed windows surrounded by an electrode. In an acute canine model (N = 6), the sheath was manipulated within the pericardial space to visualize cardiac structures and CAs. Visualization of CAs was confirmed with angiography. Ablation was then performed through the window either proximal or distal to the CA. Results: The novel sheath was successfully deployed in six canines, with no acute procedural complications. Images with an excellent spatial resolution of cardiac structures were obtained including the right ventricular outflow tract; aortic, pulmonary, and mitral valves; and left atrial appendage. CAs were successfully visualized, and ablation from a sheath window either proximal or distal to the CA did not produce angiographic or histopathological evidence of CA damage despite evidence of acute injury to the adjacent ablated myocardium. Conclusions: This novel percutaneous stabilizing sheath was able to successfully obtain high-quality EE images as well as provide a non-fluoroscopic intra-procedural means to visualize CAs. Use of this sheath enabled successful delivery of energy to avoided CA damage.

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