Validation of Beat-to-beat Wavefront Direction Using Omnipolar Mapping — ATOM  

Atrial Flutter Typical Clinical Trial

Official title: Validation of Beat-to-beat Wavefront Direction Using Omnipolar Mapping

Status Recruiting

Clinical Trial Summary

To validate omnipolar mapping in a well-described circuit within the heart (Atrial Flutter) and compare it with the gold standard of Local Activation Time (LAT) mapping during routine, clinically indicated procedures of Atrial Flutter ablation. A conventional, LAT map will be created during the procedure, prior to treatment, to guide the procedure. A repeat map will be performed after ablation during the procedure. The investigators will export the map files for off-line analysis with the omnipolar software.

Clinical Trial Description

Electroanatomical mapping of the chambers of the heart has revolutionised the way physicians treat heart rhythm disorders. However, there still are technical limitations that prevent us from gathering information that could be used to understand and treat these abnormal circuits in more detail. The gold standard technique in creating electrical maps of the heart in stable circuits is the Local Activation Time (LAT) map. This map is formed by using a stable electrical point (one of the electrode catheters within the heart - plastic tubes with metallic sensors at the end) as a zero point and then collecting electrical data from around the heart based on timings off of that point. This data is then loaded on a licenced software that creates the map. These maps are very useful in creating electrical maps of the heart in relatively stable electrical circuits and can give us information on how the electrical current travels through the heart tissue. These are widely used in guiding ablation by helping us locate areas to ablate (apply local radiofrequency and burn part of the circuit, deactivating it). In more unstable circuits, such as in Atrial Fibrillation (chaotic electrical activity at the top left chamber of the heart), there are a lot of limitations of this technology as the electrical current changes from heart beat to heart beat and there is no stable zero point In the circuit to "anchor" the map in time. In these situations real-time map creation with local electrical currents would be ideal as it would help us see the direction the electrical wave front travels in real time. Our current electrical catheters have certain limitations which mainly have to do with difficulty in local electrical discrimination and detection of the orientation of the electrical current in real time. The Advisor HD Grid catheter by Abbott UK can overcome this hurdle. It has a special electrode configuration (4 by 4) that creates 9 distinct anatomical spaces within the catheter grid that can "triangulate" micro current direction in real time (omnipolar mapping). This will greatly enhance our ability to quickly detect electrical wave fronts in unstable circuits such as Atrial Fibrillation which will lead to better understanding of the arrhythmia and identify targets for treatment quickly and efficiently. The investigators aim to first validate the robustness of omnipolar mapping in a well-described, stable circuit such as Atrial Flutter, and compare it to the gold standard of LAT mapping. This will then help pave the way for use of this technology in more complex circuits, such as Atrial Fibrillation. ;

Related Conditions & MeSH terms

• Atrial Flutter
• Atrial Flutter Typical

• NCT number: NCT04900831
• Study type: Observational
• Source: Imperial College Healthcare NHS Trust
• Contact: Dimitrios Panagopoulos
• Phone: +447858778189
• Email: d.panagopoulos@nhs.net
• Status: Recruiting
• Start date: June 18, 2020
• Completion date: August 1, 2022