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RESEARCH PRODUCT
Atrial Fibrosis Hampers Non-invasive Localization of Atrial Ectopic Foci From Multi-Electrode Signals: A 3D Simulation Study
Javier SaizRafael SebastianIgnacio García-fernándezMiguel LozanoEduardo J GodoyRob S. MacleodAna Ferrer-alberosubject
Ectopic focus locationmedicine.medical_specialtyFocus (geometry)Physiologymedicine.medical_treatment0206 medical engineeringAtrial tachycardiaStructural remodelingBody surface potential map02 engineering and technologyOptimal electrode location030204 cardiovascular system & hematology3d simulationlcsh:PhysiologyTECNOLOGIA ELECTRONICA03 medical and health sciences0302 clinical medicineFibrosisPhysiology (medical)Internal medicineMedicineMachine-learningAtrial tachycardiaOriginal Researchlcsh:QP1-981business.industryCardiac electrophysiologyCardiac arrhythmiaTorsoAblationmedicine.disease020601 biomedical engineeringmedicine.anatomical_structureCardiologymedicine.symptombusinessdescription
[EN] Introduction: Focal atrial tachycardia is commonly treated by radio frequency ablation with an acceptable long-term success. Although the location of ectopic foci tends to appear in specific hot-spots, they can be located virtually in any atrial region. Multi-electrode surface ECG systems allow acquiring dense body surface potential maps (BSPM) for non-invasive therapy planning of cardiac arrhythmia. However, the activation of the atria could be affected by fibrosis and therefore biomarkers based on BSPM need to take these effects into account. We aim to analyze the effect of fibrosis on a BSPM derived index, and its potential application to predict the location of ectopic foci in the atria. Methodology: We have developed a 3D atrial model that includes 5 distributions of patchy fibrosis in the left atrium at 5 different stages. Each stage corresponds to a different amount of fibrosis that ranges from 2 to 40%. The 25 resulting 3D models were used for simulation of Focal Atrial Tachycardia (FAT), triggered from 19 different locations described in clinical studies. BSPM were obtained for all simulations, and the body surface potential integral maps (BSPiM) were calculated to describe atrial activations. A machine learning (ML) pipeline using a supervised learning model and support vector machine was developed to learn the BSPM patterns of each of the 475 activation sequences and relate them to the origin of the FAT source. Results: Activation maps for stages with more than 15% of fibrosis were greatly affected, producing conduction blocks and delays in propagation. BSPiMs did not always cluster into non-overlapped groups since BSPiMs were highly altered by the conduction blocks. From stage 3 (15% fibrosis) the BSPiMs showed differences for ectopic beats placed around the area of the pulmonary veins. Classification results were mostly above 84% for all the configurations studied when a large enough number of electrodes were used to map the torso. However, the presence of fibrosis increases the area of the ectopic focus location and therefore decreases the utility for the electrophysiologist. Conclusions: The results indicate that the proposed ML pipeline is a promising methodology for non-invasive ectopic foci localization from BSPM signal even when fibrosis is present.
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2018-05-18 | Frontiers in Physiology |