MR-guided cardiac radiofrequency ablation allowed reliable catheter tracking and demonstrated that wall thickness and T2-signal enhancement at ablation sites increased to approximately twice their original values within 30 minutes.
An MR-guided electrophysiology platform using a tracked ablation catheter successfully allowed real-time visualization of ablation-induced tissue changes (edema and wall thickness) in a porcine model.
Background MR-guided electrophysiology (MR-EP) for the treatment of arrhythmia has the potential advantages of improved soft tissue contrast navigation and visualization of ablation-induced tissue changes. In the past, the development of MR-conditional EP catheters and an appropriate image guidance platform have represented major obstacles. The aim of this work was to establish and evaluate a catheter-guided approach that allows monitoring of radiofrequency (RF) ablation at the electrode tip. Methods A deflectable ablation catheter (Vision MRM, Imricor, Burnsville, MN) with two RF micro-coils allows tracking of the catheter tip and its orientation. The integration of dedicated transmission line technology ensures safe tracking. Continuous acquisition of projections allows tracking of the catheter motion with an update rate of 10Hz. A prototype platform (MR iSuite) was used to display the position and the orientation of the catheter tip relative to multi-planar reformatted or real-time slices and to a surface-rendered cardiac model in 3D (Figure 1a) for improved catheter guidance. The iSuite allows automatic planning of MR scans relative to the position and orientation of the catheter. This mechanism was used to invoke the acquisition of two different image datasets on a 1.5T MR-scanner (Achieva, Philips Healthcare, Netherlands) to prepare and monitor RF ablation. First, a cardiac-gated SSFP cine sequence (TR/TE=3.2/ 1.6ms, 40 phases, resolution: 1.4x1.4x8mm, AQ=15sec) is obtained to verify sufficient contact of the catheter tip to the tissue. Secondly, a high-resolution cardiac-triggered black blood T2-weighted TSE sequence (TE=50ms, Turbo-Factor=16, resolution: 0.95x0.95x4mm, AQ=12sec) is used to visualize the effect of the RF ablation on the tissue (edema and wall-thickness). This approach was first tested in a phantom and then assessed in-vivo in a 40kg pig. Four discrete RF lesions (40W, 1min) were applied on the posterior right atrial wall. Edema and wall thickness were monitored for each catheter tip location over the first 5min and at 15, 30, and 45min. The T2-signal in the wall was normalized to the ventricular myocardial signal to determine a relative enhancement.
Weiß et al. (Tue,) conducted a other in Arrhythmia (n=1). MR-guided cardiac radiofrequency ablation with catheter-tracked local MR lesion monitoring vs. Baseline (pre-ablation) was evaluated on Wall thickness and T2-signal enhancement. MR-guided cardiac radiofrequency ablation allowed reliable catheter tracking and demonstrated that wall thickness and T2-signal enhancement at ablation sites increased to approximately twice their original values within 30 minutes.