2.5D Thermometry Maps for MRI-guided Tumor Ablation

Abstract

Fast and reliable monitoring of volumetric heat distribution during MRI-guided tumor ablation is an urgent clinical need. In this work, we introduce a method for generating 2.5D thermometry maps from uniformly distributed 2D MRI phase images rotated around the applicator’s main axis. The images can be fetched directly from the MR device, reducing the delay between image acquisition and visualization. For reconstruction, we use a weighted interpolation on a cylindric coordinate representation to calculate the heat value of voxels in a region of interest. A pilot study on 13 ex vivo bio protein phantoms with flexible tubes to simulate a heat sink effect was conducted to evaluate our method. After thermal ablation, we compared the measured coagulation zone extracted from the post-treatment MR data set with the output of the 2.5D thermometry map. The results show a mean Dice score of 0.75±0.07, a sensitivity of 0.77±0.03, and a reconstruction time within18.02ms±5.91ms. Future steps should address improving temporal resolution and accuracy, e.g., incorporating advanced bioheat transfer simulations.

Description

- 13 ex vivo polyacrylamid gel phantoms
o 7 homogeneous phantoms
o 6 phantoms with flexible tubes to simulate blood flow
- All data sets consist of the:
o unprocessed magnitude and phase images
o reconstructed heat maps using the proton resonance frequency shift method
o segmentation of the coagulation zone
o the reconstructed output from our method

Keywords

Image-Guided Interventions, Image Reconstruction, Simulation, 2.5D Thermometry

Citation

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