Using phase data from MR temperature imaging to visualize anatomy during MRI-guided focused ultrasound neurosurgery

TL;DR

This study shows that phase data from MR temperature imaging during MRI-guided focused ultrasound can be used to visualize brain anatomy, improving targeting accuracy in neurosurgery without extra imaging steps.

Contribution

The paper introduces a novel method utilizing phase data from MRTI to visualize critical brain structures during MRgFUS, enhancing surgical guidance without additional imaging or registration errors.

Findings

Successfully visualized key nuclei like the red nucleus and subthalamic nucleus.

Consistently aligned anatomical landmarks with target coordinates.

Potential to visualize additional structures like the optic tract.

Abstract

Neurosurgery targets in the thalamus can be challenging to identify during transcranial MRI-guided focused ultrasound (MRgFUS) thermal ablation due to poor image quality. They also neighbor structures that can result in side effects if damaged. Here we demonstrate that the phase data obtained during MRgFUS for MR temperature imaging (MRTI) contains anatomic information that could be useful in guiding this procedure. This approach was evaluated in 68 thalamotomies for essential tremor (ET). We found that we could readily visualize the red nucleus and subthalamic nucleus, and those nuclei were consistently aligned with the sonication target coordinates. We also could consistently visualize the internal capsule, which needs to be protected from thermal damage to prevent side effects. Preliminary results from four pallidotomies in Parkinson's disease patients suggest that this approach might also be useful in visualizing the optic tract in addition to the internal capsule. Overall, this approach can visualize anatomic landmarks that may be useful to refine atlas-based targeting for MRgFUS. Since the same data is used for MRTI and anatomic visualization, there are no errors induced by registration to previously obtained planning images or image distortion, and no additional time is needed.