An open‐source automated platform for three‐dimensional visualization of subdural electrodes using CT‐MRI coregistration

Summary Objective Visualizing implanted subdural electrodes in three‐dimensional (3D) space can greatly aid in planning, executing, and validating resection in epilepsy surgery. Coregistration software is available, but cost, complexity, insufficient accuracy, or validation limit adoption. We presen...

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Bibliographic Details
Published in:Epilepsia (Copenhagen) 2014-12, Vol.55 (12), p.2028-2037
Main Authors: Azarion, Allan A., Wu, Jue, Pearce, Allison, Krish, Veena T., Wagenaar, Joost, Chen, Weixuan, Zheng, Yuanjie, Wang, Hongzhi, Lucas, Timothy H., Litt, Brian, Gee, James C., Davis, Kathryn A.
Format: Article
Language:English
Subjects:
3D CT‐MRI coregistration
Adult
Brain - pathology
Electrocorticography
Electrode localization
Electrodes
Electronic Data Processing
Epilepsy - diagnosis
Epilepsy surgery
Female
Humans
Imaging, Three-Dimensional
Magnetic Resonance Imaging
Male
Subdural electrodes
Subdural Space - pathology
Tomography, X-Ray Computed
Young Adult
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Summary:Summary Objective Visualizing implanted subdural electrodes in three‐dimensional (3D) space can greatly aid in planning, executing, and validating resection in epilepsy surgery. Coregistration software is available, but cost, complexity, insufficient accuracy, or validation limit adoption. We present a fully automated open‐source application, based on a novel method using postimplant computerized tomography (CT) and postimplant magnetic resonance (MR) images, for accurately visualizing intracranial electrodes in 3D space. Methods CT‐MR rigid brain coregistration, MR nonrigid registration, and prior‐based segmentation were carried out on seven patients. Postimplant CT, postimplant MR, and an external labeled atlas were then aligned in the same space. The coregistration algorithm was validated by manually marking identical anatomic landmarks on the postimplant CT and postimplant MR images. Following coregistration, distances between the center of the landmark masks on the postimplant MR and the coregistered CT images were calculated for all subjects. Algorithms were implemented in open‐source software and translated into a “drag and drop” desktop application for Apple Mac OS X. Results Despite postoperative brain deformation, the method was able to automatically align intrasubject multimodal images and segment cortical subregions, so that all electrodes could be visualized on the parcellated brain. Manual marking of anatomic landmarks validated the coregistration algorithm with a mean misalignment distance of 2.87 mm (standard deviation 0.58 mm)between the landmarks. Software was easily used by operators without prior image processing experience. Significance We demonstrate an easy to use, novel platform for accurately visualizing subdural electrodes in 3D space on a parcellated brain. We rigorously validated this method using quantitative measures. The method is unique because it involves no preprocessing, is fully automated, and freely available worldwide. A desktop application, as well as the source code, are both available for download on the International Epilepsy Electrophysiology Portal (https://www.ieeg.org) for use and interactive refinement.
ISSN:0013-9580
1528-1167
1528-1167
DOI:10.1111/epi.12827