Segmentation-based Registration of Ultrasound Volumes for Glioma Resection in Image-guided Neurosurgery

Overview

Journal Int J Comput Assist Radiol Surg

Publisher Springer

Specialties General Surgery
Radiology

Date 2019 Aug 9

PMID 31392670

Citations 7

Authors

Luca Canalini

Jan Klein

Dorothea Miller

Ron Kikinis

Affiliations

Soon will be listed here.

Abstract

Purpose: In image-guided surgery for glioma removal, neurosurgeons usually plan the resection on images acquired before surgery and use them for guidance during the subsequent intervention. However, after the surgical procedure has begun, the preplanning images become unreliable due to the brain shift phenomenon, caused by modifications of anatomical structures and imprecisions in the neuronavigation system. To obtain an updated view of the resection cavity, a solution is to collect intraoperative data, which can be additionally acquired at different stages of the procedure in order to provide a better understanding of the resection. A spatial mapping between structures identified in subsequent acquisitions would be beneficial. We propose here a fully automated segmentation-based registration method to register ultrasound (US) volumes acquired at multiple stages of neurosurgery.

Methods: We chose to segment sulci and falx cerebri in US volumes, which remain visible during resection. To automatically segment these elements, first we trained a convolutional neural network on manually annotated structures in volumes acquired before the opening of the dura mater and then we applied it to segment corresponding structures in different surgical phases. Finally, the obtained masks are used to register US volumes acquired at multiple resection stages.

Results: Our method reduces the mean target registration error (mTRE) between volumes acquired before the opening of the dura mater and during resection from 3.49 mm (± 1.55 mm) to 1.36 mm (± 0.61 mm). Moreover, the mTRE between volumes acquired before opening the dura mater and at the end of the resection is reduced from 3.54 mm (± 1.75 mm) to 2.05 mm (± 1.12 mm).

Conclusion: The segmented structures demonstrated to be good candidates to register US volumes acquired at different neurosurgical phases. Therefore, our solution can compensate brain shift in neurosurgical procedures involving intraoperative US data.

Citing Articles

Deep Learning-Based Glioma Segmentation of 2D Intraoperative Ultrasound Images: A Multicenter Study Using the Brain Tumor Intraoperative Ultrasound Database (BraTioUS).

Cepeda S, Esteban-Sinovas O, Singh V, Shetty P, Moiyadi A, Dixon L Cancers (Basel). 2025; 17(2.

PMID: 39858097 PMC: 11763412. DOI: 10.3390/cancers17020315.

Quantitative evaluation of the influence of multiple MRI sequences and of pathological tissues on the registration of longitudinal data acquired during brain tumor treatment.

Canalini L, Klein J, Waldmannstetter D, Kofler F, Cerri S, Hering A Front Neuroimaging. 2023; 1:977491.

PMID: 37555157 PMC: 10406206. DOI: 10.3389/fnimg.2022.977491.

Augmented Reality (AR) for Surgical Robotic and Autonomous Systems: State of the Art, Challenges, and Solutions.

Seetohul J, Shafiee M, Sirlantzis K Sensors (Basel). 2023; 23(13).

PMID: 37448050 PMC: 10347167. DOI: 10.3390/s23136202.

Self-Supervised Rigid Registration for Multimodal Retinal Images.

An C, Wang Y, Zhang J, Nguyen T IEEE Trans Image Process. 2022; 31:5733-5747.

PMID: 36040946 PMC: 11211857. DOI: 10.1109/TIP.2022.3201476.

Brain Shift in Neuronavigation of Brain Tumors: An Updated Review of Intra-Operative Ultrasound Applications.

Gerard I, Kersten-Oertel M, Hall J, Sirhan D, Collins D Front Oncol. 2021; 10:618837.

PMID: 33628733 PMC: 7897668. DOI: 10.3389/fonc.2020.618837.

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