SlicerCBM: automatic framework for biomechanical analysis of the brain

Saima Safdar; Benjamin F Zwick; Yue Yu; George C Bourantas; Grand R Joldes; Simon K Warfield; Damon E Hyde; Sarah Frisken; Tina Kapur; Ron Kikinis; Alexandra Golby; Arya Nabavi; Adam Wittek; Karol Miller

doi:10.1007/s11548-023-02881-7

SlicerCBM: automatic framework for biomechanical analysis of the brain

Int J Comput Assist Radiol Surg. 2023 Oct;18(10):1925-1940. doi: 10.1007/s11548-023-02881-7. Epub 2023 Apr 1.

Authors

Saima Safdar¹, Benjamin F Zwick², Yue Yu², George C Bourantas^{2

3}, Grand R Joldes², Simon K Warfield^{4

5}, Damon E Hyde^{4

5}, Sarah Frisken^{6

5}, Tina Kapur^{6

5}, Ron Kikinis^{6

5}, Alexandra Golby^{6

5}, Arya Nabavi⁷, Adam Wittek², Karol Miller^{2

5}

Affiliations

¹ Intelligent Systems for Medicine Laboratory, The University of Western Australia, 35 Stirling Highway, Perth, WA, Australia. saima.safdar@research.uwa.edu.au.
² Intelligent Systems for Medicine Laboratory, The University of Western Australia, 35 Stirling Highway, Perth, WA, Australia.
³ Department of Agriculture, University of Patras Nea Ktiria, 30200, Campus Mesologhi, Greece.
⁴ Computational Radiology Laboratory, Boston Children's Hospital, Boston, MA, USA.
⁵ Harvard Medical School, Boston, MA, USA.
⁶ Brigham and Women's Hospital, Boston, MA, USA.
⁷ Department of Neurosurgery, KRH Klinikum Nordstadt, Hannover, Germany.

Abstract

Purpose: Brain shift that occurs during neurosurgery disturbs the brain's anatomy. Prediction of the brain shift is essential for accurate localisation of the surgical target. Biomechanical models have been envisaged as a possible tool for such predictions. In this study, we created a framework to automate the workflow for predicting intra-operative brain deformations.

Methods: We created our framework by uniquely combining our meshless total Lagrangian explicit dynamics (MTLED) algorithm for computing soft tissue deformations, open-source software libraries and built-in functions within 3D Slicer, an open-source software package widely used for medical research. Our framework generates the biomechanical brain model from the pre-operative MRI, computes brain deformation using MTLED and outputs results in the form of predicted warped intra-operative MRI.

Results: Our framework is used to solve three different neurosurgical brain shift scenarios: craniotomy, tumour resection and electrode placement. We evaluated our framework using nine patients. The average time to construct a patient-specific brain biomechanical model was 3 min, and that to compute deformations ranged from 13 to 23 min. We performed a qualitative evaluation by comparing our predicted intra-operative MRI with the actual intra-operative MRI. For quantitative evaluation, we computed Hausdorff distances between predicted and actual intra-operative ventricle surfaces. For patients with craniotomy and tumour resection, approximately 95% of the nodes on the ventricle surfaces are within two times the original in-plane resolution of the actual surface determined from the intra-operative MRI.

Conclusion: Our framework provides a broader application of existing solution methods not only in research but also in clinics. We successfully demonstrated the application of our framework by predicting intra-operative deformations in nine patients undergoing neurosurgical procedures.

Keywords: Biomechanics; Brain deformation; Brain shift; Framework.

MeSH terms

Brain Neoplasms* / diagnostic imaging
Brain Neoplasms* / pathology
Brain Neoplasms* / surgery
Brain* / diagnostic imaging
Brain* / pathology
Brain* / surgery
Craniotomy
Humans
Magnetic Resonance Imaging / methods
Neurosurgical Procedures

Abstract

MeSH terms

Grants and funding