This paper compares three finite element-based methods used in a physics-based non-rigid registration approach and reports on the progress made over the last 15 years. Large brain shifts caused by brain tumor removal affect registration accuracy by creating point and element outliers. A combination of approximation- and geometry-based point and element outlier rejection improves the rigid registration error by 2.5 mm and meets the real-time constraints (4 min). In addition, the paper raises several questions and presents two open problems for the robust estimation and improvement of registration error in the presence of outliers due to sparse, noisy, and incomplete data. It concludes with preliminary results on leveraging Quantum Computing, a promising new technology for computationally intensive problems like Feature Detection and Block Matching in addition to finite element solver; all three account for 75% of computing time in deformable registration.
Keywords: Image-guided neurosurgery; finite element methods (FEM); high performance computing; mesh generation; physics-based deformable registration.
© 2023 Chrisochoides, Liu, Drakopoulos, Kot, Foteinos, Tsolakis, Billias, Clatz, Ayache, Fedorov, Golby, Black and Kikinis.