Enhanced FEM-based modeling of brain shift deformation in image-guided neurosurgery

Lara M. Vigneron; Romain C. Boman; Jean Philippe Ponthot; Pierre A. Robe; Simon K. Warfield; Jacques G. Verly

doi:10.1016/j.cam.2009.08.062

Enhanced FEM-based modeling of brain shift deformation in image-guided neurosurgery

Lara M. Vigneron, Romain C. Boman, Jean Philippe Ponthot, Pierre A. Robe, Simon K. Warfield, Jacques G. Verly

Research output: Contribution to journal › Article › Academic › peer-review

13 Citations (Scopus)

Abstract

We consider the problem of improving outcomes for neurosurgery patients by enhancing intraoperative navigation and guidance. Current navigation systems do not accurately account for intraoperative brain deformation. We focus on the brain shift deformation that occurs just after the opening of the skull and dura. The heart of our system is a nonrigid registration technique using a biomechanical model. We specifically work on two axes: the representation of the structures in the biomechanical model and the evaluation of the surface landmark displacement fields between intraoperative MR images. Using the modified Hausdorff distance as an image similarity measure, we demonstrate that our approach significantly improves the alignment of the intraoperative images.

Original language	English
Pages (from-to)	2046-2053
Number of pages	8
Journal	Journal of Computational and Applied Mathematics
Volume	234
Issue number	7
DOIs	https://doi.org/10.1016/j.cam.2009.08.062
Publication status	Published - 15 Aug 2010

Keywords

Biomechanical model
Brain shift
FEM
Intraoperative MR
Nonrigid registration

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10.1016/j.cam.2009.08.062

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abstract = "We consider the problem of improving outcomes for neurosurgery patients by enhancing intraoperative navigation and guidance. Current navigation systems do not accurately account for intraoperative brain deformation. We focus on the brain shift deformation that occurs just after the opening of the skull and dura. The heart of our system is a nonrigid registration technique using a biomechanical model. We specifically work on two axes: the representation of the structures in the biomechanical model and the evaluation of the surface landmark displacement fields between intraoperative MR images. Using the modified Hausdorff distance as an image similarity measure, we demonstrate that our approach significantly improves the alignment of the intraoperative images.",

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AU - Boman, Romain C.

AU - Ponthot, Jean Philippe

AU - Robe, Pierre A.

AU - Warfield, Simon K.

AU - Verly, Jacques G.

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AB - We consider the problem of improving outcomes for neurosurgery patients by enhancing intraoperative navigation and guidance. Current navigation systems do not accurately account for intraoperative brain deformation. We focus on the brain shift deformation that occurs just after the opening of the skull and dura. The heart of our system is a nonrigid registration technique using a biomechanical model. We specifically work on two axes: the representation of the structures in the biomechanical model and the evaluation of the surface landmark displacement fields between intraoperative MR images. Using the modified Hausdorff distance as an image similarity measure, we demonstrate that our approach significantly improves the alignment of the intraoperative images.

KW - Biomechanical model

KW - Brain shift

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KW - Nonrigid registration

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Enhanced FEM-based modeling of brain shift deformation in image-guided neurosurgery

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Keywords

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