Augmented Reality to Compensate for Navigation Inaccuracies.
Miriam H A BoppFelix CorrBenjamin SassMirza PojskicAndré KemmlingChristopher NimskyPublished in: Sensors (Basel, Switzerland) (2022)
This study aims to report on the capability of microscope-based augmented reality (AR) to evaluate registration and navigation accuracy with extracranial and intracranial landmarks and to elaborate on its opportunities and obstacles in compensation for navigation inaccuracies. In a consecutive single surgeon series of 293 patients, automatic intraoperative computed tomography-based registration was performed delivering a high initial registration accuracy with a mean target registration error of 0.84 ± 0.36 mm. Navigation accuracy is evaluated by overlaying a maximum intensity projection or pre-segmented object outlines within the recent focal plane onto the in situ patient anatomy and compensated for by translational and/or rotational in-plane transformations. Using bony landmarks (85 cases), there was two cases where a mismatch was seen. Cortical vascular structures (242 cases) showed a mismatch in 43 cases and cortex representations (40 cases) revealed two inaccurate cases. In all cases, with detected misalignment, a successful spatial compensation was performed (mean correction: bone (6.27 ± 7.31 mm), vascular (3.00 ± 1.93 mm, 0.38° ± 1.06°), and cortex (5.31 ± 1.57 mm, 1.75° ± 2.47°)) increasing navigation accuracy. AR support allows for intermediate and straightforward monitoring of accuracy, enables compensation of spatial misalignments, and thereby provides additional safety by increasing overall accuracy.
Keyphrases
- computed tomography
- end stage renal disease
- magnetic resonance imaging
- ejection fraction
- newly diagnosed
- functional connectivity
- high resolution
- chronic kidney disease
- prognostic factors
- peritoneal dialysis
- magnetic resonance
- high intensity
- patients undergoing
- positron emission tomography
- body composition
- single cell
- contrast enhanced
- middle cerebral artery
- pet ct