Abstract
Purpose
A patient registration and real-time surgical navigation system and a novel device and method (Noctopus) is presented. With any tracking system technology and a patient/target-specific registration marker configuration, submillimetric target registration error (TRE), high-precise application accuracy for single or multiple anatomical targets in image-guided neurosurgery or ENT surgery is realized.
Methods
The system utilizes the advantages of marker-based registration technique and allows to perform automatized patient registration using on the device attached and with patient scanned four fiducial markers. The best possible sensor/marker positions around the patient’s head are determined for single or multiple region(s) of interest (target/s) in the anatomy. Once brought at the predetermined positions the device can be operated with any tracking system for registration purposes.
Results
Targeting accuracy was evaluated quantitatively at various target positions on a phantom skull. The target registration error (TRE) was measured on individual targets using an electromagnetic tracking system. The overall averaged TRE was 0.22 ± 0.08 mm for intraoperative measurements.
Conclusion
An automatized patient registration system using optimized patient-/target-specific marker configurations is proposed. High-precision and user-error-free intraoperative surgical navigation with minimum number of registration markers and sensors is realized. The targeting accuracy is significantly improved in minimally invasive neurosurgical and ENT interventions.
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Funding
This study was funded by Austria Wirtschaftsservice (AWS) under the project number P2407952-PSL01 and partly funded by Medical University of Innsbruck under the project number D-153110-015-014.
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Özbek, Y., Bárdosi, Z. & Freysinger, W. Noctopus: a novel device and method for patient registration and navigation in image-guided cranial surgery. Int J CARS (2024). https://doi.org/10.1007/s11548-024-03135-w
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DOI: https://doi.org/10.1007/s11548-024-03135-w