A navigation system for open liver surgery: design, workflow and first clinical applications

Background The surgical treatment of liver tumours relies on precise localization of the lesions and detailed knowledge of the patient‐specific vascular and biliary anatomy. Detailed three‐dimensional (3D) anatomical information facilitates complete tumour removal while preserving a sufficient amoun...

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Bibliographic Details
Published in:The international journal of medical robotics + computer assisted surgery 2011-03, Vol.7 (1), p.7-16
Main Authors: Peterhans, M., vom Berg, A., Dagon, B., Inderbitzin, D., Baur, C., Candinas, D., Weber, S.
Format: Article
Language:English
Subjects:
Computer-Aided Design
computer-assisted surgery
Equipment Design
Equipment Failure Analysis
Hepatectomy - instrumentation
Humans
Liver
liver surgery
Mathematical models
Navigation
Navigation systems
Pilot Projects
Reproducibility of Results
Robotics - instrumentation
Sensitivity and Specificity
Surgery
Surgery, Computer-Assisted - instrumentation
surgical navigation
Three dimensional
tumour resection
Tumours
User-Computer Interface
virtual resection planning
Workflow
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Summary:Background The surgical treatment of liver tumours relies on precise localization of the lesions and detailed knowledge of the patient‐specific vascular and biliary anatomy. Detailed three‐dimensional (3D) anatomical information facilitates complete tumour removal while preserving a sufficient amount of functional liver tissue. Methods We present an easy to use, clinically applicable navigation system for efficient visualization and tool guidance during liver surgery. Accurate instrument guidance within 3D planning models was achieved with a fast registration procedure, assuming a locally rigid and temporarily static scenario. After deformations occurring during the procedure, efficient means for registration updates are provided. Special focus was given to workflow integration and the minimization of overhead time. The navigation system was validated with nine clinical cases. Results Navigated surgical interventions were performed with a median time overhead of 16.5 min. The navigation technology had a median accuracy of 6.3 mm, improving anatomical orientation and the detection of structures at risk. Conclusions Successful application of the navigation technology to open liver surgery was achieved by minimizing the procedural complexity and optimizing integration within the existing surgical environment. The assumption of locally rigid patient registration was validated, and clinical evaluation shows clear benefits for the surgeon. Copyright © 2010 John Wiley & Sons, Ltd.
ISSN:1478-5951
1478-596X
1478-596X
DOI:10.1002/rcs.360