OBJECTIVE: To characterize the accuracy of the Magellan electromagnetic navigation system (Biosense Webster, Tirat HaCarmel, Israel) and to demonstrate the feasibility of its use in image-guided neurosurgical applications. DESCRIPTION OF INSTRUMENTATION: The Magellan system was developed to provide real-time tracking of the distal tips of flexible catheters, steerable endoscopes, and other surgical instruments, using ultra-low electromagnetic fields and a novel miniature position sensor for image-correlated intraoperative navigation and mapping applications. METHODS: An image registration procedure was performed, and static and qualitative accuracies were assessed in a series of phantom, animal, and human neurosurgical studies. EXPERIENCE AND RESULTS: During the human study phase, an accuracy error of up to 5 mm was deemed acceptable. Results demonstrated that this degree of accuracy was maintained throughout all procedures. All anatomic landmarks were reached with precision and were accurately viewed on the display screen. Navigation that relied on the system was also successful. No interference with operating room equipment was noted. The accuracy of the system was maintained during regular surgical procedures, using standard surgical tools. CONCLUSION: The system provides precise lesion localization without limiting the line of vision, the mobility of the surgeon, or the flexibility of instruments. Electromagnetic navigation promises new advances in neuronavigation and frameless stereotactic surgery.
OBJECTIVE: To characterize the accuracy of the Magellan electromagnetic navigation system (Biosense Webster, Tirat HaCarmel, Israel) and to demonstrate the feasibility of its use in image-guided neurosurgical applications. DESCRIPTION OF INSTRUMENTATION: The Magellan system was developed to provide real-time tracking of the distal tips of flexible catheters, steerable endoscopes, and other surgical instruments, using ultra-low electromagnetic fields and a novel miniature position sensor for image-correlated intraoperative navigation and mapping applications. METHODS: An image registration procedure was performed, and static and qualitative accuracies were assessed in a series of phantom, animal, and human neurosurgical studies. EXPERIENCE AND RESULTS: During the human study phase, an accuracy error of up to 5 mm was deemed acceptable. Results demonstrated that this degree of accuracy was maintained throughout all procedures. All anatomic landmarks were reached with precision and were accurately viewed on the display screen. Navigation that relied on the system was also successful. No interference with operating room equipment was noted. The accuracy of the system was maintained during regular surgical procedures, using standard surgical tools. CONCLUSION: The system provides precise lesion localization without limiting the line of vision, the mobility of the surgeon, or the flexibility of instruments. Electromagnetic navigation promises new advances in neuronavigation and frameless stereotactic surgery.
Authors: Vaibhav Patil; Rajiv Gupta; Raúl San José Estépar; Ronilda Lacson; Arnold Cheung; Judith M Wong; A John Popp; Alexandra Golby; Christopher Ogilvy; Kirby G Vosburgh Journal: Stereotact Funct Neurosurg Date: 2015-01-31 Impact factor: 1.875
Authors: Bernhard C Meyer; Olaf Peter; Markus Nagel; Martin Hoheisel; Bernd B Frericks; Karl-Jürgen Wolf; Frank K Wacker Journal: Eur Radiol Date: 2008-06-11 Impact factor: 5.315
Authors: Olaf Suess; Silke Suess; Sven Mularski; Björn Kühn; Thomas Picht; Stefanie Hammersen; Rüdiger Stendel; Mario Brock; Theodoros Kombos Journal: Head Face Med Date: 2006-04-26 Impact factor: 2.151
Authors: Boris Rivkin; Christian Becker; Balram Singh; Azaam Aziz; Farzin Akbar; Aleksandr Egunov; Dmitriy D Karnaushenko; Ronald Naumann; Rudolf Schäfer; Mariana Medina-Sánchez; Daniil Karnaushenko; Oliver G Schmidt Journal: Sci Adv Date: 2021-12-17 Impact factor: 14.136