BACKGROUND: Use of the operating microscope has become pervasive since its introduction to the neurosurgical world. Neuronavigation fused with the operating microscope has allowed accurate correlation of the focal point of the microscope and its location on the downloaded imaging study. However, the robotic ability of the Pentero microscope has not been utilized to orient the angle of the microscope or to change its focal length to hone in on a predefined target. OBJECTIVE: To report a novel technology that allows automatic positioning of the operating microscope onto a set target and utilization of a planned trajectory, either determined with the StealthStation S7 by using preoperative imaging or intraoperatively with the microscope. METHODS: By utilizing the current motorized capabilities of the Zeiss OPMI Pentero microscope, a robotic autopositioning feature was developed in collaboration with Surgical Technologies, Medtronic, Inc. (StealthStation S7). The system is currently being tested at the Barrow Neurological Institute. RESULTS: Three options were developed for automatically positioning the microscope: AutoLock Current Point, Align Parallel to Plan, and Point to Plan Target. These options allow the microscope to pivot around the lesion, hover in a set plane parallel to the determined trajectory, or rotate and point to a set target point, respectively. CONCLUSION: Integration of automatic microscope positioning into the operative workflow has potential to increase operative efficacy and safety. This technology is best suited for precise trajectories and entry points into deep-seated lesions.
BACKGROUND: Use of the operating microscope has become pervasive since its introduction to the neurosurgical world. Neuronavigation fused with the operating microscope has allowed accurate correlation of the focal point of the microscope and its location on the downloaded imaging study. However, the robotic ability of the Pentero microscope has not been utilized to orient the angle of the microscope or to change its focal length to hone in on a predefined target. OBJECTIVE: To report a novel technology that allows automatic positioning of the operating microscope onto a set target and utilization of a planned trajectory, either determined with the StealthStation S7 by using preoperative imaging or intraoperatively with the microscope. METHODS: By utilizing the current motorized capabilities of the Zeiss OPMI Pentero microscope, a robotic autopositioning feature was developed in collaboration with Surgical Technologies, Medtronic, Inc. (StealthStation S7). The system is currently being tested at the Barrow Neurological Institute. RESULTS: Three options were developed for automatically positioning the microscope: AutoLock Current Point, Align Parallel to Plan, and Point to Plan Target. These options allow the microscope to pivot around the lesion, hover in a set plane parallel to the determined trajectory, or rotate and point to a set target point, respectively. CONCLUSION: Integration of automatic microscope positioning into the operative workflow has potential to increase operative efficacy and safety. This technology is best suited for precise trajectories and entry points into deep-seated lesions.
Authors: Bassel Zebian; Francesco Vergani; José Pedro Lavrador; Soumya Mukherjee; William John Kitchen; Vita Stagno; Christos Chamilos; Benedetta Pettorini; Conor Mallucci Journal: CNS Oncol Date: 2016-12-21
Authors: Evgenii Belykh; Nikolay L Martirosyan; Kaan Yagmurlu; Eric J Miller; Jennifer M Eschbacher; Mohammadhassan Izadyyazdanabadi; Liudmila A Bardonova; Vadim A Byvaltsev; Peter Nakaji; Mark C Preul Journal: Front Surg Date: 2016-10-17
Authors: Justin R Mascitelli; Leslie Schlachter; Alexander G Chartrain; Holly Oemke; Jeffrey Gilligan; Anthony B Costa; Raj K Shrivastava; Joshua B Bederson Journal: Oper Neurosurg (Hagerstown) Date: 2018-08-01 Impact factor: 2.703
Authors: Evgenii G Belykh; Xiaochun Zhao; Claudio Cavallo; Michael A Bohl; Kaan Yagmurlu; Joseph L Aklinski; Vadim A Byvaltsev; Nader Sanai; Robert F Spetzler; Michael T Lawton; Peter Nakaji; Mark C Preul Journal: Cureus Date: 2018-07-30