Laboratory Evaluation of a Robotic Operative Microscope - Visualization Platform for Neurosurgery

Background We assessed a new robotic visualization platform with novel user-control features and compared its performance to the previous model of operative microscope. Methods In a neurosurgery research laboratory, we performed anatomical dissections and assessed robotic, exoscopic, endoscopic, fluorescence functionality. Usability and functionality were tested in the operating room over 1 year. Results The robotic microscope showed higher sensitivity for fluorescein sodium, higher detail in non-fluorescent background, and recorded/presented pictures with color quality similar to observation through the oculars. PpIX visualization was comparable to the previous microscope. Near-infrared indocyanine green imaging 3-step replay allowed for more convenient accurate assessment of blood flow. Point lock and pivot point functions were used in dissections to create 3D virtual reality microsurgical anatomy demonstrations. Pivot point control was particularly useful in deep surgical corridors with dynamic retraction. 3D exoscopic function was successfully used in brain tumor and spine cases. Endoscopic assistance was used for around-the-corner views in minimally invasive approaches. We present illustrative cases highlighting utility and new ways to control the operative microscope. Conclusion Improvements of the robotic visualization platform include intraoperative fluorescence visualization using FNa, integrated micro-inspection tool, improved ocular imaging clarity, and exoscopic mode. New robotic movements positively assist the surgeon and provide improved ergonomics and a greater level of intraoperative comfort, with the potential to increase the viewing quality. New operational modes also allow significant impact for anatomy instruction. With the increasing number and complexity of functions, surgeons should receive additional training in order to avail themselves of the advantages of the numerous novel features.

[1]  A. Morita,et al.  Evaluation of Patency After Vascular Anastomosis Using Quantitative Evaluation of Visualization Time in Indocyanine Green Video Angiography. , 2017, World neurosurgery.

[2]  P. Ferroli,et al.  Fluorescein-Guided Resection of Intramedullary Spinal Cord Tumors: Results from a Preliminary, Multicentric, Retrospective Study. , 2017, World neurosurgery.

[3]  P. Ferroli,et al.  Fluorescein-Guided Surgery for Resection of High-Grade Gliomas: A Multicentric Prospective Phase II Study (FLUOGLIO) , 2017, Clinical Cancer Research.

[4]  R. Tubbs,et al.  Advancement of Surgical Visualization Methods: Comparison Study Between Traditional Microscopic Surgery and a Novel Robotic Optoelectronic Visualization Tool for Spinal Surgery. , 2017, World neurosurgery.

[5]  Mohammadhassan Izadyyazdanabadi,et al.  Intraoperative Fluorescence Imaging for Personalized Brain Tumor Resection: Current State and Future Directions , 2016, Front. Surg..

[6]  Michael A. Bohl,et al.  A Prospective Cohort Evaluation of a Robotic, Auto-Navigating Operating Microscope , 2016, Cureus.

[7]  V A Byvaltsev,et al.  [New simulation technologies in neurosurgery]. , 2016, Zhurnal voprosy neirokhirurgii imeni N. N. Burdenko.

[8]  P. Ferroli,et al.  Letter: Intraoperative Assessment of Blood Flow With Quantitative Indocyanine Green Videoangiography: The Role for Diagnosis of Regional Cerebral Hypoperfusion. , 2016, Neurosurgery.

[9]  Marek Romanowski,et al.  Integration of Indocyanine Green Videoangiography With Operative Microscope: Augmented Reality for Interactive Assessment of Vascular Structures and Blood Flow , 2015, Neurosurgery.

[10]  K. Yağmurlu,et al.  Three-Dimensional Topographic Fiber Tract Anatomy of the Cerebrum , 2015, Neurosurgery.

[11]  M. Ammirati,et al.  Quantitative and qualitative analysis of the working area obtained by endoscope and microscope in pterional and orbitozigomatic approach to the basilar artery bifurcation using computed tomography based frameless stereotaxy: A cadaver study , 2015, Asian journal of neurosurgery.

[12]  A. Cohen-Gadol,et al.  A prospective comparative study of microscope-integrated intraoperative fluorescein and indocyanine videoangiography for clip ligation of complex cerebral aneurysms. , 2015, Journal of neurosurgery.

[13]  K. Iihara,et al.  Efficacy of FLOW 800 with indocyanine green videoangiography for the quantitative assessment of flow dynamics in cerebral arteriovenous malformation surgery. , 2015, World Neurosurgery.

[14]  R. Spetzler,et al.  Robotic Autopositioning of the Operating Microscope , 2014, Neurosurgery.

[15]  Francesco Acerbi,et al.  Fluorescein-guided surgery for malignant gliomas: a review , 2014, Neurosurgical Review.

[16]  Francesco Acerbi,et al.  Is fluorescein-guided technique able to help in resection of high-grade gliomas? , 2014, Neurosurgical focus.

[17]  V. Kshettry,et al.  An endoscopic-assisted technique for retrosellar access during the extended retrosigmoid approach: a cadaveric feasibility study and quantitative analysis of retrosellar working area , 2014, Neurosurgical Review.

[18]  E. A. Chiocca,et al.  Quantitative analysis of surgical exposure and maneuverability associated with the endoscope and the microscope in the retrosigmoid and various posterior petrosectomy approaches to the petroclival region using computer tomograpy-based frameless stereotaxy. A cadaveric study , 2013, Clinical Neurology and Neurosurgery.

[19]  Francesco Acerbi,et al.  Fluorescein-guided surgery for grade IV gliomas with a dedicated filter on the surgical microscope: preliminary results in 12 cases , 2013, Acta Neurochirurgica.

[20]  François Conti,et al.  Virtual reality simulation in neurosurgery: technologies and evolution. , 2013, Neurosurgery.

[21]  Achim Schweikard,et al.  Evaluation of a completely robotized neurosurgical operating microscope. , 2013, Neurosurgery.

[22]  Stephan Waldeck,et al.  Intraoperative Image Guidance in Neurosurgery: Development, Current Indications, and Future Trends , 2012, Radiology research and practice.

[23]  Kutluay Uluç,et al.  Operating microscopes: past, present, and future. , 2009, Neurosurgical focus.

[24]  Mark C. Preul,et al.  Multilayer Image Grid Reconstruction Technology: Four-Dimensional Interactive Image Reconstruction of Microsurgical Neuroanatomic Dissections , 2006, Neurosurgery.

[25]  K. Fujii,et al.  Anatomic dissection and classic three-dimensional documentation: a unit of education for neurosurgical anatomy revisited. , 2006, Neurosurgery.

[26]  Mark C Preul,et al.  Intraoperative stereoscopic QuickTime Virtual Reality. , 2004, Journal of neurosurgery.

[27]  Antonio Bernardo,et al.  A Three-dimensional Interactive Virtual Dissection Model to Simulate Transpetrous Surgical Avenues , 2003, Neurosurgery.

[28]  Y. Seki,et al.  "Picture-in-picture" endoscopic images in the microscope. , 1999, Neurosurgical focus.