OBJECTIVE: We have developed a highly interactive virtual environment that enables collaborative examination of stereoscopic three-dimensional (3-D) medical imaging data for planning, discussing, or teaching neurosurgical approaches and strategies. MATERIALS AND METHODS: The system consists of an interactive console with which the user manipulates 3-D data using hand-held and tracked devices within a 3-D virtual workspace and a stereoscopic projection system. The projection system displays the 3-D data on a large screen while the user is working with it. This setup allows users to interact intuitively with complex 3-D data while sharing this information with a larger audience. RESULTS: We have been using this system on a routine clinical basis and during neurosurgical training courses to collaboratively plan and discuss neurosurgical procedures with 3-D reconstructions of patient-specific magnetic resonance and computed tomographic imaging data or with a virtual model of the temporal bone. Working collaboratively with the 3-D information of a large, interactive, stereoscopic projection provides an unambiguous way to analyze and understand the anatomic spatial relationships of different surgical corridors. In our experience, the system creates a unique forum for open and precise discussion of neurosurgical approaches. CONCLUSION: We believe the system provides a highly effective way to work with 3-D data in a group, and it significantly enhances teaching of neurosurgical anatomy and operative strategies.
OBJECTIVE: We have developed a highly interactive virtual environment that enables collaborative examination of stereoscopic three-dimensional (3-D) medical imaging data for planning, discussing, or teaching neurosurgical approaches and strategies. MATERIALS AND METHODS: The system consists of an interactive console with which the user manipulates 3-D data using hand-held and tracked devices within a 3-D virtual workspace and a stereoscopic projection system. The projection system displays the 3-D data on a large screen while the user is working with it. This setup allows users to interact intuitively with complex 3-D data while sharing this information with a larger audience. RESULTS: We have been using this system on a routine clinical basis and during neurosurgical training courses to collaboratively plan and discuss neurosurgical procedures with 3-D reconstructions of patient-specific magnetic resonance and computed tomographic imaging data or with a virtual model of the temporal bone. Working collaboratively with the 3-D information of a large, interactive, stereoscopic projection provides an unambiguous way to analyze and understand the anatomic spatial relationships of different surgical corridors. In our experience, the system creates a unique forum for open and precise discussion of neurosurgical approaches. CONCLUSION: We believe the system provides a highly effective way to work with 3-D data in a group, and it significantly enhances teaching of neurosurgical anatomy and operative strategies.
Authors: Marija Mavar-Haramija; Alberto Prats-Galino; Juan A Juanes Méndez; Anna Puigdelívoll-Sánchez; Matteo de Notaris Journal: J Med Syst Date: 2015-08-26 Impact factor: 4.460
Authors: Matteo de Notaris; Alberto Prats-Galino; Luigi Maria Cavallo; Felice Esposito; Giorgio Iaconetta; Joan Berenguer Gonzalez; Stefania Montagnani; Enrique Ferrer; Paolo Cappabianca Journal: Childs Nerv Syst Date: 2010-02-27 Impact factor: 1.475
Authors: Elena d'Avella; Flavio Angileri; Matteo de Notaris; Joaquin Enseñat; Vita Stagno; Luigi Maria Cavallo; Joan Berenguer Gonzales; Alessandro Weiss; Alberto Prats-Galino Journal: Neurosurg Rev Date: 2014-02-05 Impact factor: 3.042
Authors: Ali Alaraj; Cristian J Luciano; Daniel P Bailey; Abdussalam Elsenousi; Ben Z Roitberg; Antonio Bernardo; P Pat Banerjee; Fady T Charbel Journal: Neurosurgery Date: 2015-03 Impact factor: 4.654