BACKGROUND: Through previous efforts we have developed a fully virtual environment to provide procedural training of otologic surgical technique. The virtual environment is based on high-resolution volumetric data of the regional anatomy. These volumetric data help drive an interactive multisensory, ie, visual (stereo), aural (stereo), and tactile, simulation environment. Subsequently, we have extended our efforts to support the training of neurosurgical procedural technique as part of the Congress of Neurological Surgeons simulation initiative. OBJECTIVE: To deliberately study the integration of simulation technologies into the neurosurgical curriculum and to determine their efficacy in teaching minimally invasive cranial and skull base approaches. METHODS: We discuss issues of biofidelity and our methods to provide objective, quantitative and automated assessment for the residents. RESULTS: We conclude with a discussion of our experiences by reporting preliminary formative pilot studies and proposed approaches to take the simulation to the next level through additional validation studies. CONCLUSION: We have presented our efforts to translate an otologic simulation environment for use in the neurosurgical curriculum. We have demonstrated the initial proof of principles and define the steps to integrate and validate the system as an adjuvant to the neurosurgical curriculum.
BACKGROUND: Through previous efforts we have developed a fully virtual environment to provide procedural training of otologic surgical technique. The virtual environment is based on high-resolution volumetric data of the regional anatomy. These volumetric data help drive an interactive multisensory, ie, visual (stereo), aural (stereo), and tactile, simulation environment. Subsequently, we have extended our efforts to support the training of neurosurgical procedural technique as part of the Congress of Neurological Surgeons simulation initiative. OBJECTIVE: To deliberately study the integration of simulation technologies into the neurosurgical curriculum and to determine their efficacy in teaching minimally invasive cranial and skull base approaches. METHODS: We discuss issues of biofidelity and our methods to provide objective, quantitative and automated assessment for the residents. RESULTS: We conclude with a discussion of our experiences by reporting preliminary formative pilot studies and proposed approaches to take the simulation to the next level through additional validation studies. CONCLUSION: We have presented our efforts to translate an otologic simulation environment for use in the neurosurgical curriculum. We have demonstrated the initial proof of principles and define the steps to integrate and validate the system as an adjuvant to the neurosurgical curriculum.
Authors: C V Edmond; D Heskamp; D Sluis; D Stredney; D Sessanna; G Wiet; R Yagel; S Weghorst; P Oppenheimer; J Miller; M Levin; L Rosenberg Journal: Stud Health Technol Inform Date: 1997
Authors: Ricardo L L Dolci; Lívia Castellari Burchianti; Alexandre Bossi Todeschini; Andre Fanhani Lopes; Mirna Duarte Barros; Américo Rubens Leite Dos Santos; Paulo Roberto Lazarini Journal: J Neurol Surg B Skull Base Date: 2018-08-28
Authors: J Scott Pannell; David R Santiago-Dieppa; Arvin R Wali; Brian R Hirshman; Jeffrey A Steinberg; Vincent J Cheung; David Oveisi; Jon Hallstrom; Alexander A Khalessi Journal: Cureus Date: 2016-08-29
Authors: Sergio Garcia-Garcia; Sofia Kakaizada; Laura Oleaga; Arnau Benet; Jordina Rincon-Toroella; José Juan González-Sánchez Journal: Neurol India Date: 2019 May-Jun Impact factor: 2.117