Simulation training in neurosurgery: advances in education and practice

Konakondla, Sanjay; Fong, Reginald; Schirmer, Clemens M.

doi:10.2147/amep.s113565

Cited by 69 publications

(40 citation statements)

References 72 publications

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“…Advanced and user-friendly virtual reality simulators with simplified imaging technology could provide the new options for neurosurgical training. 5 We agree with Field et al. 1 that online meetings can serve as virtual conferences and can be performed using the many video conferencing platforms available.…”

supporting

confidence: 86%

Letter to Editor Regarding: “Decrease in Neurosurgical Program Volume During COVID-19: Residency Programs Must Adapt”

et al. 2020

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supporting

confidence: 86%

Letter to Editor Regarding: “Decrease in Neurosurgical Program Volume During COVID-19: Residency Programs Must Adapt”

et al. 2020

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“…Currently, even the most advanced mannequins and computer-generated simulations have very limited capacity to produce a realistic focal neurological deficit or combination of signs and symptoms. Design and implementation of SBME tools is especially challenging in brain disease due to the complexity of the brain, and the variety of its responses to insult ( Chitkara et al, 2013 ; Ermak et al, 2013 ; Fuerch et al, 2015 ; Micieli et al, 2015 ; Konakondla et al, 2017 ). This complexity suggests that back-end multiscale modeling would be particularly valuable in SBME development for brain disease.…”

Section: Use Of Simulation In Medical Educationmentioning

confidence: 99%

Credibility, Replicability, and Reproducibility in Simulation for Biomedicine and Clinical Applications in Neuroscience

Mulugeta

Drach

Erdemir

et al. 2018

Front. Neuroinform.

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Modeling and simulation in computational neuroscience is currently a research enterprise to better understand neural systems. It is not yet directly applicable to the problems of patients with brain disease. To be used for clinical applications, there must not only be considerable progress in the field but also a concerted effort to use best practices in order to demonstrate model credibility to regulatory bodies, to clinics and hospitals, to doctors, and to patients. In doing this for neuroscience, we can learn lessons from long-standing practices in other areas of simulation (aircraft, computer chips), from software engineering, and from other biomedical disciplines. In this manuscript, we introduce some basic concepts that will be important in the development of credible clinical neuroscience models: reproducibility and replicability; verification and validation; model configuration; and procedures and processes for credible mechanistic multiscale modeling. We also discuss how garnering strong community involvement can promote model credibility. Finally, in addition to direct usage with patients, we note the potential for simulation usage in the area of Simulation-Based Medical Education, an area which to date has been primarily reliant on physical models (mannequins) and scenario-based simulations rather than on numerical simulations.

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“…They demonstrate several advantages when compared to physical models (animal or bench models): they have a lower cost in use, there is no limit in the repetitions, and they offer a great sense of variety and diversity in the simulated cases. However, the resolution and realism of the constructed world are still issues to be resolved [37].…”

Section: Neurosurgerymentioning

confidence: 99%

“…Other specialized variations of the simulator also exist, such as the NeuroTouch Cranio, a simulator for brain tumor resection. The trainer provides haptic feedback and measures the trainee's performance [37].…”

Section: Neurosurgerymentioning

confidence: 99%

Virtual and Augmented Reality in Medical Education

Pantelidis¹,

Chorti²,

Papagiouvanni³

et al. 2018

Medical and Surgical Education - Past, Present and Future

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Virtual reality (VR) and augmented reality (AR) are two contemporary simulation models that are currently upgrading medical education. VR provides a 3D and dynamic view of structures and the ability of the user to interact with them. The recent technological advances in haptics, display systems, and motion detection allow the user to have a realistic and interactive experience, enabling VR to be ideal for training in hands-on procedures. Consequently, surgical and other interventional procedures are the main fields of application of VR. AR provides the ability of projecting virtual information and structures over physical objects, thus enhancing or altering the real environment. The integration of AR applications in the understanding of anatomical structures and physiological mechanisms seems to be beneficial. Studies have tried to demonstrate the validity and educational effect of many VR and AR applications, in many different areas, employed via various hardware platforms. Some of them even propose a curriculum that integrates these methods. This chapter provides a brief history of VR and AR in medicine, as well as the principles and standards of their function. Finally, the studies that show the effect of the implementation of these methods in different fields of medical training are summarized and presented.

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Simulation training in neurosurgery: advances in education and practice

Cited by 69 publications

References 72 publications

Letter to Editor Regarding: “Decrease in Neurosurgical Program Volume During COVID-19: Residency Programs Must Adapt”

Letter to Editor Regarding: “Decrease in Neurosurgical Program Volume During COVID-19: Residency Programs Must Adapt”

Credibility, Replicability, and Reproducibility in Simulation for Biomedicine and Clinical Applications in Neuroscience

Virtual and Augmented Reality in Medical Education

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