Practice on an Augmented Reality/Haptic Simulator and Library of Virtual Brains Improves Residents’ Ability to Perform a Ventriculostomy
Autor: | David M. Frim, Kelly M. Smith, Pat Banerjee, Silvio Rizzi, Richard W. Byrne, Fady T. Charbel, Cristian Luciano, Bernard R. Bendok, G. Michael Lemole, Alan Schwartz, Rachel Yudkowsky, Ali Alaraj |
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Rok vydání: | 2013 |
Předmět: |
Ventriculostomy
medicine.medical_specialty Engineering Epidemiology medicine.medical_treatment Neurosurgery Medicine (miscellaneous) Virtual reality Education User-Computer Interface Surveys and Questionnaires Medical Staff Hospital medicine Humans Computer Simulation Simulation Haptic technology Chicago business.industry Brain Computer-mediated reality Neurosurgical Procedure Catheter Touch Perception Modeling and Simulation Augmented reality business |
Zdroj: | Simulation in Healthcare: The Journal of the Society for Simulation in Healthcare. 8:25-31 |
ISSN: | 1559-2332 |
DOI: | 10.1097/sih.0b013e3182662c69 |
Popis: | Introduction Ventriculostomy is a neurosurgical procedure for providing therapeutic cerebrospinal fluid drainage. Complications may arise during repeated attempts at placing the catheter in the ventricle. We studied the impact of simulation-based practice with a library of virtual brains on neurosurgery residents' performance in simulated and live surgical ventriculostomies. Methods Using computed tomographic scans of actual patients, we developed a library of 15 virtual brains for the ImmersiveTouch system, a head- and hand-tracked augmented reality and haptic simulator. The virtual brains represent a range of anatomies including normal, shifted, and compressed ventricles. Neurosurgery residents participated in individual simulator practice on the library of brains including visualizing the 3-dimensional location of the catheter within the brain immediately after each insertion. Performance of participants on novel brains in the simulator and during actual surgery before and after intervention was analyzed using generalized linear mixed models. Results Simulator cannulation success rates increased after intervention, and live procedure outcomes showed improvement in the rate of successful cannulation on the first pass. However, the incidence of deeper, contralateral (simulator) and third-ventricle (live) placements increased after intervention. Residents reported that simulations were realistic and helpful in improving procedural skills such as aiming the probe, sensing the pressure change when entering the ventricle, and estimating how far the catheter should be advanced within the ventricle. Conclusions Simulator practice with a library of virtual brains representing a range of anatomies and difficulty levels may improve performance, potentially decreasing complications due to inexpert technique. |
Databáze: | OpenAIRE |
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