Interactive teaching environment for diagnostic radiography with real-time X-ray simulation and patient positioning

Aaron Sujar Garrido; Graham Kelly; Marcos Garcia; Franck Vidal

doi:10.1007/s11548-021-02499-7

Interactive teaching environment for diagnostic radiography with real-time X-ray simulation and patient positioning

Aaron Sujar Garrido, Graham Kelly, Marcos Garcia, Franck Vidal

School of Computer Science & Engineering

Research output: Contribution to journal › Article › peer-review

220 Downloads (Pure)

Abstract

PURPOSE: Traditional undergraduate radiographer training mixes academic lectures and clinical practice. Our goal is to bridge the current disconnection between theory and practice in a safe environment, avoiding the risk of radiation for both practitioners and patients. To this end, this research proposes a new software to teach diagnostic radiography using real-time interactive X-ray simulation and patient positioning.

METHODS: The proposed medical simulator is composed of three main modules. A fast and accurate character animation technique is in charge of simulating the patient positioning phase and adapts their internal anatomy accordingly. gVirtualXRay is an open-source X-ray simulation library and generates the corresponding radiographs in real time. Finally, the courseware allows going through all the diagnostic radiology steps from the patient positioning and the machine configuration to the final image enhancing.

RESULTS: A face and content validation study has been conducted; 18 radiology professionals were recruited to evaluate our software using a questionnaire. The results show that our tool is realistic in many ways (72% of the participants agreed that the simulations are visually realistic), useful (67%) and suitable (78%) for teaching X-ray radiography.

CONCLUSIONS: The proposed tool allows simulating the most relevant steps of the projectional radiography procedure. The virtual patient posing system and X-ray simulation module execute at interactive rates. These features enable the lectures to show their students the results of good and bad practices in a classroom environment, avoiding radiation risk.

Original language	English
Pages (from-to)	85-95
Number of pages	11
Journal	International Journal of Computer Assisted Radiology and Surgery
Volume	17
Issue number	1
Early online date	13 Oct 2021
DOIs	https://doi.org/10.1007/s11548-021-02499-7
Publication status	Published - Jan 2022

Keywords

Virtual Reality
Medical Simulation
X-rays
Diagnostic Radiography
Medical Diagnostic Imaging
Training

Access to Document

10.1007/s11548-021-02499-7Licence: CC BY

Sujar2022_Article_InteractiveTeachingEnvironmentFinal published version, 1.96 MBLicence: CC BY

1 Finished

Fly4PET
Vidal, F. (PI)
1/09/12 → 31/03/17
Project: Research

2 Conference contribution
1 Article

Simulation of X-ray projections on GPU: benchmarking gVirtualXray with clinically realistic phantoms
Pointon, J., Wen, T., Tugwell-Allsup, J., Sujar, A., Létang, J. M. & Vidal, F., Jun 2023, In: Computer Methods and Programs in Biomedicine. 234, 107500.
Research output: Contribution to journal › Article › peer-review

Open Access
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352 Downloads (Pure)
Projectional Radiography Simulator: an Interactive Teaching Tool
Sujar Garrido, A., Kelly, G., Garcia, M. & Vidal, F., 12 Sept 2019, Computer Graphics & Visual Computing (CGVC). The Eurographics Association, p. 125 - 128 4 p.
Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review
gVirtualXRay: Virtual X-Ray Imaging Library on GPU
Sujar, A., Meuleman, A., Villard, P. F., Garcia, M. & Vidal, F., 14 Sept 2017, Computer Graphics & Visual Computing (CGVC) 2017. The Eurographics Association, p. 61-68
Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

gVirtualXRay: an open source library from Bangor University to simulate X-ray images on GPU in real-time
Vidal, F. (Participant)
Impact: Technological, Societal

Cite this

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title = "Interactive teaching environment for diagnostic radiography with real-time X-ray simulation and patient positioning",

abstract = "PURPOSE: Traditional undergraduate radiographer training mixes academic lectures and clinical practice. Our goal is to bridge the current disconnection between theory and practice in a safe environment, avoiding the risk of radiation for both practitioners and patients. To this end, this research proposes a new software to teach diagnostic radiography using real-time interactive X-ray simulation and patient positioning.METHODS: The proposed medical simulator is composed of three main modules. A fast and accurate character animation technique is in charge of simulating the patient positioning phase and adapts their internal anatomy accordingly. gVirtualXRay is an open-source X-ray simulation library and generates the corresponding radiographs in real time. Finally, the courseware allows going through all the diagnostic radiology steps from the patient positioning and the machine configuration to the final image enhancing.RESULTS: A face and content validation study has been conducted; 18 radiology professionals were recruited to evaluate our software using a questionnaire. The results show that our tool is realistic in many ways (72% of the participants agreed that the simulations are visually realistic), useful (67%) and suitable (78%) for teaching X-ray radiography.CONCLUSIONS: The proposed tool allows simulating the most relevant steps of the projectional radiography procedure. The virtual patient posing system and X-ray simulation module execute at interactive rates. These features enable the lectures to show their students the results of good and bad practices in a classroom environment, avoiding radiation risk.",

keywords = "Virtual Reality, Medical Simulation, X-rays, Diagnostic Radiography, Medical Diagnostic Imaging, Training",

author = "{Sujar Garrido}, Aaron and Graham Kelly and Marcos Garcia and Franck Vidal",

note = "This research has been partially funded by: the Spanish Government [TIN2017-83132-C2-1-R and FPU15/05747] and RaSimAS: Regional Anaesthesia Simulator and Assistant - FP7-ICT 610425, and Fly4PET: Fly Algorithm in PET Reconstruction for Radiotherapy Treatment Planning - FP7-PEOPLE-2012-CIG 321968]",

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N2 - PURPOSE: Traditional undergraduate radiographer training mixes academic lectures and clinical practice. Our goal is to bridge the current disconnection between theory and practice in a safe environment, avoiding the risk of radiation for both practitioners and patients. To this end, this research proposes a new software to teach diagnostic radiography using real-time interactive X-ray simulation and patient positioning.METHODS: The proposed medical simulator is composed of three main modules. A fast and accurate character animation technique is in charge of simulating the patient positioning phase and adapts their internal anatomy accordingly. gVirtualXRay is an open-source X-ray simulation library and generates the corresponding radiographs in real time. Finally, the courseware allows going through all the diagnostic radiology steps from the patient positioning and the machine configuration to the final image enhancing.RESULTS: A face and content validation study has been conducted; 18 radiology professionals were recruited to evaluate our software using a questionnaire. The results show that our tool is realistic in many ways (72% of the participants agreed that the simulations are visually realistic), useful (67%) and suitable (78%) for teaching X-ray radiography.CONCLUSIONS: The proposed tool allows simulating the most relevant steps of the projectional radiography procedure. The virtual patient posing system and X-ray simulation module execute at interactive rates. These features enable the lectures to show their students the results of good and bad practices in a classroom environment, avoiding radiation risk.

AB - PURPOSE: Traditional undergraduate radiographer training mixes academic lectures and clinical practice. Our goal is to bridge the current disconnection between theory and practice in a safe environment, avoiding the risk of radiation for both practitioners and patients. To this end, this research proposes a new software to teach diagnostic radiography using real-time interactive X-ray simulation and patient positioning.METHODS: The proposed medical simulator is composed of three main modules. A fast and accurate character animation technique is in charge of simulating the patient positioning phase and adapts their internal anatomy accordingly. gVirtualXRay is an open-source X-ray simulation library and generates the corresponding radiographs in real time. Finally, the courseware allows going through all the diagnostic radiology steps from the patient positioning and the machine configuration to the final image enhancing.RESULTS: A face and content validation study has been conducted; 18 radiology professionals were recruited to evaluate our software using a questionnaire. The results show that our tool is realistic in many ways (72% of the participants agreed that the simulations are visually realistic), useful (67%) and suitable (78%) for teaching X-ray radiography.CONCLUSIONS: The proposed tool allows simulating the most relevant steps of the projectional radiography procedure. The virtual patient posing system and X-ray simulation module execute at interactive rates. These features enable the lectures to show their students the results of good and bad practices in a classroom environment, avoiding radiation risk.

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Interactive teaching environment for diagnostic radiography with real-time X-ray simulation and patient positioning

Abstract

Keywords

Access to Document

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Projects

Fly4PET

Research output

Simulation of X-ray projections on GPU: benchmarking gVirtualXray with clinically realistic phantoms

Projectional Radiography Simulator: an Interactive Teaching Tool

gVirtualXRay: Virtual X-Ray Imaging Library on GPU

Impacts

gVirtualXRay: an open source library from Bangor University to simulate X-ray images on GPU in real-time

Cite this