Informatics in radiology: use of a C-arm fluoroscopy simulator to support training in intraoperative radiography.

Mobile image intensifier systems (C-arms) are used frequently in orthopedic and reconstructive surgery, especially in trauma and emergency settings, but image quality and radiation exposure levels may vary widely, depending on the extent of the C-arm operator's knowledge and experience. Current training programs consist mainly of theoretical instruction in C-arm operation, the physical foundations of radiography, and radiation avoidance, and are largely lacking in hands-on application. A computer-based simulation program such as that tested by the authors may be one way to improve the effectiveness of C-arm training. In computer simulations of various scenarios commonly encountered in the operating room, trainees using the virtX program interact with three-dimensional models to test their knowledge base and improve their skill levels. Radiographs showing the simulated patient anatomy and surgical implants are "reconstructed" from data computed on the basis of the trainee's positioning of models of a C-arm, patient, and table, and are displayed in real time on the desktop monitor. Trainee performance is signaled in real time by color graphics in several control panels and, on completion of the exercise, is compared in detail with the performance of an expert operator. Testing of this computer-based training program in continuing medical education courses for operating room personnel showed an improvement in the overall understanding of underlying principles of intraoperative radiography performed with a C-arm, with resultant higher image quality, lower overall radiation exposure, and greater time efficiency. Supplemental material available at http://radiographics.rsna.org/lookup/suppl/doi:10.1148/rg.313105125/-/DC1.

[1]  W. Panzer,et al.  Skill dependence of radiation exposure for the orthopaedic surgeon during interlocking nailing of long-bone shaft fractures: a clinical study , 2004, Archives of Orthopaedic and Trauma Surgery.

[2]  R. Dega,et al.  Measurement of the dose of radiation to the surgeon during surgery to the foot and ankle. , 2007, The Journal of bone and joint surgery. British volume.

[3]  John Damilakis,et al.  Estimation of Patient Dose and Associated Radiogenic Risks From Fluoroscopically Guided Pedicle Screw Insertion , 2004, Spine.

[4]  J. McElwain,et al.  Radiation exposure of the hands and thyroid gland during percutaneous wiring of wrist and hand procedures. , 2006, Acta orthopaedica Belgica.

[5]  Sebastian Garde,et al.  Can design principles of traditional learning theories be fulfilled by computer-based training systems in medicine: The example of CAMPUS , 2007, Int. J. Medical Informatics.

[6]  M R Fischer,et al.  Do computers teach better? A media comparison study for case-based teaching in radiology. , 2001, Radiographics : a review publication of the Radiological Society of North America, Inc.

[7]  N. Theocharopoulos,et al.  Occupational exposure from common fluoroscopic projections used in orthopaedic surgery. , 2003, The Journal of bone and joint surgery. American volume.

[8]  R. Graham,et al.  Radiology education: a glimpse into the future. , 2006, Clinical radiology.

[9]  K M Stürmer,et al.  [Radiation dosage of the surgery from intraoperative roentgen procedures: risks and dose management in the operating room]. , 1998, Langenbecks Archiv fur Chirurgie. Supplement. Kongressband. Deutsche Gesellschaft fur Chirurgie. Kongress.

[10]  Oliver J. Bott,et al.  An Approach to Calculate and Visualize Intraoperative Scattered Radiation Exposure , 2009, MIE.

[11]  Kunio Doi,et al.  Physical characteristics of scattered radiation and the performance of antiscatter grids in diagnostic radiology , 1982 .

[12]  J. Hallett,et al.  Use of a laser guide to reduce screening time for the dynamic hip screw. , 1996, Injury.

[13]  W. Lee,et al.  Computer-based learning in medical education: a critical view. , 2006, Journal of the American College of Radiology : JACR.

[14]  D. Gould,et al.  Interventional radiology simulation: prepare for a virtual revolution in training. , 2007, Journal of vascular and interventional radiology : JVIR.

[15]  K. Stürmer,et al.  [Measuring intraoperative radiation exposure of the trauma surgeon. Measuring eye, thyroid gland and hand with highly sensitive thermoluminescent detectors]. , 1999, Der Unfallchirurg.

[16]  M Marschollek,et al.  virtX – Evaluation of a Computer-based Training System for Mobile C-arm Systems in Trauma and Orthopedic Surgery , 2008, Methods of Information in Medicine.

[17]  L. Hedman,et al.  A Randomized Trial of Simulation-Based Versus Conventional Training of Dental Student Skill at Interpreting Spatial Information in Radiographs , 2007, Simulation in healthcare : journal of the Society for Simulation in Healthcare.

[18]  Oliver J. Bott,et al.  Improving education on C-arm operation and radiation protection with a computer-based training and simulation system , 2009, International Journal of Computer Assisted Radiology and Surgery.

[19]  I. Harris,et al.  Radiation exposure using laser aiming guide in orthopaedic procedures , 2002, ANZ journal of surgery.

[20]  T. Desser Simulation-based training: the next revolution in radiology education? , 2007, Journal of the American College of Radiology : JACR.

[21]  M. Wagner,et al.  virtX : Virtuelles Lehr- und Lernsystem für den Einsatz mobiler Bildverstärkersysteme (Leitthema) , 2009 .