Rubén Lopez Benítez1, Tomás Reyes Del Castillo2, David Benz1, Carsten Fechner1, Lorant Szabo1, Levent Kara3, Etienne Monnard4, Michael Kostrzewa5, Justus E Roos1. 1. Department of Radiology and Nuclear Medicine, Luzerner Kantonsspital, 6000, Lucerne, Switzerland. 2. Department of Radiology and Nuclear Medicine, Luzerner Kantonsspital, 6000, Lucerne, Switzerland. tomas.reyesdelcastillo@luks.ch. 3. Institute of Radiology and Nuclear Medicine, Stadtspital Triemli Zürich, 8063, Zurich, Switzerland. 4. Department of Radiology, Fribourg Hopital Cantonal, 1752, Fribourg, Switzerland. 5. Institute of Radiology, Kantosspital Baden, 5404, Baden, Switzerland.
Abstract
BACKGROUND: The aim of this study was to present a percutaneous transhepatic biliary puncture simulator that can be used without radiation exposure and that reflects the conventional anatomy of the biliary ducts and its vicinity structures. METHODS: An anatomically based model of the biliary tree was developed using a cord network fixed to a wooden frame. The skin, ribs, intercostal muscles, and right lower lobe pleura were simulated using foam sponge, plastic tubes, a polystyrene foam panel, and an air pad, respectively. For the puncture, we used a 20-G Chiba needle and a wire with distal double arches; these were used to troll a cord, simulating the successful puncture of a bile duct. A camera was also placed above the model to allow the trainees to train eye-hand coordination while viewing the image on a monitor in real time. The simulator was tested with 60 radiology residents to evaluate the confidence and skills transferability of the training model. RESULTS: After receiving an introduction of the system and 5 min of training under tutor surveillance, all participants were able to troll a cord of the biliary simulator by themselves in less than 4 min. Only one participant punctured the simulated pleura. The participants' evaluations showed positive results, with increased user confidence and skills transferability after the training session. CONCLUSIONS: This proposed simulator can be an effective tool to improve a trainee's confidence and competence while achieving procedural and non-procedural interventional radiology skills related to the liver. TRIAL REGISTRATION: Retrospectively registered.
BACKGROUND: The aim of this study was to present a percutaneous transhepatic biliary puncture simulator that can be used without radiation exposure and that reflects the conventional anatomy of the biliary ducts and its vicinity structures. METHODS: An anatomically based model of the biliary tree was developed using a cord network fixed to a wooden frame. The skin, ribs, intercostal muscles, and right lower lobe pleura were simulated using foam sponge, plastic tubes, a polystyrene foam panel, and an air pad, respectively. For the puncture, we used a 20-G Chiba needle and a wire with distal double arches; these were used to troll a cord, simulating the successful puncture of a bile duct. A camera was also placed above the model to allow the trainees to train eye-hand coordination while viewing the image on a monitor in real time. The simulator was tested with 60 radiology residents to evaluate the confidence and skills transferability of the training model. RESULTS: After receiving an introduction of the system and 5 min of training under tutor surveillance, all participants were able to troll a cord of the biliary simulator by themselves in less than 4 min. Only one participant punctured the simulated pleura. The participants' evaluations showed positive results, with increased user confidence and skills transferability after the training session. CONCLUSIONS: This proposed simulator can be an effective tool to improve a trainee's confidence and competence while achieving procedural and non-procedural interventional radiology skills related to the liver. TRIAL REGISTRATION: Retrospectively registered.
Authors: P F Villard; F P Vidal; L ap Cenydd; R Holbrey; S Pisharody; S Johnson; A Bulpitt; N W John; F Bello; D Gould Journal: Int J Comput Assist Radiol Surg Date: 2013-07-24 Impact factor: 2.924