Initial experience with a novel electrophysiology mapping simulator.

BACKGROUND: Despite data supporting the use of simulation training in procedural specialties and accreditation requirements, few options exist for electrophysiology (EP) training. We aimed to develop a low-cost, accessible simulator for training in EP mapping, and to test the simulator in a group of novice users. METHODS: Our mapping simulator is composed of three components: an acrylic case representing torso and thigh; three-dimensional (3D) printed cardiac models; and a commercially available mapping system. Using a proprietary flexible material that mimics the consistency of human heart tissue, we created an anatomically accurate model of a normal right atrium (RA) from computed tomography data. We developed a test protocol consisting of two activities: creation of a RA shell and timed navigation to specific locations within the RA shell. Seventeen participants were randomized to either practice versus no practice on the simulator, and repeated simulator and self-assessment tests were performed after 1 week. We measured volume of the RA map and time taken and distance from the target sites for each target location. RESULTS: Both groups showed improvement in generation of geometry, volume, time to target, and self-assessed comfort level after initial exposure to the simulator. Compared with no-practice, the practice group demonstrated an improved sense of confidence in mapping. CONCLUSIONS: Focused training in EP mapping using a novel simulator created with 3D printed heart models and a standard mapping system is feasible for use in the training environment. Exposure to the simulator is associated with improved mapping skills and trainee comfort level.