Surgical advantages of using 3D patient-specific models in high-energy tibial plateau fractures.

ABSTRACT

PURPOSE: Treatment of tibial plateau fractures are difficult due to the intra-articular nature of the proximal tibia and extensive involvement of the soft tissue envelope. In this study, we investigated the surgical experience acquired using digitally designed life-size fracture models to guide as a template to place plates and screws in the treatment of tibial plateau fractures and anatomic reduction of joint. METHODS: 20 tibial plateau frature patients were divided into two equal surgery groups as conventional versus 3D model assisted. The fracture line angles, depression depth, and preoperative/postoperative Rasmussen knee score were measured for each patient. RESULTS: The duration of the operation, blood loss volume, turniquet time and number of intraoperative fluoroscopy was 89.5 ± 5.9 min, 160.5 ± 15.3 ml, 74.5 ± 6 min and 10.7 ± 1.76 times, for 3D printing group and 127 ± 14.5 min, 276 ± 44.8 ml, 104.5 ± 5.5 min and 18.5 ± 2.17 times for the conventional group, respectively. 3D model-assisted group indicated significantly shorter operation time, less blood loss volume, shorter turniquet and fluoroscopy times, and better outcome than the conventional one. CONCLUSIONS: The customized 3D model was user friendly, and it provided a radiation-free tibial screw insertion. The use of these models assisted surgical planning, maximized the possibility of ideal anatomical reduction and provided individualized information concerning tibial plateau fractures.