Arthroscopically assisted and three-dimensionally modeled minimally invasive rim plate osteosynthesis via modified anterolateral approach for posterolateral tibial plateau fractures

Aim: The aim of this study was to describe a new, closed, arthroscopically-assisted reduction of posterolateral tibial plateau fractures with minimally invasive plate osteosynthesis using a plate pre-contoured over a 3D-model based on a CT-scan of the injured tibial plateau and positioned by using a minimal anterolateral approach. Methods: A five to six centimeter long curvilinear incision was made over the Gerdy's tubercle. After subcutaneous dissection, the fascia was incised, the ileo-tibial band was split, and the dissection was extended posteriorly. The knee was flexed to 90° and the space between the fibular collateral ligament and the posterolateral plateau rim (para-FCL space) was created. A variable-angle locking compression plate contoured on a 3D-model was inserted flush to the tibial plateau rim. Two cortical screws were placed to ensure support under the area of depression as far posteriorly as possible. Two additional screws were implanted, and a cortical screw was used for the most anterior screw hole. The custom pre-contoured plate based on a person-specific 3D-model, associated with arthroscopy reduction, provides a supporting and containing effect to the posterolateral periarticular fragments and allows a minimally invasive plate osteosynthesis fixation to be performed. This guarantees a proper reduction and fixation without the described limitations and risks associated with the classic approaches. Conclusions: This approach should be considered to treat fractures of the posterolateral plateau, isolated or associated with medial tibial plateau fractures, as it could improve the outcome in terms of lower associated risks, better reduction and fixation, and faster and improved patient recovery.