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Evaluation of stabilization of intra-articular fracture of distal humerus - finite element study.

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PURPOSE The treatment of comminuted fractures of distal humerus poses a challenge for orthopaedics. Previous studies assessing the global stiffness of the bone - stabilizer system - made it impossible… Click to show full abstract

PURPOSE The treatment of comminuted fractures of distal humerus poses a challenge for orthopaedics. Previous studies assessing the global stiffness of the bone - stabilizer system - made it impossible to explicitly indicate an optimal configuration of the locking plates in the treatment of this kind of fractures. The aim of the present research was to comparatively analyze the stabilization conditions of intraarticular fractures of distal humerus with the use of various configurations of the stabilizer. METHODS The research was based on the analysis of mutual displacements of bone fragments. Such evaluation was performed with the use of numerical simulation conducted with the use of the finite element method. A realistic model of humerus was based on the CT data. Three spatial configurations of the stabilizer (parallel, posteromedial and posterolateral) were considered. The mutual displacements of bone fragments as well as the deformity of the stabilizer under various loading conditions were analyzed. RESULTS In most cases, the parallel setting of the plates ensures a better stabilization of the bone fragments than the perpendicular configuration. The most difficult conditions of stabilization were obtained for the lateral bone fragment. The value of the fragments' displacements significantly increases for loading directions occurring with ascending flexion angle of the joint. CONCLUSIONS In most cases, the parallel setting of the plates ensures a better stabilization of the bone fragments than the perpendicular configuration.

Keywords: finite element; stabilization; bone fragments; distal humerus; humerus

Journal Title: Acta of bioengineering and biomechanics
Year Published: 2020

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