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Research Database PMU-SQQUID

Finite element analysis of Bi-condylar Tibial Plateau fractures to assess the effect of coronal splits.
Samsami, S; Herrmann, S; Patzold, R; Winkler, M; Augat, P
MED ENG PHYS. 2020; 84: 84-95.
Full papers/articles (Journal)

PMU-Authors

Augat Peter
P├Ątzold Robert
Samsami Shabnam

Abstract

Bi-condylar tibial plateau fractures are demanding to treat due to the complex geometry and the articular comminution. The presence of a coronal fracture line plays a crucial role in the fixation strategy. Disregarding this fracture line in previous biomechanical studies and established fracture classifications resulted in a lack of detailed knowledge regarding the influence of medial-posterior fragments on implant load sharings. This study aimed to evaluate the effects of coronal splits on stress distributions within the implants using the finite element analysis (FEA). FE models with (Fracture C) and without the coronal split (Fracture H) were developed and validated in order to assess stress distributions within the implant components. Comparing FE outcomes with biomechanical experiments indicated that both fracture models were well validated. FE evaluations demonstrated that the coronal split caused destabilization of the medial tibia, as well as a shift in the peak-stress areas from the middle part of the plate to the proximal section, and a 61% increase in the maximum stress of the kick-stand screw. Therefore, FE models based on clinically-relevant fracture morphologies can provide a reliable tool to assess implant failures as well as to compare different fracture fixation techniques. (C) 2020 Published by Elsevier Ltd on behalf of IPEM.


Find related publications in this database (Keywords)

Bi-condylar tibial plateau fracture
Coronal fracture line
Horwitz fracture model
Coronal fracture model
Finite element analysis
Validation
Stress distribution