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Biomechanical evaluation of unilateral subcondylar fracture of the mandible on the varying materials: A finite element analysis

Bryan Taekyung Jung, Won‐Hyeon Kim, Byungho Park, Jong-Ho Lee, Jong-Ho Lee, Bongju Kim, Jee-Ho Lee, Jee-Ho Lee

2020PLoS ONE22 citationsDOIOpen Access PDF

Abstract

Fixation materials used in the surgical treatment of subcondylar fractures contribute to successful clinical outcomes. In this study, we simulated the mechanical properties of four fixation materials [titanium (Ti), magnesium alloy (Mg alloy), poly-L-lactic acid (PLLA), and hydroxyapatite/poly-L-lactide (HA-PLLA)] in a finite-element analysis model of subcondylar fracture. Two four-hole plates were fixed on the anterior and posterior surfaces of the subcondyle of the mandible. In the simulation model of a subcondylar fracture, we evaluated the stress distribution and mechanical deformation of fixation materials. The stress distribution conspicuously appeared on the condylar neck of the non-fractured side and the center of the anterior plate for all materials. More stress distribution to the biologic component appeared with HA-PLLA than with Ti or Mg alloy, but its effects were less prominent than that of PLLA. The largest deformation was observed with PLLA, followed by HA-PLLA, Mg alloy, and Ti. The results of the present study imply the clinical potential of the HA-PLLA fixation material for open reduction of subcondylar fractures.

Topics & Concepts

Materials scienceCondyleFixation (population genetics)AlloyTitanium alloyMagnesium alloyInternal fixationDeformation (meteorology)Composite materialDentistryOrthodonticsMedicineSurgeryPopulationEnvironmental healthFacial Trauma and Fracture ManagementDental Radiography and ImagingPelvic and Acetabular Injuries
Biomechanical evaluation of unilateral subcondylar fracture of the mandible on the varying materials: A finite element analysis | Litcius