Journal
COMPUTERS IN BIOLOGY AND MEDICINE
Volume 139, Issue -, Pages -Publisher
PERGAMON-ELSEVIER SCIENCE LTD
DOI: 10.1016/j.compbiomed.2021.105008
Keywords
Finite element analysis (FEA); Additive manufacturing (AM); Patient-specific customised implants (PSCIs); Mandible reconstruction; Biomechanics
Categories
Funding
- Department of Oral and Maxillofacial Surgery, University Hospitals Leuven, Belgium
- China Scholarship Council [201806830109]
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The combination of long and short titanium plates showed superior biomechanical properties for mandible reconstruction compared to a conventional single long plate. It provided higher safety, lower fixation instability, and good bone segment stability during masticatory activities. This preclinical evidence supports the feasibility of using short plates for complete mandible reconstruction and may have implications for treating other large-sized bone defects with customised implants using additive manufacturing technology.
Background: A combination of short titanium plates fabricated using additive manufacturing (AM) provides multiple advantages for complete mandible reconstruction, such as the minimisation of inherent implant deformation formed during AM and the resulting clinical impact, as well as greater flexibility for surgical operation. However, the biomechanical feasibility of this strategy is still unclear, and therefore needs to be explored. Method: Three different combinations of short mandible reconstruction plates (MRPs) were customised considering implant deformation during the AM process. The resulting biomechanical performance was analysed by finite element analysis (FEA) and compared to a conventional single long MRP. Results: The combination of a long plate and a short plate (Design 3 [LL61 mm/RL166 mm]) shows superior biomechanical properties to the conventional single long plate (Design 1 [TL246 mm]) and reveals the most reliable fixation stability among the three designs with short plates. Compared to conventional Design 1, Design 3 provides higher plate safety (maximum tensile stress on plates reduced by 6.3%), lower system fixation instability (relative total displacement reduced by 41.4%), and good bone segment stability (bone segment dislocation below 42.1 mu m) under masticatory activities. Conclusions: Preclinical evidence supports the biomechanical feasibility of using short MRPs for complete mandible reconstruction. Furthermore, the results could also provide valuable information when treating other large-sized bone defects using short customised implants, expanding the potential of AM for use in implant applications.
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