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A bio-inspired remodelling algorithm combined with a natural neighbour meshless method to obtain optimized functionally graded materials
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Authors
Advisor(s)
Abstract(s)
Recent developments suggest the use of triply periodic minimal surfaces (such as the gyroid) as a possibility for
bone tissue scaffold. Moreover, through functional gradients of cellular structures, the mechanical properties
can be edited and enhanced to achieve the most efficient results. One of the main concerns when designing
bone scaffold is avoiding stress shielding, which occurs when the Young’s modulus of the implant is higher than
the Young’s modulus of the bone it is replacing. If so, bone decay occurs in the surrounding tissue. While the
literature possesses some approaches exploring functional gradients of material density, there are no solutions
based on bone tissue phenomenological laws. Thus, the gyroid infill obtained with PLA (𝐸 = 3145 MPa) was
characterized with mechanical tests, namely tensile and compression, and the obtained model was implemented
in a bone remodelling algorithm. Using the natural neighbour radial point interpolation method (NNRPIM)
it was found that similar bone density distributions were obtained for the gyroid infill and for bone tissue
when subject to the same boundary conditions. Finally, the gyroid mechanical behaviour was extrapolated to
other materials and it was concluded that similar properties can be obtained for bone tissue and titanium alloy
(𝐸 = 110 GPa) scaffold.
Description
Keywords
FEM Natural neighbour radial point interpolation method Bio-inspired remodelling algorithm Gyroid Bone scaffold
Citation
Publisher
Elsevier