Fractal algorithm for 3D-printed continuous porous scaffold design

In practice, 3D modelling software, such as UG and Pro/E, are commonly adopted to design porous scaffolds within given contours. However, this manual method is quite time-consuming and complicated with poor adaptability. In this study, a novel facial algorithm is proposed for smart scaffold design....

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Vydáno v:	Journal of engineering (Stevenage, England) Ročník 2019; číslo 14; s. 485 - 489
Hlavní autoři:	Zhao, Zongyue, Chen, Xiaojun
Médium:	Journal Article
Jazyk:	angličtina
Vydáno:	The Institution of Engineering and Technology 01.02.2019
Témata:	3D modelling software 3D‐printed continuous porous scaffold design biomedical materials CAD cellular biophysics dendritic fractal network facial algorithm fractal algorithm fractals generated model hollow contour shapes input model orthopaedics porosity porous materials porous scaffolds prosthetics second‐order uniformity smart scaffold design solid modelling The 14th Asian Conference on Computer Aided Surgery (ACCAS 2018) tissue engineering 3D-printed continuous porous scaffold design tissue engineering orthopaedics cellular biophysics input model porosity porous scaffolds CAD smart scaffold design fractals hollow contour shapes fractal algorithm facial algorithm prosthetics generated model biomedical materials porous materials second-order uniformity 3D modelling software solid modelling dendritic fractal network
ISSN:	2051-3305, 2051-3305
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Popis
Shrnutí:	In practice, 3D modelling software, such as UG and Pro/E, are commonly adopted to design porous scaffolds within given contours. However, this manual method is quite time-consuming and complicated with poor adaptability. In this study, a novel facial algorithm is proposed for smart scaffold design. By forming a dendritic fractal network, the second-order uniformity and complete connectivity of pores are guaranteed while considering the axial symmetry of certain orthopaedic implants, and the algorithm is adapted for concave and hollow contour shapes. Through experiments, the stability of the algorithm and the characteristics of the two vital performance indicators, i.e. porosity $P{\rm \; }$P and surface area ratio R, are studied. The results show that P and $R{\rm \; }$R of the generated model are insensitive to the shape of the input model, which proves the stability of authors’ method, and the maximum available porosity reaches 78%, higher than the maximum effective porosity found in the literature.
ISSN:	2051-3305 2051-3305
DOI:	10.1049/joe.2018.9404