The availability of advanced tools able to model complex geometries along with the relaxing of the constraints related to the manufacturing technologies are heavily transforming the design approach in many fields, including healthcare. The focus of this paper is on the optimization of porous lightweight cellular geometries in the orthopedic implants design: lattice structures have proven to fulfill the biological, mechanical, and technological constraints required in designing load bearing devices. The aim is to collect the information provided by the related literature to describe the effects induced by the selection of parameters designing lattice gyroid structures for orthopedic implants.
Graded Gyroid Structures for Load Bearing Orthopedic Implants / Guariento L.; Buonamici F.; Marzola A.; Volpe Y.; Governi L.. - ELETTRONICO. - (2020), pp. 02SAMA20-1-02SAMA20-5. (Intervento presentato al convegno 10th IEEE International Conference on "Nanomaterials: Applications and Properties", NAP 2020 tenutosi a ukr nel 2020) [10.1109/NAP51477.2020.9309692].
Graded Gyroid Structures for Load Bearing Orthopedic Implants
Guariento L.;Buonamici F.;Marzola A.;Volpe Y.;Governi L.
2020
Abstract
The availability of advanced tools able to model complex geometries along with the relaxing of the constraints related to the manufacturing technologies are heavily transforming the design approach in many fields, including healthcare. The focus of this paper is on the optimization of porous lightweight cellular geometries in the orthopedic implants design: lattice structures have proven to fulfill the biological, mechanical, and technological constraints required in designing load bearing devices. The aim is to collect the information provided by the related literature to describe the effects induced by the selection of parameters designing lattice gyroid structures for orthopedic implants.
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