Russian doll deployable meta-implants

Fusion of kirigami, origami, and multi-stability

Journal Article (2020)
Author(s)

Françoise S.L. Bobbert (TU Delft - Biomaterials & Tissue Biomechanics)

Shahram Janbaz (TU Delft - Biomaterials & Tissue Biomechanics)

T. van Manen (TU Delft - Biomaterials & Tissue Biomechanics)

Y. Li (TU Delft - Biomaterials & Tissue Biomechanics)

Amir Zadpoor (TU Delft - Biomaterials & Tissue Biomechanics)

Research Group
Biomaterials & Tissue Biomechanics
Copyright
© 2020 F.S.L. Bobbert, S. Janbaz, T. van Manen, Y. Li, A.A. Zadpoor
DOI related publication
https://doi.org/10.1016/j.matdes.2020.108624
More Info
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Publication Year
2020
Language
English
Copyright
© 2020 F.S.L. Bobbert, S. Janbaz, T. van Manen, Y. Li, A.A. Zadpoor
Research Group
Biomaterials & Tissue Biomechanics
Volume number
191
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Abstract

Deployable meta-implants aim to minimize the invasiveness of orthopaedic surgeries by allowing for changes in their shape and size that are triggered by an external stimulus. Multi-stability enables deployable implants to transform their shape from some compact retracted state to the deployed state where they take their full sizes and are load-bearing. We combined multiple design features to develop a new generation of deployable orthopaedic implants. Kirigami cut patterns were used to create bi-stability in flat sheets which can be folded into deployable implants using origami techniques. Inspired by Russian dolls, we designed multi-layered specimens that allow for adjusting the mechanical properties and the geometrical features of the implants through the number of the layers. Because all layers are folded from a flat state, surface-related functionalities could be applied to our deployable implants. We fabricated specimens from polylactic acid, titanium sheets, and aluminum sheets, and demonstrated that a deployment ratio of up to ≈2 is possible. We performed experiments to characterize the deployment and load-bearing behavior of the specimens and found that the above-mentioned design variables allow for adjustments in the deployment force and the maximum force before failure. Finally, we demonstrate the possibility of decorating the specimens with micropatterns.