Exploiting generative design for multi-material inkjet 3D printed cell instructive, bacterial biofilm resistant composites

Yinfeng He; Belen Begines; Gustavo F. Trindade; Meisam Abdi; Jean-Frédéric Dubern; Elisabetta Prina; Andrew L. Hook; Gabriel Choong; Javier Ledesma; Christopher J. Tuck; Felicity R. A. J. Rose; Richard Hague; Clive J. Roberts; Davide De de Focatiis; Ian A.  Ashcroft; Paul Williams; Derek J. Irvine; Morgan R. Alexander; Ricky D.  Wildman

doi:10.26434/chemrxiv.12596999.v1

Exploiting generative design for multi-material inkjet 3D printed cell instructive, bacterial biofilm resistant composites

Yinfeng He, Belen Begines, Gustavo F. Trindade, Meisam Abdi, Jean-Frédéric Dubern, Elisabetta Prina, Andrew L. Hook, Gabriel Choong, Javier Ledesma, Christopher J. Tuck, Felicity R. A. J. Rose, Richard Hague, Clive J. Roberts, Davide De de Focatiis, Ian A. Ashcroft, Paul Williams, Derek J. Irvine, Morgan R. Alexander, Ricky D. Wildman

Research output: Working paper

Abstract

As our understanding of disease grows, it is becoming established that treatment needs to be personalized and targeted to the needs of the individual. In this paper we show that multi-material inkjet-based 3D printing, when backed with generative design algorithms, can bring a step change in the personalization of medical devices. We take cell-instructive materials known for their resistance to bacterial biofilm formation and reformulate for multi-material inkjet-based 3D printing. Specimens with customizable mechanical moduli are obtained without loss of their cell-instructive properties. The manufacturing is coupled to a design algorithm that takes a user-specified deformation and computes the distribution of the materials needed to meet the target under given load constraints. Optimisation led to a voxel map file defining where different materials should be placed. Manufactured products were assessed against the mechanical and cell-instructive specifications and ultimately showed how multifunctional personalization emerges from generative design driven 3D printing.

Original language	English
Place of Publication	Cambridge
Publisher	Cambridge Open Engage
DOIs	https://doi.org/10.26434/chemrxiv.12596999.v1
Publication status	Published - 2020
Externally published	Yes

Keywords

Multimaterial
3D printing
Generative design
Cell instructive
Bacterial biofilm resistant

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10.26434/chemrxiv.12596999.v1

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He, Y., Begines, B., Trindade, G. F., Abdi, M., Dubern, J.-F., Prina, E., Hook, A. L., Choong, G., Ledesma, J., Tuck, C. J., Rose, F. R. A. J., Hague, R., Roberts, C. J., de Focatiis, D. D., Ashcroft, I. A., Williams, P., Irvine, D. J., Alexander, M. R., & Wildman, R. D. (2020). Exploiting generative design for multi-material inkjet 3D printed cell instructive, bacterial biofilm resistant composites. Cambridge Open Engage. https://doi.org/10.26434/chemrxiv.12596999.v1

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abstract = "As our understanding of disease grows, it is becoming established that treatment needs to be personalized and targeted to the needs of the individual. In this paper we show that multi-material inkjet-based 3D printing, when backed with generative design algorithms, can bring a step change in the personalization of medical devices. We take cell-instructive materials known for their resistance to bacterial biofilm formation and reformulate for multi-material inkjet-based 3D printing. Specimens with customizable mechanical moduli are obtained without loss of their cell-instructive properties. The manufacturing is coupled to a design algorithm that takes a user-specified deformation and computes the distribution of the materials needed to meet the target under given load constraints. Optimisation led to a voxel map file defining where different materials should be placed. Manufactured products were assessed against the mechanical and cell-instructive specifications and ultimately showed how multifunctional personalization emerges from generative design driven 3D printing.",

keywords = "Multimaterial, 3D printing, Generative design, Cell instructive, Bacterial biofilm resistant",

author = "Yinfeng He and Belen Begines and Trindade, {Gustavo F.} and Meisam Abdi and Jean-Fr{\'e}d{\'e}ric Dubern and Elisabetta Prina and Hook, {Andrew L.} and Gabriel Choong and Javier Ledesma and Tuck, {Christopher J.} and Rose, {Felicity R. A. J.} and Richard Hague and Roberts, {Clive J.} and {de Focatiis}, {Davide De} and Ashcroft, {Ian A.} and Paul Williams and Irvine, {Derek J.} and Alexander, {Morgan R.} and Wildman, {Ricky D.}",

year = "2020",

doi = "10.26434/chemrxiv.12596999.v1",

language = "English",

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He, Y, Begines, B, Trindade, GF, Abdi, M, Dubern, J-F, Prina, E, Hook, AL, Choong, G, Ledesma, J, Tuck, CJ, Rose, FRAJ, Hague, R, Roberts, CJ, de Focatiis, DD, Ashcroft, IA, Williams, P, Irvine, DJ, Alexander, MR & Wildman, RD 2020 'Exploiting generative design for multi-material inkjet 3D printed cell instructive, bacterial biofilm resistant composites' Cambridge Open Engage, Cambridge. https://doi.org/10.26434/chemrxiv.12596999.v1

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AU - Dubern, Jean-Frédéric

AU - Prina, Elisabetta

AU - Hook, Andrew L.

AU - Choong, Gabriel

AU - Ledesma, Javier

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AU - Hague, Richard

AU - Roberts, Clive J.

AU - de Focatiis, Davide De

AU - Ashcroft, Ian A.

AU - Williams, Paul

AU - Irvine, Derek J.

AU - Alexander, Morgan R.

AU - Wildman, Ricky D.

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KW - Bacterial biofilm resistant

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PB - Cambridge Open Engage

CY - Cambridge

ER -

Exploiting generative design for multi-material inkjet 3D printed cell instructive, bacterial biofilm resistant composites

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Keywords

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