Magnetically driven formation of 3D freestanding soft bioscaffolds

Ruoxiao Xie; Yuanxiong Cao; Rujie Sun; Richard Wang; Alexis Morgan; Junyoung Kim; Sebastien J.P. Callens; Kai Xie; Jiawen Zou; Junliang Lin; Kun Zhou; Xiangrong Lu; Molly M. Stevens

doi:10.1126/sciadv.adl1549

Magnetically driven formation of 3D freestanding soft bioscaffolds

Ruoxiao Xie
, Yuanxiong Cao
, Rujie Sun
, Richard Wang
, Alexis Morgan
, Junyoung Kim
, Sebastien J.P. Callens
, Kai Xie
, Jiawen Zou
, Junliang Lin
, Kun Zhou
, Xiangrong Lu
, Molly M. Stevens (Corresponding author)

Research output: Contribution to journal › Article › Academic › peer-review

40 Citations (Scopus)

Abstract

3D soft bioscaffolds have great promise in tissue engineering, biohybrid robotics, and organ-on-a-chip engineering applications. Though emerging three-dimensional (3D) printing techniques offer versatility for assembling soft biomaterials, challenges persist in overcoming the deformation or collapse of delicate 3D structures during fabrication, especially for overhanging or thin features. This study introduces a magnet-assisted fabrication strategy that uses a magnetic field to trigger shape morphing and provide remote temporary support, enabling the straightforward creation of soft bioscaffolds with overhangs and thin-walled structures in 3D. We demonstrate the versatility and effectiveness of our strategy through the fabrication of bioscaffolds that replicate the complex 3D topology of branching vascular systems. Furthermore, we engineered hydrogel-based bioscaffolds to support biohybrid soft actuators capable of walking motion triggered by cardiomyocytes. This approach opens new possibilities for shaping hydrogel materials into complex 3D morphologies, which will further empower a broad range of biomedical applications.

Original language	English
Article number	eadl1549
Number of pages	14
Journal	Science Advances
Volume	10
Issue number	5
DOIs	https://doi.org/10.1126/sciadv.adl1549
Publication status	Published - 2 Feb 2024
Externally published	Yes

Funding

We acknowledge Y. Wang for designing and making Fig. 1. We thank n. del Piccolo for manuscript proofreading and A. nogiwa valdez for manuscript editing and data management support. R.X. and M.M.S. acknowledge funding from the engineering and Physical Sciences Research council (eP/P001114/1 and eP/t020792/1). Y.c. acknowledges the funding support from the department of Physiology, Anatomy and Genetics at the University of Oxford and china Scholarship council. R.W. acknowledges funding from the Rosetrees trust under the Young enterprise Fellowship agreement (A2741/M873) and the British heart Foundation under the centre of Research excellence agreement (Re/18/4/34215). J.K. acknowledges the support of the Korea health industry development institute (Khidi) grant (hi19c1095) and national Research Foundation (nRF) grant (2022R1A6A3A03069072) funded by the Korean Government. S.J.P.c. acknowledges funding through a Rubicon fellowship from the dutch Research council (File no. 019.211en.025) and through a UKRi Postdoctoral Fellowship (eP/ X027163/1). K.X. acknowledges funding from a UKRi Postdoctoral Fellowship (eP/X027287/1). M.M.S. is also affiliated to the Karolinska institute. Research raw data are available at dOi: 10.5281/ zenodo.10518755.

Keywords

Tissue Engineering/methods
Biocompatible Materials/chemistry
Hydrogels/chemistry
Printing, Three-Dimensional
Robotics

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title = "Magnetically driven formation of 3D freestanding soft bioscaffolds",

abstract = "3D soft bioscaffolds have great promise in tissue engineering, biohybrid robotics, and organ-on-a-chip engineering applications. Though emerging three-dimensional (3D) printing techniques offer versatility for assembling soft biomaterials, challenges persist in overcoming the deformation or collapse of delicate 3D structures during fabrication, especially for overhanging or thin features. This study introduces a magnet-assisted fabrication strategy that uses a magnetic field to trigger shape morphing and provide remote temporary support, enabling the straightforward creation of soft bioscaffolds with overhangs and thin-walled structures in 3D. We demonstrate the versatility and effectiveness of our strategy through the fabrication of bioscaffolds that replicate the complex 3D topology of branching vascular systems. Furthermore, we engineered hydrogel-based bioscaffolds to support biohybrid soft actuators capable of walking motion triggered by cardiomyocytes. This approach opens new possibilities for shaping hydrogel materials into complex 3D morphologies, which will further empower a broad range of biomedical applications.",

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AU - Callens, Sebastien J.P.

AU - Xie, Kai

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Magnetically driven formation of 3D freestanding soft bioscaffolds

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Keywords

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