A new approach to design artificial 3D microniches with combined chemical, topographical, and rheological cues
The in vitro methods to recapitulate environmental cues around cells are usually optimized to test a specific property of the environment (biochemical nature or the stiffness of the extracellular matrix (ECM), or nanotopography) for its capability to induce defined cell behaviors (lineage commitment...
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sg-ntu-dr.10356-1436112020-09-14T04:35:42Z A new approach to design artificial 3D microniches with combined chemical, topographical, and rheological cues Stoecklin, Celine Yue, Zhang Chen, Wilhelm W. de Mets, Richard Fong, Eileen Studer, Vincent Viasnoff, Virgile School of Materials Science and Engineering Engineering::Materials 3D Cell Culture Biomimetic Materials The in vitro methods to recapitulate environmental cues around cells are usually optimized to test a specific property of the environment (biochemical nature or the stiffness of the extracellular matrix (ECM), or nanotopography) for its capability to induce defined cell behaviors (lineage commitment, migration). Approaches that combine different environmental cues in 3D to assess the biological response of cells to the spatial organization of different biophysical and biochemical cues are growingly being developed. It is demonstrated how the lamination of through‐hole polymeric biofunctionalized membranes can be implemented to create complex bona fide microniches with differential 3D environmental properties using photoactive materials. The approach enables to create microniches ranging in size from single cells to cell aggregates. They are biofunctionalized in 3D simultaneously with topographical featured, protein patterns and structured ECM surrogate with 1 µm resolution. It is demonstrated how these niches extend in 3D the ability to pattern cells. It is exemplified how they can be used to standardize cells' shapes in 3D and to trigger the apicobasal polarization of single epithelial cells. 2020-09-14T04:32:35Z 2020-09-14T04:32:35Z 2018 Journal Article Stoecklin, C., Yue, Z., Chen, W. W., de Mets, R., Fong, E., Studer, V., & Viasnoff, V. (2018). A new approach to design artificial 3D microniches with combined chemical, topographical, and rheological cues. Advanced Biosystems, 2(7), 1700237-. doi:10.1002/adbi.201700237 2366-7478 https://hdl.handle.net/10356/143611 10.1002/adbi.201700237 7 2 1700237 en Advanced Biosystems © 2018 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim. All rights reserved. |
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Engineering::Materials 3D Cell Culture Biomimetic Materials Stoecklin, Celine Yue, Zhang Chen, Wilhelm W. de Mets, Richard Fong, Eileen Studer, Vincent Viasnoff, Virgile A new approach to design artificial 3D microniches with combined chemical, topographical, and rheological cues |
| description |
The in vitro methods to recapitulate environmental cues around cells are usually optimized to test a specific property of the environment (biochemical nature or the stiffness of the extracellular matrix (ECM), or nanotopography) for its capability to induce defined cell behaviors (lineage commitment, migration). Approaches that combine different environmental cues in 3D to assess the biological response of cells to the spatial organization of different biophysical and biochemical cues are growingly being developed. It is demonstrated how the lamination of through‐hole polymeric biofunctionalized membranes can be implemented to create complex bona fide microniches with differential 3D environmental properties using photoactive materials. The approach enables to create microniches ranging in size from single cells to cell aggregates. They are biofunctionalized in 3D simultaneously with topographical featured, protein patterns and structured ECM surrogate with 1 µm resolution. It is demonstrated how these niches extend in 3D the ability to pattern cells. It is exemplified how they can be used to standardize cells' shapes in 3D and to trigger the apicobasal polarization of single epithelial cells. |
| author2 |
School of Materials Science and Engineering |
| author_facet |
School of Materials Science and Engineering Stoecklin, Celine Yue, Zhang Chen, Wilhelm W. de Mets, Richard Fong, Eileen Studer, Vincent Viasnoff, Virgile |
| format |
Article |
| author |
Stoecklin, Celine Yue, Zhang Chen, Wilhelm W. de Mets, Richard Fong, Eileen Studer, Vincent Viasnoff, Virgile |
| author_sort |
Stoecklin, Celine |
| title |
A new approach to design artificial 3D microniches with combined chemical, topographical, and rheological cues |
| title_short |
A new approach to design artificial 3D microniches with combined chemical, topographical, and rheological cues |
| title_full |
A new approach to design artificial 3D microniches with combined chemical, topographical, and rheological cues |
| title_fullStr |
A new approach to design artificial 3D microniches with combined chemical, topographical, and rheological cues |
| title_full_unstemmed |
A new approach to design artificial 3D microniches with combined chemical, topographical, and rheological cues |
| title_sort |
new approach to design artificial 3d microniches with combined chemical, topographical, and rheological cues |
| publishDate |
2020 |
| url |
https://hdl.handle.net/10356/143611 |
| _version_ |
1681056277406416896 |