Engineering subcellular-patterned biointerfaces to regulate the surface wetting of multicellular spheroids
Studying the wetting behaviors of multicellular spheroids is crucial in the fields of embryo implantation, cancer propagation, and tissue repair. Existing strategies for controlling the wetting of multicellular spheroids mainly focus on surface chemistry and substrate rigidity. Although topography i...
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sg-ntu-dr.10356-1378132023-07-14T15:54:58Z Engineering subcellular-patterned biointerfaces to regulate the surface wetting of multicellular spheroids Wang, Luying Cai, Pingqiang Luo, Jing Zhang, Feilong Liu, Jian Chen, Yupeng Zhu, Zhongpeng Song, Yongyang Yang, Bingquan Liu, Xi Chen, Xiaodong Wang, Shutao School of Materials Science & Engineering Engineering::Materials Topography Wetting Studying the wetting behaviors of multicellular spheroids is crucial in the fields of embryo implantation, cancer propagation, and tissue repair. Existing strategies for controlling the wetting of multicellular spheroids mainly focus on surface chemistry and substrate rigidity. Although topography is another important feature in the biological micro-environment, its effect on multicellular spheroid wetting has seldom been explored. In this study, the influence of topography on the surface wetting of multicellular spheroids was investigated using subcellularpatterned opal films with controllable colloidal particle diameters (from 200 to 1,500 nm). The wetting of hepatoma carcinoma cellular (Hep G2) spheroids was impaired on opal films compared with that on flat substrates, and the wetting rate decreased as colloidal particle diameter increased. The decrement reached 48.5% when the colloidal particle diameter was 1,500 nm. The subcellular-patterned topography in opal films drastically reduced the cellular mobility in precursor films, especially the frontier cells in the leading edge. The frontier cells failed to form mature focal adhesions and stress fibers on micro-patterned opal films. This was due to gaps between colloidal particles leaving adhesion vacancies, causing weak cell–substrate adhesion and consequent retarded migration of Hep G2 spheroids. Our study manifests the inhibiting effects of subcellular-patterned topography on the wetting behaviors of multicellular spheroids, providing new insight into tissue wetting-associated treatments and biomaterial design. Accepted version 2020-04-15T04:47:07Z 2020-04-15T04:47:07Z 2018 Journal Article Wang, L., Cai, P., Luo, J., Zhang, F., Liu, J., Chen, Y., . . ., Wang, S. (2018). Engineering subcellular-patterned biointerfaces to regulate the surface wetting of multicellular spheroids. Nano Research, 11(10), 5704–5715. doi:10.1007/s12274-018-2117-6 1998-0124 https://hdl.handle.net/10356/137813 10.1007/s12274-018-2117-6 2-s2.0-85048834182 10 11 5704 5715 en Nano Research © 2018 Tsinghua University Press and Springer-Verlag GmbH Germany, part of Springer Nature. All rights reserved. This paper was published in Nano Research and is made available with permission of Tsinghua University Press and Springer-Verlag GmbH Germany, part of Springer Nature. application/pdf |
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Engineering::Materials Topography Wetting Wang, Luying Cai, Pingqiang Luo, Jing Zhang, Feilong Liu, Jian Chen, Yupeng Zhu, Zhongpeng Song, Yongyang Yang, Bingquan Liu, Xi Chen, Xiaodong Wang, Shutao Engineering subcellular-patterned biointerfaces to regulate the surface wetting of multicellular spheroids |
| description |
Studying the wetting behaviors of multicellular spheroids is crucial in the fields of embryo implantation, cancer propagation, and tissue repair. Existing strategies for controlling the wetting of multicellular spheroids mainly focus on surface chemistry and substrate rigidity. Although topography is another important feature in the biological micro-environment, its effect on multicellular spheroid wetting has seldom been explored. In this study, the influence of topography on the surface wetting of multicellular spheroids was investigated using subcellularpatterned opal films with controllable colloidal particle diameters (from 200 to 1,500 nm). The wetting of hepatoma carcinoma cellular (Hep G2) spheroids was impaired on opal films compared with that on flat substrates, and the wetting rate decreased as colloidal particle diameter increased. The decrement reached 48.5% when the colloidal particle diameter was 1,500 nm. The subcellular-patterned topography in opal films drastically reduced the cellular mobility in precursor films, especially the frontier cells in the leading edge. The frontier cells failed to form mature focal adhesions and stress fibers on micro-patterned opal films. This was due to gaps between colloidal particles leaving adhesion vacancies, causing weak cell–substrate adhesion and consequent retarded migration of Hep G2 spheroids. Our study manifests the inhibiting effects of subcellular-patterned topography on the wetting behaviors of multicellular spheroids, providing new insight into tissue wetting-associated treatments and biomaterial design. |
| author2 |
School of Materials Science & Engineering |
| author_facet |
School of Materials Science & Engineering Wang, Luying Cai, Pingqiang Luo, Jing Zhang, Feilong Liu, Jian Chen, Yupeng Zhu, Zhongpeng Song, Yongyang Yang, Bingquan Liu, Xi Chen, Xiaodong Wang, Shutao |
| format |
Article |
| author |
Wang, Luying Cai, Pingqiang Luo, Jing Zhang, Feilong Liu, Jian Chen, Yupeng Zhu, Zhongpeng Song, Yongyang Yang, Bingquan Liu, Xi Chen, Xiaodong Wang, Shutao |
| author_sort |
Wang, Luying |
| title |
Engineering subcellular-patterned biointerfaces to regulate the surface wetting of multicellular spheroids |
| title_short |
Engineering subcellular-patterned biointerfaces to regulate the surface wetting of multicellular spheroids |
| title_full |
Engineering subcellular-patterned biointerfaces to regulate the surface wetting of multicellular spheroids |
| title_fullStr |
Engineering subcellular-patterned biointerfaces to regulate the surface wetting of multicellular spheroids |
| title_full_unstemmed |
Engineering subcellular-patterned biointerfaces to regulate the surface wetting of multicellular spheroids |
| title_sort |
engineering subcellular-patterned biointerfaces to regulate the surface wetting of multicellular spheroids |
| publishDate |
2020 |
| url |
https://hdl.handle.net/10356/137813 |
| _version_ |
1772825976601837568 |