Author
Listed:
- Wontae Lee
(McGill University)
- Nikita Kalashnikov
(McGill University)
- Stephanie Mok
(McGill University)
- Ruba Halaoui
(McGill University
McGill University)
- Elena Kuzmin
(McGill University
McGill University)
- Andrew J. Putnam
(University of Michigan)
- Shuichi Takayama
(University of Michigan
Georgia Institute of Technology and Emory University)
- Morag Park
(McGill University
McGill University)
- Luke McCaffrey
(McGill University
McGill University)
- Ruogang Zhao
(State University of New York at Buffalo)
- Richard L. Leask
(McGill University
Montreal Heart Institute
McGill University)
- Christopher Moraes
(McGill University
McGill University
McGill University)
Abstract
Understanding how forces orchestrate tissue formation requires technologies to map internal tissue stress at cellular length scales. Here, we develop ultrasoft mechanosensors that visibly deform under less than 10 Pascals of cell-generated stress. By incorporating these mechanosensors into multicellular spheroids, we capture the patterns of internal stress that arise during spheroid formation. We experimentally demonstrate the spontaneous generation of a tensional ‘skin’, only a few cell layers thick, at the spheroid surface, which correlates with activation of mechanobiological signalling pathways, and balances a compressive stress profile within the tissue. These stresses develop through cell-driven mechanical compaction at the tissue periphery, and suggest that the tissue formation process plays a critically important role in specifying mechanobiological function. The broad applicability of this technique should ultimately provide a quantitative basis to design tissues that leverage the mechanical activity of constituent cells to evolve towards a desired form and function.
Suggested Citation
Wontae Lee & Nikita Kalashnikov & Stephanie Mok & Ruba Halaoui & Elena Kuzmin & Andrew J. Putnam & Shuichi Takayama & Morag Park & Luke McCaffrey & Ruogang Zhao & Richard L. Leask & Christopher Moraes, 2019.
"Dispersible hydrogel force sensors reveal patterns of solid mechanical stress in multicellular spheroid cultures,"
Nature Communications, Nature, vol. 10(1), pages 1-14, December.
Handle:
RePEc:nat:natcom:v:10:y:2019:i:1:d:10.1038_s41467-018-07967-4
DOI: 10.1038/s41467-018-07967-4
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