Independent control over cell patterning and adhesion on hydrogel substrates for tissue interface mechanobiology

Tissue boundaries and interfaces are engines of morphogenesis in vivo. However, despite a wealth of micropatterning approaches available to control tissue size, shape, and mechanical environment in vitro, fine-scale spatial control of cell positioning within tissue constructs remains an engineering...

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Bibliographic Details
Published in:iScience 2023-05, Vol.26 (5), p.106657-106657, Article 106657
Main Authors: Prahl, Louis S., Porter, Catherine M., Liu, Jiageng, Viola, John M., Hughes, Alex J.
Format: Article
Language:English
Subjects:
Bioengineering
Cell biology
Tissue engineering
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Summary:Tissue boundaries and interfaces are engines of morphogenesis in vivo. However, despite a wealth of micropatterning approaches available to control tissue size, shape, and mechanical environment in vitro, fine-scale spatial control of cell positioning within tissue constructs remains an engineering challenge. To address this, we augment DNA “velcro” technology for selective patterning of ssDNA-labeled cells on mechanically defined photoactive polyacrylamide hydrogels. Hydrogels bearing photopatterned single-stranded DNA (ssDNA) features for cell capture are then co-functionalized with extracellular matrix (ECM) proteins to support subsequent adhesion of patterned tissues. ECM protein co-functionalization does not alter ssDNA pattern fidelity, cell capture, or hydrogel elastic stiffness. This approach enables mechanobiology studies and measurements of signaling activity at dynamic cell interfaces with precise initial patterning. Combining DNA velcro patterning and ECM functionalization provides independent control of initial cell placement, adhesion, and mechanics, constituting a new tool for studying biological interfaces and for programming multicellular interactions in engineered tissues. [Display omitted] •DNA“velcro”enables precise cell patterning on photoactive BP-PA hydrogels•BP-PA hydrogels support stiffness tuning and ECM functionalization•Multiplexed DNA“velcro” supports long-term adhesion of patterned interfaces•Epithelial ERK signaling depends on tissue interface geometry Bioengineering; Tissue engineering; Cell biology
ISSN:2589-0042
2589-0042
DOI:10.1016/j.isci.2023.106657