Julia M. Yeomans scite author profile

Coupling between flows and material properties imbues rheological matter with its wide-ranging applicability, hence the excitement for harnessing the rheology of active fluids for which internal structure and continuous energy injection lead to spontaneous flows and complex, out-of-equilibrium dynamics. We propose and demonstrate a convenient, highly tunable method for controlling flow, topology, and composition within active films. Our approach establishes rheological coupling via the indirect presence of fully submersed micropatterned structures within a thin, underlying oil layer. Simulations reveal that micropatterned structures produce effective virtual boundaries within the superjacent active nematic film due to differences in viscous dissipation as a function of depth. This accessible method of applying position-dependent, effective dissipation to the active films presents a nonintrusive pathway for engineering active microfluidic systems.

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Sustained oscillations of epithelial cell sheets

Peyret

Mueller

D’Alessandro

et al. 2018

Preprint

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Morphological changes during development, tissue repair, and disease largely rely on coordinated cell movements and are controlled by the tissue environment. Epithelial cell sheets are often subjected to large scale deformation during tissue formation. The active mechanical environment in which epithelial cells operate have the ability to promote collective oscillations, but how these cellular movements are generated and relate to collective migration remains unclear. Here, combining in vitro experiments and computational modelling we describe a novel mode of collective oscillations in confined epithelial tissues where the oscillatory motion is the dominant contribution to the cellular movements. We show that epithelial cells exhibit large-scale coherent oscillations when constrained within micro-patterns of varying shapes and sizes, and that their period and amplitude are set by the smallest confinement dimension. Using molecular perturbations, we then demonstrate that force transmission at cell-cell junctions and its coupling to cell polarity are pivotal for the generation of these collective movements. We find that the resulting tissue deformations are sufficient to trigger mechanotransduction within cells, potentially affecting a wide range of cellular processes.The formation of multicellular patterns of moving cells in living tissues is a hallmark of many developmental and pathological processes including morphogenesis, tissue regeneration, and tumourigenesis 1,2,3 . The ability of the cells to coordinate their motion over large scales 2,4 enables the rapid transmission of mechanical information across the tissue, for example during tissue invagination driven by acto-myosin contractions 5 , gastrulation 6 , the propagation of velocity waves far from the free edge of migrating monolayers 7,8 or the transmission of contact-guidance signals away from localised topographical cues 9 . It is * These authors contributed equally to this work

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A New Theory of Polytypism

Smith

Yeomans

Heine

1984

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Phase Ordering in Fluids

Yeomans¹

2000

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Julia M. Yeomans

Statistical Mechanics of Phase Transitions

Submersed micropatterned structures control active nematic flow, topology, and concentration

Sustained oscillations of epithelial cell sheets

A New Theory of Polytypism

Phase Ordering in Fluids

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