Julia Yeomans OBE FRS

Topology and morphology of self-deforming active shells

(2019)

Authors:

Luuk Metselaar, Julia M Yeomans, Amin Doostmohammadi

Active matter invasion.

Soft matter (2019)

Authors:

Felix Kempf, Romain Mueller, Erwin Frey, Julia M Yeomans, Amin Doostmohammadi

Abstract:

Biologically active materials such as bacterial biofilms and eukaryotic cells thrive in confined micro-spaces. Here, we show through numerical simulations that confinement can serve as a mechanical guidance to achieve distinct modes of collective invasion when combined with growth dynamics and the intrinsic activity of biological materials. We assess the dynamics of the growing interface and classify these collective modes of invasion based on the activity of the constituent particles of the growing matter. While at small and moderate activities the active material grows as a coherent unit, we find that blobs of active material collectively detach from the cohort above a well-defined activity threshold. We further characterise the mechanical mechanisms underlying the crossovers between different modes of invasion and quantify their impact on the overall invasion speed.

Active Matter Invasion

(2019)

Authors:

Felix Kempf, Romain Mueller, Erwin Frey, Julia M Yeomans, Amin Doostmohammadi

Sustained Oscillations of Epithelial Cell Sheets.

Biophysical journal 117:3 (2019) 464-478

Authors:

Grégoire Peyret, Romain Mueller, Joseph d'Alessandro, Simon Begnaud, Philippe Marcq, René-Marc Mège, Julia M Yeomans, Amin Doostmohammadi, Benoît Ladoux

Abstract:

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 modeling, we describe a form of collective oscillations in confined epithelial tissues in which the oscillatory motion is the dominant contribution to the cellular movements. We show that epithelial cells exhibit large-scale coherent oscillations when constrained within micropatterns 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 osillatory mechanotransduction of YAP within cells, potentially affecting a wide range of cellular processes.

Dynamics of individual Brownian rods in a microchannel flow

Soft Matter Royal Society of Chemistry 15 (2019) 5810-5814

Authors:

Andreas Zöttl Zöttl, Kira Klop, Andrew Balin, Yongxiang Gao, Julia Yeomans, Dirk Aarts

Abstract:

We study the orientational dynamics of heavy silica microrods flowing through a microfluidic channel. Comparing experiments and Brownian dynamics simulations we identify different particle orbits, in particular in-plane tumbling behavior, which cannot be explained by classical Jeffery theory, and we relate this behavior to the rotational diffusion of the rods. By constructing the full, three-dimensional, orientation distribution, we describe the rod trajectories and quantify the persistence of Jeffery orbits using temporal correlation functions of the Jeffery constant. We find that our colloidal rods lose memory of their initial configuration in about a second, corresponding to half a Jeffery period.