4.7 Article

Integer topological defects of cell monolayers: Mechanics and flows

Journal

PHYSICAL REVIEW E
Volume 103, Issue 1, Pages -

Publisher

AMER PHYSICAL SOC
DOI: 10.1103/PhysRevE.103.012405

Keywords

-

Funding

  1. Human Frontiers of Science Program [LT-000793/2018-C]
  2. SystemsX EpiPhysX consortium
  3. Swiss National Fund for Research [31003A_149975]
  4. Swiss National Science Foundation (SNF) [31003A_149975] Funding Source: Swiss National Science Foundation (SNF)

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Researchers used principles of liquid crystal physics to determine material parameters of cell monolayers and studied steady-state mechanical patterns at integer topological defects using an active polar fluid description. They demonstrated how topological defects can be utilized to fully characterize the mechanical properties of biological active matter.
Monolayers of anisotropic cells exhibit long-ranged orientational order and topological defects. During the development of organisms, orientational order often influences morphogenetic events. However, the linkage between the mechanics of cell monolayers and topological defects remains largely unexplored. This holds specifically at the timescales relevant for tissue morphogenesis. Here, we build on the physics of liquid crystals to determine material parameters of cell monolayers. In particular, we use a hydrodynamical description of an active polar fluid to study the steady-state mechanical patterns at integer topological defects. Our description includes three distinct sources of activity: traction forces accounting for cell-substrate interactions as well as anisotropic and isotropic active nematic stresses accounting for cell-cell interactions. We apply our approach to C2C12 cell monolayers in small circular confinements, which form isolated aster or spiral topological defects. By analyzing the velocity and orientational order fields in spirals as well as the forces and cell number density fields in asters, we determine mechanical parameters of C2C12 cell monolayers. Our work shows how topological defects can be used to fully characterize the mechanical properties of biological active matter.

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