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Real-time characterization of the mechanical behaviour of an actively growing bacterial culture by rheology

The population growth of a Staphylococcus aureus culture was followed by rheological measurements, under steady-state and dynamic shear flows. We observed a rich viscoelastic behaviour as a consequence of the bacteria activity. First, the viscosity increased ~10 times due to cell multiplication and aggregation. This viscosity increase presented several drops and full recoveries, which are reproducible, allowing us to evoke the existence of a percolation phenomenon. Eventually, as the bacteria population reached a final stage of development, fulfilling the sample volume, the viscosity returned to its initial value, most probably caused by a change in the bacteria physiological activity, in particular the decrease of their adhesion properties. Finally, the viscous and the elastic moduli presented power law behaviours compatible with the "soft glassy materials" model, which exponents are dependent on the bacteria growth stage.

preprint2012arXivOpen access
R. PortelaP. L. AlmeidaP. PatricioT. CidadeR. G. SobralC. R. Leal
Biological Physicscond-mat.soft
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R. PortelaP. L. AlmeidaP. PatricioT. CidadeR. G. SobralC. R. Leal

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