Biofilms and mechanics: a review of experimental techniques and findings

Biofilms are developmentally-dynamic communities of sessile microbes that adhere to each other and, often, to other structures in their environment. The cohesive mechanical forces binding microbes to each other confer mechanical and structural stability on the biofilm and give rise to biofilm viscoe...

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Veröffentlicht in:	Journal of physics. D, Applied physics Applied physics, 2017-05, Vol.50 (22), p.223002
Hauptverfasser:	Gordon, Vernita D, Davis-Fields, Megan, Kovach, Kristin, Rodesney, Christopher A
Format:	Artikel
Sprache:	eng
Schlagworte:	bacteria bacterial cohesion biofilm microrheology rheology surface adhesion surface sensing
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container_title	Journal of physics. D, Applied physics
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creator	Gordon, Vernita D Davis-Fields, Megan Kovach, Kristin Rodesney, Christopher A
description	Biofilms are developmentally-dynamic communities of sessile microbes that adhere to each other and, often, to other structures in their environment. The cohesive mechanical forces binding microbes to each other confer mechanical and structural stability on the biofilm and give rise to biofilm viscoelasticity. The adhesive mechanical forces binding microbes to other structures in their environment can promote biofilm initiation and mechanosensing that leads to changes in biological activity. Thus, physical mechanics is intrinsic to characteristics that distinguish biofilms from free-swimming or free-floating microbes in liquid culture. However, very little is known about the specifics of what mechanical traits characterize different types of biofilms at different stages of development. Even less is known about how mechanical inputs impact microbial biology and how microbes can adjust their mechanical coupling to, and interaction with, their environment. These knowledge gaps arise, in part, from the challenges associated with experimental measurements of microbial and biofilm biomechanics. Here, we review extant experimental techniques and their most-salient findings to date. At the end of this review we indicate areas where significant advances in the state-of-the art are heading.
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subjects	bacteria bacterial cohesion biofilm microrheology rheology surface adhesion surface sensing
title	Biofilms and mechanics: a review of experimental techniques and findings
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