Mathematical modelling reveals the balance between growth and mechanical forces underlying wrinkling bacterial films
16 April 2020
Cling Film
Bacteria grow at an ever increasing, exponential rate – their invisible spread a challenge to combat in kitchens and hospitals. In this sprawling community, or biofilm, of Vibrio cholerae bacteria a pattern develops under a microscope, influenced by the struggle for space and food. Scientists simulating biofilms with mathematical models – using equations to represent different stresses on bacterial life – managed to reproduce a strange quirk seen in real life – wrinkles. They believe these crinkly 'starburst' patterns are caused by a balance of growth and mechanical forces used as the bacteria attach to different surfaces. The team hope their models can predict weaknesses in spreading biofilms, aiding the design new materials more resistant to growth for safer transplants or tissue engineering.
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