Viscoelasticity of biofilms and their recalcitrance to mechanical and chemical challenges
Viscoelasticity of biofilms and their recalcitrance to mechanical and chemical challenges
We summarize different studies describing mechanisms through which bacteria in a biofilm mode of growth resist mechanical and chemical challenges. Acknowledging previous microscopic work describing voids and channels in biofilms that govern a biofilms response to such challenges, we advocate a more quantitative approach that builds on the relation between structure and composition of materials with their viscoelastic properties. Biofilms possess features of both viscoelastic solids and liquids, like skin or blood, and stress relaxation of biofilms has been found to be a corollary of their structure and composition, including the EPS matrix and bacterial interactions. Review of the literature on viscoelastic properties of biofilms in ancient and modern environments as well as of infectious biofilms reveals that the viscoelastic properties of a biofilm relate with antimicrobial penetration in a biofilm. In addition, also the removal of biofilm from surfaces appears governed by the viscoelasticity of a biofilm. Herewith, it is established that the viscoelasticity of biofilms, as a corollary of structure and composition, performs a role in their protection against mechanical and chemical challenges. Pathways are discussed to make biofilms more susceptible to antimicrobials by intervening with their viscoelasticity, as a quantifiable expression of their structure and composition.
biofilm, structure, extracellular polymeric substances (EPS), antimicrobial penetration, detachment, viscoelasticity
Peterson, B.W.
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He, Y.
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Ren, Y.
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Zerdoum, A.
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Libera, M.R.
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Sharma, P.K.
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van Winkelhoff, A.-J.
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Neut, D.
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Stoodley, P.
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van der Mei, H.C.
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Busscher, H.J.
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Peterson, B.W.
b83adf33-c845-442a-a994-b74273c04616
He, Y.
ccaae702-0497-4be1-80be-095d248f5907
Ren, Y.
99503ea8-fd70-4fa1-af9a-de8b8104f947
Zerdoum, A.
4cc1401d-dd07-4e4e-a176-8b97262d7018
Libera, M.R.
93b34a5e-ce27-40fd-9591-515ae4a78631
Sharma, P.K.
799634bd-87dd-4eeb-8434-8268bd7effc2
van Winkelhoff, A.-J.
67af6820-3a24-46cd-b596-d7c7397a1c7d
Neut, D.
9111cba2-2836-4776-b7ca-8ea983602b9a
Stoodley, P.
08614665-92a9-4466-806e-20c6daeb483f
van der Mei, H.C.
85699252-69cc-42fe-a6de-c5ea0397db0b
Busscher, H.J.
587f0c85-e2d3-4d1d-8ca0-9de711276a55
Peterson, B.W., He, Y., Ren, Y., Zerdoum, A., Libera, M.R., Sharma, P.K., van Winkelhoff, A.-J., Neut, D., Stoodley, P., van der Mei, H.C. and Busscher, H.J.
(2015)
Viscoelasticity of biofilms and their recalcitrance to mechanical and chemical challenges.
FEMS Microbiology Reviews.
(doi:10.1093/femsre/fuu008).
Abstract
We summarize different studies describing mechanisms through which bacteria in a biofilm mode of growth resist mechanical and chemical challenges. Acknowledging previous microscopic work describing voids and channels in biofilms that govern a biofilms response to such challenges, we advocate a more quantitative approach that builds on the relation between structure and composition of materials with their viscoelastic properties. Biofilms possess features of both viscoelastic solids and liquids, like skin or blood, and stress relaxation of biofilms has been found to be a corollary of their structure and composition, including the EPS matrix and bacterial interactions. Review of the literature on viscoelastic properties of biofilms in ancient and modern environments as well as of infectious biofilms reveals that the viscoelastic properties of a biofilm relate with antimicrobial penetration in a biofilm. In addition, also the removal of biofilm from surfaces appears governed by the viscoelasticity of a biofilm. Herewith, it is established that the viscoelasticity of biofilms, as a corollary of structure and composition, performs a role in their protection against mechanical and chemical challenges. Pathways are discussed to make biofilms more susceptible to antimicrobials by intervening with their viscoelasticity, as a quantifiable expression of their structure and composition.
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e-pub ahead of print date: 3 February 2015
Keywords:
biofilm, structure, extracellular polymeric substances (EPS), antimicrobial penetration, detachment, viscoelasticity
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nCATS Group
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Local EPrints ID: 374209
URI: http://eprints.soton.ac.uk/id/eprint/374209
ISSN: 0168-6445
PURE UUID: 1ac12da5-abf5-4740-b9a0-04df2bed5646
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Date deposited: 10 Feb 2015 10:59
Last modified: 15 Mar 2024 03:34
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Contributors
Author:
B.W. Peterson
Author:
Y. He
Author:
Y. Ren
Author:
A. Zerdoum
Author:
M.R. Libera
Author:
P.K. Sharma
Author:
A.-J. van Winkelhoff
Author:
D. Neut
Author:
H.C. van der Mei
Author:
H.J. Busscher
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