Coupled CFD-DEM modeling to predict how EPS affects bacterial biofilm deformation, recovery and detachment under flow conditions
Coupled CFD-DEM modeling to predict how EPS affects bacterial biofilm deformation, recovery and detachment under flow conditions
The deformation and detachment of bacterial biofilm are related to the structural and mechanical properties of the biofilm itself. Extracellular polymeric substances (EPS) play an important role on keeping the mechanical stability of biofilms. The understanding of biofilm mechanics and detachment can help to reveal biofilm survival mechanisms under fluid shear and provide insight about what flows might be needed to remove biofilm in a cleaning cycle or for a ship to remove biofilms. However, how the EPS may affect biofilm mechanics and its deformation in flow conditions remains elusive. To address this, a coupled computational fluid dynamic– discrete element method (CFD-DEM) model was developed. The mechanisms of biofilm detachment, such as erosion and sloughing have been revealed by imposing hydrodynamic fluid flow at different velocities and loading rates. The model, which also allows adjustment of the proportion of different functional groups of microorganisms in the biofilm, enables the study of the contribution of EPS toward biofilm resistance to fluid shear stress. Furthermore, the stress–strain curves during biofilm deformation have been captured by loading and unloading fluid shear stress to study the viscoelastic properties of the biofilm. Our predicted emergent viscoelastic properties of biofilms were consistent with relevant experimental measurements.
biofilm mechanics, biofilm modeling, computational fluid dynamics, discrete element method, extracellular polymeric substances
2551-2563
Xia, Yuqing
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Gedara Jayathilake, Pahala
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Li, Bowen
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Zuliani, Paolo
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Deehan, David
ac53a37a-1e4b-474d-854e-d05ea2338e36
Longyear, Jennifer
fbc8ed1c-9fe4-45c3-bda4-7ca64551e5ce
Stoodley, Paul
08614665-92a9-4466-806e-20c6daeb483f
Chen, Jinju
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September 2022
Xia, Yuqing
38263e04-20a2-4f48-9341-cb6aeb5de008
Gedara Jayathilake, Pahala
c1da7b1b-2781-429e-b5fc-e7fc366330fa
Li, Bowen
8ab881a6-ca5b-4231-b2dd-fd3b01cbffa0
Zuliani, Paolo
92474c99-a9f7-48c4-bc1e-31595ea4c60e
Deehan, David
ac53a37a-1e4b-474d-854e-d05ea2338e36
Longyear, Jennifer
fbc8ed1c-9fe4-45c3-bda4-7ca64551e5ce
Stoodley, Paul
08614665-92a9-4466-806e-20c6daeb483f
Chen, Jinju
105a3320-0a27-49fc-83c5-9c07e89b506c
Xia, Yuqing, Gedara Jayathilake, Pahala, Li, Bowen, Zuliani, Paolo, Deehan, David, Longyear, Jennifer, Stoodley, Paul and Chen, Jinju
(2022)
Coupled CFD-DEM modeling to predict how EPS affects bacterial biofilm deformation, recovery and detachment under flow conditions.
Biotechnology and Bioengineering, 119 (9), .
(doi:10.1002/bit.28146).
Abstract
The deformation and detachment of bacterial biofilm are related to the structural and mechanical properties of the biofilm itself. Extracellular polymeric substances (EPS) play an important role on keeping the mechanical stability of biofilms. The understanding of biofilm mechanics and detachment can help to reveal biofilm survival mechanisms under fluid shear and provide insight about what flows might be needed to remove biofilm in a cleaning cycle or for a ship to remove biofilms. However, how the EPS may affect biofilm mechanics and its deformation in flow conditions remains elusive. To address this, a coupled computational fluid dynamic– discrete element method (CFD-DEM) model was developed. The mechanisms of biofilm detachment, such as erosion and sloughing have been revealed by imposing hydrodynamic fluid flow at different velocities and loading rates. The model, which also allows adjustment of the proportion of different functional groups of microorganisms in the biofilm, enables the study of the contribution of EPS toward biofilm resistance to fluid shear stress. Furthermore, the stress–strain curves during biofilm deformation have been captured by loading and unloading fluid shear stress to study the viscoelastic properties of the biofilm. Our predicted emergent viscoelastic properties of biofilms were consistent with relevant experimental measurements.
Text
PS269 Coupled CFD-DEM modelling to predict how EPS affects bacterial biofilm deformation, recovery and detachment under flow conditions
- Accepted Manuscript
Text
Biotech Bioengineering - 2022 - Xia - Coupled CFD‐DEM modeling to predict how EPS affects bacterial biofilm deformation
- Version of Record
More information
Accepted/In Press date: 14 May 2022
e-pub ahead of print date: 14 May 2022
Published date: September 2022
Additional Information:
Funding Information:
The authors acknowledge funding from the Engineering and Physical Sciences Research Council (EP/K039083/1) and BBSRC national Biofilm Innovation Centre (NBIC) (BB/R012415/1|003POC20015). Dr. Subash Bommu Chinnaraj is acknowledged for providing some experimental results in the supporting information. Prof. Tom Curtis and Dr. Saikat Jana are acknowledged for useful discussions.
Publisher Copyright:
© 2022 The Authors. Biotechnology and Bioengineering published by Wiley Periodicals LLC.
Keywords:
biofilm mechanics, biofilm modeling, computational fluid dynamics, discrete element method, extracellular polymeric substances
Identifiers
Local EPrints ID: 457718
URI: http://eprints.soton.ac.uk/id/eprint/457718
ISSN: 0006-3592
PURE UUID: e0502a2c-b1c8-445f-b258-47bc7f114904
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Date deposited: 16 Jun 2022 00:23
Last modified: 17 Mar 2024 03:18
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Contributors
Author:
Yuqing Xia
Author:
Pahala Gedara Jayathilake
Author:
Bowen Li
Author:
Paolo Zuliani
Author:
David Deehan
Author:
Jennifer Longyear
Author:
Jinju Chen
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