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Measuring fluid shear

Measuring fluid shear
Measuring fluid shear
Very little is known about the material properties of dental biofilms. Unlike conventional materials like plastics, which can be molded into uniform test pieces, biofilms are nonuniform, microscopically small, and attached to surfaces. Removal from the surface will inevitably disrupt the sample, and it is difficult to reproduce in the lab the varying and complex physical forces existing in the mouth, so testing remains a challenge.

In our laboratory at the Center for Biofilm Engineering at Montana State University, we have developed methods for testing the material properties of biofilms using fluid shear as the deforming force. By measuring the deformation to biofilms caused by long- and short-term exposure to elevated fluid shear, we found that various pure and mixed-species aerobic and anaerobic biofilms grown in glass flow cells were in fact viscous fluids that behaved elastically over short loading time periods (seconds or less), but could flow like viscous fluids when the load was sustained. Also, biofilms grown at higher shear were more firmly attached and cohesively stronger than those grown at lower shear.

This has a number of implications. Because the mouth has an incredibly wide range of shear and normal stresses, we might expect that the biofilms will also exhibit a wide range of cohesive and adhesive strengths depending on the local growth environment in the mouth. The material properties of dental plaque will also likely change with time. As calcification occurs, the plaque will be expected to become more rigid and solid-like and behave less like a fluid. In this case, instead of flowing it may fracture in response to an applied physical force. Also, because biofilms can flow, albeit slowly, it is likely that the action of chewing or movement of the tongue may actually smear biofilm from one place to another. By looking at biofilms from a materials standpoint and refining our methods, we can begin to design new technologies to address their control.
1048-0943
p.25
Stoodley, P.
08614665-92a9-4466-806e-20c6daeb483f
Howard, Ken
d611a6df-3e09-42f3-ab79-f24d0a3a5b4f
Stoodley, P.
08614665-92a9-4466-806e-20c6daeb483f
Howard, Ken
d611a6df-3e09-42f3-ab79-f24d0a3a5b4f

Stoodley, P. , Howard, Ken (ed.) (2002) Measuring fluid shear. [in special issue: Emerging Trends in Oral Care. The Biofilm Revolution] Scientific American, supplement Emerging Trends in Oral Care. The Biofilm Revolution, p.25.

Record type: Article

Abstract

Very little is known about the material properties of dental biofilms. Unlike conventional materials like plastics, which can be molded into uniform test pieces, biofilms are nonuniform, microscopically small, and attached to surfaces. Removal from the surface will inevitably disrupt the sample, and it is difficult to reproduce in the lab the varying and complex physical forces existing in the mouth, so testing remains a challenge.

In our laboratory at the Center for Biofilm Engineering at Montana State University, we have developed methods for testing the material properties of biofilms using fluid shear as the deforming force. By measuring the deformation to biofilms caused by long- and short-term exposure to elevated fluid shear, we found that various pure and mixed-species aerobic and anaerobic biofilms grown in glass flow cells were in fact viscous fluids that behaved elastically over short loading time periods (seconds or less), but could flow like viscous fluids when the load was sustained. Also, biofilms grown at higher shear were more firmly attached and cohesively stronger than those grown at lower shear.

This has a number of implications. Because the mouth has an incredibly wide range of shear and normal stresses, we might expect that the biofilms will also exhibit a wide range of cohesive and adhesive strengths depending on the local growth environment in the mouth. The material properties of dental plaque will also likely change with time. As calcification occurs, the plaque will be expected to become more rigid and solid-like and behave less like a fluid. In this case, instead of flowing it may fracture in response to an applied physical force. Also, because biofilms can flow, albeit slowly, it is likely that the action of chewing or movement of the tongue may actually smear biofilm from one place to another. By looking at biofilms from a materials standpoint and refining our methods, we can begin to design new technologies to address their control.

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Published date: 2002
Organisations: Engineering Mats & Surface Engineerg Gp

Identifiers

Local EPrints ID: 158305
URI: http://eprints.soton.ac.uk/id/eprint/158305
ISSN: 1048-0943
PURE UUID: e43cd17b-6bbf-4d3b-bf1b-f7edeb750d07
ORCID for P. Stoodley: ORCID iD orcid.org/0000-0001-6069-273X

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Date deposited: 29 Jun 2010 09:10
Last modified: 14 Mar 2024 02:55

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Contributors

Author: P. Stoodley ORCID iD
Editor: Ken Howard

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