Microrheology and Spatial Heterogeneity of Staphylococcus aureus Biofilms Modulated by Hydrodynamic Shear and Biofilm-Degrading Enzymes
journal contributionposted on 01.02.2019, 00:00 by J. W. Hart, T. A. Waigh, J. R. Lu, I. S. Roberts
Particle tracking microrheology was used to investigate the viscoelasticity of Staphylococcus aureus biofilms grown in microfluidic cells at various flow rates and when subjected to biofilm-degrading enzymes. Biofilm viscoelasticity was found to harden as a function of shear rate but soften with increasing height away from the attachment surface in good agreement with previous bulk results. Ripley’s K-function was used to quantify the spatial distribution of the bacteria within the biofilm. For all conditions, biofilms would cluster as a function of height during growth. The effects of proteinase K and DNase-1 on the viscoelasticity of biofilms were also investigated. Proteinase K caused an order of magnitude change in the compliances, softening the biofilms. However, DNase-1 was found to have no significant effects over the first 6 h of development, indicating that DNA is less important in biofilm maintenance during the initial stages of growth. Our results demonstrate that during the preliminary stages of Staphylococcus aureus biofilm development, column-like structures with a vertical gradient of viscoelasticity are established and modulated by the hydrodynamic shear caused by fluid flow in the surrounding environment. An understanding of these mechanical properties will provide more accurate insights for removal strategies of early-stage biofilms.
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Proteinase Kattachment surfacebulk resultshydrodynamic shearfluid flowBiofilm-Degrading Enzymes Particleshear ratemagnitude changebiofilm-degrading enzymesmicrofluidic cellsBiofilm viscoelasticityHydrodynamic ShearStaphylococcus aureus biofilmsfunctionDNAbiofilm maintenanceremoval strategiesflow ratescolumn-like structuresearly-stage biofilmsStaphylococcus aureus Biofilms ModulatedSpatial Heterogeneityproteinase K6 hStaphylococcus aureus biofilm development