Browsing by Author "Cargo, R."
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Item Biofilm material properties as related to shear-induced deformation and detachment phenomena(2002-12) Stoodley, Paul; Cargo, R.; Rupp, Cory J.; Wilson, Suzanne; Klapper, IsaacBiofilms of various Pseudomonas aeruginosa strains were grown in glass flow cells under laminar and turbulent flows. By relating the physical deformation of biofilms to variations in fluid shear, we found that the biofilms were viscoelastic fluids which behaved like elastic solids over periods of a few seconds but like linear viscous fluids over longer times. These data can be explained using concepts of associated polymeric systems, suggesting that the extracellular polymeric slime matrix determines the cohesive strength. Biofilms grown under high shear tended to form filamentous streamers while those grown under low shear formed an isotropic pattern of mound-shaped microcolonies. In some cases, sustained creep and necking in response to elevated shear resulted in a time-dependent fracture failure of the "tail" of the streamer from the attached upstream "head." In addition to structural differences, our data suggest that biofilms grown under higher shear were more strongly attached and were cohesively stronger than those grown under lower shears.Item Detachment and other dynamic processes in bacterial biofilms(2001) Stoodley, Paul; Wilson, Suzanne; Cargo, R.; Piscitteli, C.; Rupp, Cory J.Item Viscoelastic fluid description of bacterial biofilm material properties(2002-09) Klapper, Isaac; Rupp, Cory J.; Cargo, R.; Purevdorj, B.; Stoodley, PaulA mathematical model describing the constitutive properties of biofilms is required for predicting biofilm deformation, failure and detachment in response to mechanical forces. Laboratory observations indicate that biofilms are viscoelastic materials. Likewise, current knowledge of biofilm internal structure suggests modeling biofilms as associated polymer viscoelastic systems. Supporting experimental results and a system of viscoelastic fluid equations with a linear Jeffreys viscoelastic stress-strain law are presented here. This system of equations is based on elements of associated polymer physics and is also consistent with presented and previous experimental results. A number of predictions can be made. One particularly interesting result is the prediction of an elastic relaxation time on the order of a few minutes: biofilm disturbances on shorter time scales produce an elastic response, biofilm disturbances on longer time scales result in viscous flow, i.e., non-reversible biofilm deformation. Although not previously recognized, evidence of this phenomenon is in fact present in recent experimental results.