Secondary Flow as a Mechanism for the Formation of Biofilm Streamers

Rusconi, Roberto; Lecuyer, Sigolène; Autrusson, Nicolas; Guglielmini, Laura; Stone, Howard A.

doi:10.1016/j.bpj.2011.01.065

Cited by 112 publications

(160 citation statements)

References 41 publications

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“…γ is a measure of the biofilm cohesion estimated from the biofilm Young modulus. Reference [13] gives values in the range 70 − 140 Pa. To reduce the computational cost, we adjust it so that our biofilms involve a small number of tiles. Images in Reference [13] yield estimates for the adhesion time τ of 1 block of biomass per second.…”

Section: Numerical Resultsmentioning

confidence: 99%

Dynamics of Bacterial Aggregates in Microflows

Carpio

Einarsson

Espeso

2016

Mathematics in Industry

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Biofilms are bacterial aggregates that grow on moist surfaces. Thin homogeneous biofilms naturally formed on the walls of conducts may serve as biosensors, providing information on the status of microsystems (MEMS) without disrupting them. However, uncontrolled biofilm growth may largely disturb the environment they develop in, increasing the drag and clogging the tubes. To ensure controlled biofilm expansion we need to understand the effect of external variables on their structure. We formulate a hybrid model for the computational study of biofilms growing in laminar microflows. Biomass evolves according to stochastic rules for adhesion, erosion and motion, informed by numerical approximations of the flow fields at each stage. The model is tested studying the formation of streamers in three dimensional corner flows, gaining some insight on the effect of external variables on their structure.

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Section: Numerical Resultsmentioning

confidence: 99%

Dynamics of Bacterial Aggregates in Microflows

Carpio

Einarsson

Espeso

2016

Mathematics in Industry

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“…Non-linear streamers often form in rapid flow [89], whose visually-determined deformation fields can be fitted to those of simple elastic bodies to estimate static moduli [6,90]. More recently, microfluidic devices have been employed to provide better environmental control and ensure laminar flow [52,80,86,101], and fitting of visually-identified streamers [50] or partitioning walls [43] permits parameter estimation.…”

Section: Flow Cellsmentioning

confidence: 99%

“…1, the relationship between the deformation and growth of immersed biofilms and the shear stresses generated by the surrounding fluid flow is complex and bidirectional. Biofilm morphology influences local flow patterns and hence the fluxes of dispersed phases such as nutrients, metabolites, and quorum sensing molecules [86,87,101], and flow can drive biofilm morphogenesis to rippled beds [42,89], streamers [80,89,90,101], and rolling clusters [79]. The relevance of such process to the formation, growth, and dispersal of both infectious and non-infectious biofilms demands quantitative modelling with a predictive capability, but this situation is far from being realised.…”

Section: Fluid-structure Couplingmentioning

confidence: 99%

“…Streamers are elongated oscillating structures aligned with the flow direction that can form in turbulent conditions [89,90] or in rapid laminar flow in microfluidic devices [80,101], and can be visualised with optical or confocal microscopy and the profiles fitted to predictions for slender elastic filaments [6]. Note that fitting to elastic bodies only allows static quantities to be extracted, i.e.…”

Section: Fluid-structure Couplingmentioning

confidence: 99%

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Biomechanical Analysis of Infectious Biofilms

Head

2016

Biophysics of Infection

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The removal of infectious biofilms from tissues or implanted devices and their transmission through fluid transport systems depends in part of the mechanical properties of their polymeric matrix. Linking the various physical and chemical microscopic interactions to macroscopic deformation and failure modes promises to unveil design principles for novel therapeutic strategies targeting biofilm eradication, and provide a predictive capability to accelerate the development of devices, water lines etc. that minimise microbial dispersal. Here our current understanding of biofilm mechanics is appraised from the perspective of biophysics, with an emphasis on constitutive modelling that has been highly successful in soft matter. Fitting rheometric data to viscoelastic models has quantified linear and non-linear stress relaxation mechanisms, how they vary between species and environments, and how candidate chemical treatments alter the mechanical response. The rich interplay between growth, mechanics and hydrodynamics is just becoming amenable to computational modelling and promises to provide unprecedented characterisation of infectious biofilms in their native state.

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“…This difference in kinetics between these works could be partially attributed to the bacteria/channels size ratio differences. The mechanisms leading to streamer formation in such tortuous geometry has been discussed by Rusconi et al (2011). These authors highlighted the creation of EPS filaments and bacterial streamers between consecutive angles in the flow.…”

Section: B Role Of Tortuosity On Streamers Formationmentioning

confidence: 99%

Impact of tortuous flow on bacteria streamer development in microfluidic system during filtration

et al. 2014

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The way in which bacterial communities colonize flow in porous media is of importance, but basic knowledge on the dynamic of these phenomena is still missing. The aim of this work is to develop microfluidic experiments in order to progress in the understanding of bacteria capture in filters and membranes. PDMS microfluidic devices mimicking filtration processes have been developed to allow a direct dynamic observation of bacteria across 10 or 20 lm width microchannels. When filtered in such devices, bacteria behave surprisingly: Escherichia coli, Pseudomonas aeruginosa or Staphylococcus aureus accumulate in the downstream zone of the filter and form large streamers which oscillate in the flow. In this study, streamer formation is put in evidence for bacteria suspension in non nutritive conditions in less than 1 h. This result is totally different from the one observed in same system with "inert" particles or dead bacteria which are captured in the bottleneck zone and are accumulated in the upstream zone. Observations within different flow geometries (straight channels, connected channels, and staggered row pillars) show that the bacteria streamer development is influenced by the flow configuration and, particularly by the presence of tortuosity within the microchannels zone. These results are discussed at the light of 3D flow simulations. In confined systems and in laminar flow, there is secondary flow (z-velocities) superimposed to the streamwise motion (in xy plane). The presence of the secondary flow in the microsystems has an effect on the bacterial adhesion. A scenario in three steps is established to describe the formation of the streamers and to explain the positive effect of tortuous flow on the development kinetics. V C 2014 AIP Publishing LLC. [http://dx

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Secondary Flow as a Mechanism for the Formation of Biofilm Streamers

Cited by 112 publications

References 41 publications

Dynamics of Bacterial Aggregates in Microflows

Dynamics of Bacterial Aggregates in Microflows

Biomechanical Analysis of Infectious Biofilms

Impact of tortuous flow on bacteria streamer development in microfluidic system during filtration

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