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

Marty, A.; Causserand, Christel; Roques, Christine; Bacchin, Patrice

doi:10.1063/1.4863724

Cited by 17 publications

(17 citation statements)

References 30 publications

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“…Bacterial streamers have been observed to form both in high 12 13 , and in low Reynolds number conditions 10 11 14 15 16 . Streamer formation in low Re transport is of significant technological and biomedical interest due to relevance to a wide variety of critical operating scenarios including clogging of biomedical devices such as heart stents, catheters, porous media and water filtration systems 8 11 17 . Rusconi et al 10 , while studying the effect of curved channel geometries using a microfluidic device, found that Pseudomonas aeruginosa formed streamers in the curved sections of the microchannels.…”

mentioning

confidence: 99%

Bacterial floc mediated rapid streamer formation in creeping flows

Hassanpourfard

Nikakhtari

Ghosh

et al. 2015

Sci Rep

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One of the central puzzles concerning the interaction of low Reynolds number fluid transport with bacterial biomass is the formation of filamentous structures called streamers. In this manuscript, we report our discovery of a new kind of low Re bacterial streamers, which appear from pre-formed bacterial flocs. In sharp contrast to the biofilm-mediated streamers, these streamers form over extremely small timescales (less than a second). Our experiments, carried out in a microchannel with micropillars rely on fluorescence microscopy techniques to illustrate that floc-mediated streamers form when a freely-moving floc adheres to the micropillar wall and gets rapidly sheared by the background flow. We also show that at their inception the deformation of the flocs is dominated by recoverable large strains indicating significant elasticity. These strains subsequently increase tremendously to produce filamentous streamers. Interestingly, we find that these fully formed streamers are not static structures and show viscous response at time scales larger than their formation time scales. Finally, we show that such novel streamer formation can lead to rapid clogging of microfluidic devices.

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mentioning

confidence: 99%

Bacterial floc mediated rapid streamer formation in creeping flows

Hassanpourfard

Nikakhtari

Ghosh

et al. 2015

Sci Rep

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“…They studied the effect of different pore sizes and dead-end and pseudo cross-flow filtration modes on the biofouling during filtration. In subsequent work, they also reported that pore tortuosity and secondary flows have a significant impact on biofouling formation in the mimic system [33].…”

Section: Microfluidic Membrane Mimicmentioning

confidence: 90%

“…Streamers in a microfluidic system are typically tethered at one end to the pillar walls while the rest of the body is suspended in the downstream direction. Their filamentous structure can extend significantly with the flow [6,33,34].…”

Section: Bacterial Streamer Due To Biofoulingmentioning

confidence: 99%

“…Marty et al [33,34] studied the effect of different pore sizes and filtration modes on the lengths of streamers that formed in a microfluidic membrane mimic system. They fabricated a microfluidic device with 25 straight, interconnected and staggered PDMS pillars to observe the nature of biofouling in a membrane mimic.…”

Section: Bacterial Streamer Due To Biofoulingmentioning

confidence: 99%

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Microfluidic Membrane Filtration Systems to Study Biofouling

Biswas¹,

Kumar²,

Sadrzadeh³

2018

Microfluidics and Nanofluidics

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In wastewater treatment, the membrane functions as a semipermeable barrier that restricts transport of undesired particulates. A major problem related to membrane filtration processes is fouling of membranes by colloidal particles, organic matter, and biomaterials. Among the various types of fouling, biofouling is one of the most severe, as it is a dynamic process. Even a few surviving cells that adhere to the membrane surface multiply exponentially at the expense of biodegradable substances in the feed solution. To analyze the mechanism of biofouling, membrane cell is typically considered as a black-box, where only the input and the output can be measured and put into use for analysis. Microfluidic devices are being used to study and understand the nature, properties, and evolution of biofouling. A primary advantage of a microfluidic membrane is the ability to conduct realtime observations of biofilm. This chapter presents an overview of the biofouling in membrane processes and different fabrication technique of microfluidic membrane systems.

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“…The streamers were spatially localized to the middle plane of the curved channel and connected only at the inner curve during each turn, where a secondary vortical flow was observed. The effect of secondary flow on biofilm formation was evaluated by Marty et al (2014) . They discussed the role of secondary flow in streamer formation in three steps.…”

Section: Biofilm Formationmentioning

confidence: 99%

Bacterial biomechanics—From individual behaviors to biofilm and the gut flora

Ishikawa

Omori

2020

APL Bioengineering

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Bacteria inhabit a variety of locations and play important roles in the environment and health. Our understanding of bacterial biomechanics has improved markedly in the last decade and has revealed that biomechanics play a significant role in microbial biology. The obtained knowledge has enabled investigation of complex phenomena, such as biofilm formation and the dynamics of the gut flora. A bottom-up strategy, i.e., from the cellular to the macroscale, facilitates understanding of macroscopic bacterial phenomena. In this Review, we first cover the biomechanics of individual bacteria in the bulk liquid and on surfaces as the base of complex phenomena. The collective behaviors of bacteria in simple environments are next introduced. We then introduce recent advances in biofilm biomechanics, in which adhesion force and the flow environment play crucial roles. We also review transport phenomena in the intestine and the dynamics of the gut flora, focusing on that in zebrafish. Finally, we provide an overview of the future prospects for the field.

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

Cited by 17 publications

References 30 publications

Bacterial floc mediated rapid streamer formation in creeping flows

Bacterial floc mediated rapid streamer formation in creeping flows

Microfluidic Membrane Filtration Systems to Study Biofouling

Bacterial biomechanics—From individual behaviors to biofilm and the gut flora

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