Computational pore network modeling of the influence of biofilm permeability on bioclogging in porous media

Thullner, Martin; Baveye, Philippe C.

doi:10.1002/bit.21708

Cited by 100 publications

(127 citation statements)

References 33 publications

(37 reference statements)

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“…Quantifying biomass effluent from complex biofilms grown in a glass-bead reactor in terms of a spatially-averaged model has revealed design principles that could be exploited to control growth and detachment [18]. Spatially-extended models reveal a complex biomass distribution on the scale of reactor pores, with reduced nutrient availability and biofilm growth downstream from clogged pores [52,93]. A suite of techniques has been employed to measure velocity profiles and metabolic fluxes in terms of biofilm age and microbial composition [47], generating a range of data that could be used to validate highly sophisticated and predictive models.…”

Section: Mechanically-induced Detachmentmentioning

confidence: 99%

“…In addition, the response to surface airflow and known airborne dispersal modes should be considered in the design of nosocomial ventilation systems [38,83]. Flow is also a key consideration for industrial biofilms as overgrowth can cause clogging in biofilm reactors [52,93], although here the goal is to maximise metabolic efficacy rather than microbial eradication.…”

Section: Introductionmentioning

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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Section: Mechanically-induced Detachmentmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Biomechanical Analysis of Infectious Biofilms

Head

2016

Biophysics of Infection

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“…In most PNM of biofilm, usually pores are assumed to have circular cross sections (e.g., Kim and Fogler 2000;Thullner and Baveye 2008). In this subsection, results for the dependencies of the dimensionless mass exchange coefficient ξ * in a pore domain with circular cross section are presented.…”

Section: Mass Exchange Coefficient For the Case Of Circular Cross Secmentioning

confidence: 99%

“…It not only sheds light on physical fundamentals of flow and transport at the pore scale, but also can provide constitutive relationships which appear in upscaled macroscale transport equations, like effective dispersive tensor, effective reaction rate, and relationship between permeability and biofilm volume fraction (Ezeuko et al 2011;Graf von der Schulenburg et al 2009;Hesse et al 2009;Kim and Fogler 2000;Li et al 2006;Stewart and Kim 2004;Suchomel et al 1998a, b;Thullner et al 2002;Thullner and Baveye 2008). Graf von der developed a Lattice-Boltzmann (LB) model to study the coupled interactions between nutrient transport, biofilm growth, and hydrodynamics.…”

Section: Introductionmentioning

confidence: 99%

“…Biofilm growth was assumed to occur uniformly around the pore walls. Inside a cylindrical pore, either local mass equilibrium (Ezeuko et al 2011) or a first-order kinetic model with a constant mass exchange coefficient was used (e.g., Thullner and Baveye 2008). But, it is worth noting that even in the tubes of a pore network we still need to distinguish non-equilibrium from equilibrium conditions.…”

Section: Introductionmentioning

confidence: 99%

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Solute Mass Exchange Between Water Phase and Biofilm for a Single Pore

Qin

Hassanizadeh

2015

Transp Porous Med

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Currently, there are no tractable approaches available for modeling nonequilibrium mass exchange of a solute between water phase and biofilm in porous media. The present work contributes to a quantitative description of the mass exchange of a solute over a single pore domain under a wide range of prevailing conditions. First, we developed a semiempirical model for the rate of solute mass exchange between water phase and biofilm. Then, extensive microscale simulations in a single pore were conducted. Results were averaged over a single pore domain, in order to determine a tube-scale kinetic rate coefficient as a function of various transport and biofilm properties. We illustrated the dependencies of the coefficient on a number of variables like Péclet number, Damköhler number, and biofilm volume fraction. Based on those results, we developed empirical formulae for the tube-scale mass exchange coefficient as a function of Damköhler number and biofilm volume fraction. Finally, we verified the proposed mass exchange rate against microscale simulations of solute transport in a long capillary tube. Good match was obtained over a wide range of conditions. Keywords Porous media with biofilm · Non-equilibrium condition · Pore-scale modeling · Mass exchange coefficient · Solute transport List of symbols Latin symbols

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Modeling biofilm dynamics and hydraulic properties in variably saturated soils using a channel network model

Rosenzweig

Furman

Dosoretz

et al. 2014

Water Resources Research

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Biofilm effects on water flow in unsaturated environments have largely been ignored in the past. However, intensive engineered systems that involve elevated organic loads such as wastewater irrigation, effluent recharge, and bioremediation processes make understanding how biofilms affect flow highly important. In the current work, we present a channel-network model that incorporates water flow, substrate transport, and biofilm dynamics to simulate the alteration of soil hydraulic properties, namely water retention and conductivity. The change in hydraulic properties due to biofilm growth is not trivial and depends highly on the spatial distribution of the biofilm development. Our results indicate that the substrate mass transfer coefficient across the water-biofilm interface dominates the spatiotemporal distribution of biofilm. High mass transfer coefficients lead to uncontrolled biofilm growth close to the substrate source, resulting in preferential clogging of the soil. Low mass transfer coefficients, on the other hand, lead to a more uniform biofilm distribution. The first scenario leads to a dramatic reduction of the hydraulic conductivity with almost no change in water retention, whereas the second scenario has a smaller effect on conductivity but a larger influence on retention. The current modeling approach identifies key factors that still need to be studied and opens the way for simulation and optimization of processes involving significant biological activity in unsaturated soils.

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Computational pore network modeling of the influence of biofilm permeability on bioclogging in porous media

Cited by 100 publications

References 33 publications

Biomechanical Analysis of Infectious Biofilms

Biomechanical Analysis of Infectious Biofilms

Solute Mass Exchange Between Water Phase and Biofilm for a Single Pore

Modeling biofilm dynamics and hydraulic properties in variably saturated soils using a channel network model

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