Your search keyword '"Davit, Y"' showing total 4 results

1. Quantitative 3D comparison of biofilm imaged by X-ray micro-tomography and two-photon laser scanning microscopy.

Author

Larue AE, Swider P, Duru P, Daviaud D, Quintard M, and Davit Y

Subjects

Contrast Media, Porosity, Pseudomonas aeruginosa physiology, Biofilms, Imaging, Three-Dimensional methods, Microscopy, Confocal methods, X-Ray Microtomography methods

Abstract

Optical imaging techniques for biofilm observation, like laser scanning microscopy, are not applicable when investigating biofilm formation in opaque porous media. X-ray micro-tomography (X-ray CMT) might be an alternative but it finds limitations in similarity of X-ray absorption coefficients for the biofilm and aqueous phases. To overcome this difficulty, barium sulphate was used in Davit et al. (2011) to enable high-resolution 3D imaging of biofilm via X-ray CMT. However, this approach lacks comparison with well-established imaging methods, which are known to capture the fine structures of biofilms, as well as uncertainty quantification. Here, we compare two-photon laser scanning microscopy (TPLSM) images of Pseudomonas Aeruginosa biofilm grown in glass capillaries against X-ray CMT using an improved protocol where barium sulphate is combined with low-gelling temperature agarose to avoid sedimentation. Calibrated phantoms consisting of mono-dispersed fluorescent and X-ray absorbent beads were used to evaluate the uncertainty associated with our protocol along with three different segmentation techniques, namely hysteresis, watershed and region growing, to determine the bias relative to image binarization. Metrics such as volume, 3D surface area and thickness were measured and comparison of both imaging modalities shows that X-ray CMT of biofilm using our protocol yields an accuracy that is comparable and even better in certain respects than TPLSM, even in a nonporous system that is largely favourable to TPLSM., (© 2018 The Authors Journal of Microscopy © 2018 Royal Microscopical Society.)

Published

2018

2. Hydrodynamic dispersion within porous biofilms.

Author

Davit Y, Byrne H, Osborne J, Pitt-Francis J, Gavaghan D, and Quintard M

Subjects

Computer Simulation, Hydrodynamics, Porosity, Bacterial Physiological Phenomena, Biofilms growth & development, Culture Media metabolism, Models, Biological

Abstract

Many microorganisms live within surface-associated consortia, termed biofilms, that can form intricate porous structures interspersed with a network of fluid channels. In such systems, transport phenomena, including flow and advection, regulate various aspects of cell behavior by controlling nutrient supply, evacuation of waste products, and permeation of antimicrobial agents. This study presents multiscale analysis of solute transport in these porous biofilms. We start our analysis with a channel-scale description of mass transport and use the method of volume averaging to derive a set of homogenized equations at the biofilm-scale in the case where the width of the channels is significantly smaller than the thickness of the biofilm. We show that solute transport may be described via two coupled partial differential equations or telegrapher's equations for the averaged concentrations. These models are particularly relevant for chemicals, such as some antimicrobial agents, that penetrate cell clusters very slowly. In most cases, especially for nutrients, solute penetration is faster, and transport can be described via an advection-dispersion equation. In this simpler case, the effective diffusion is characterized by a second-order tensor whose components depend on (1) the topology of the channels' network; (2) the solute's diffusion coefficients in the fluid and the cell clusters; (3) hydrodynamic dispersion effects; and (4) an additional dispersion term intrinsic to the two-phase configuration. Although solute transport in biofilms is commonly thought to be diffusion dominated, this analysis shows that hydrodynamic dispersion effects may significantly contribute to transport.

Published

2013

3. Imaging biofilm in porous media using X-ray computed microtomography.

Author

Davit Y, Iltis G, Debenest G, Veran-Tissoires S, Wildenschild D, Gerino M, and Quintard M

Subjects

Contrast Media, Image Processing, Computer-Assisted, Porosity, Research Design, Biofilms, Imaging, Three-Dimensional methods, X-Ray Microtomography

Abstract

In this study, a new technique for three-dimensional imaging of biofilm within porous media using X-ray computed microtomography is presented. Due to the similarity in X-ray absorption coefficients for the porous media (plastic), biofilm and aqueous phase, an X-ray contrast agent is required to image biofilm within the experimental matrix using X-ray computed tomography. The presented technique utilizes a medical suspension of barium sulphate to differentiate between the aqueous phase and the biofilm. Potassium iodide is added to the suspension to aid in delineation between the biofilm and the experimental porous medium. The iodide readily diffuses into the biofilm while the barium sulphate suspension remains in the aqueous phase. This allows for effective differentiation of the three phases within the experimental systems utilized in this study. The behaviour of the two contrast agents, in particular of the barium sulphate, is addressed by comparing two-dimensional images of biofilm within a pore network obtained by (1) optical visualization and (2) X-ray absorption radiography. We show that the contrast mixture provides contrast between the biofilm, the aqueous-phase and the solid-phase (beads). The imaging method is then applied to two three-dimensional packed-bead columns within which biofilm was grown. Examples of reconstructed images are provided to illustrate the effectiveness of the method. Limitations and applications of the technique are discussed. A key benefit, associated with the presented method, is that it captures a substantial amount of information regarding the topology of the pore-scale transport processes. For example, the quantification of changes in porous media effective parameters, such as dispersion or permeability, induced by biofilm growth, is possible using specific upscaling techniques and numerical analysis. We emphasize that the results presented here serve as a first test of this novel approach; issues with accurate segmentation of the images, optimal concentrations of contrast agents and the potential need for use of synchrotron radiation sources need to be addressed before the method can be used for precise quantitative analysis of biofilm geometry in porous media., (© 2010 The Author Journal of Microscopy © 2010 The Royal Microscopical Society.)

Published

2011

4. Multiple-scale analysis of transport in porous media with biofilms.

Author

Davit, Y., Debenest, G., and Quintard, M.

Subjects

*BIOFILMS, *POROUS materials, *MICROBIAL aggregation, *MICROBIAL ecology, *CHEMICAL decomposition

Abstract

Biodegradation in porous media is most often the consequence of coupled transport phenomena in the presence of biofilms. The description of such transport problems involves different scales: the bacteria scale, the scale of a locally homogenized biofilm, heterogeneous biofilms at a scale lower than the pore-scale, the pore-scale problem, the Darcy-scale description, and, possibly, subsequent scales corresponding to heterogeneities effects. In this paper, various upscaling problems are reviewed. Different models may be built, depending on the amount of local non-equilibrium included in the analysis: equilibrium models, multiple-equations models, asymptotic models. These different models feature different effective properties, which can be estimated from real data through the resolution of several “closure problems” linking averaged variables and lower-scale deviations. The relevance of these different models is discussed based on some theoretical analysis and direct numerical simulation. [ABSTRACT FROM AUTHOR]

Published

2010