The project tackles the issue of biofilm development in the porous microstructure of the soils, where it is submitted to the porous media flows and the subsequent mixing.
Bacteria strive in these hidden and complex environments. Most times, their can be observed attached to the surface, upon which they have formed biofilms. Since soils are generally opaque, it is impossible to monitor in the environments the formation of such biofilms. The project aims at reproducing the mixing conditions of the soil, and observe biofilm development in it.
First, we needed to build the tool, which we successfully achieved thanks to microfluidics devices which mimics the soil's mixing properties.
Second, we observed the growth of biofilm in various mixing conditions (i) without antibiotics and in homogeneous conditions and (ii) in the presence of a mixture of antibiotics, for which the mixing properties define the viable space available for the growth of the biofilm.
Results:
1) We managed to recreate the transport properties of a 3D soil in a quasi-2D microfluidic device, by unveiling the strong ties between the dispersion and the chaotic mixing properties.
2) We observed that the biofilm would grow wider in the geometries which would disperse AND mix solute better.
3) In the presence of antibiotics, we saw that the biofilm would grow better in the less mixing geometries, where the viable space would be larger.