Hydrodynamic resistance of a yeast clog

TL;DR

This study develops a microfluidic method to measure the hydraulic resistance of yeast biofilms at microscale, revealing how pressure and backflush cycles affect permeability and cell density, and proposing a new physical model for bioclogging.

Contribution

It introduces a novel high-accuracy microfluidic technique for quantifying yeast clog resistance and presents a new physical model challenging existing empirical descriptions.

Findings

Resistance increases with clog length.

Permeability decreases with pressure during filtration.

Backflush cycles significantly increase permeability.

Abstract

Bioclogging, the clogging of pores with living particles, is a complex process that involves various coupled mechanisms such as hydrodynamics and particle properties. This article explores bioclogging at the microscale level. At this scale, the flow rates are very low (< 100 nL/min), so a dedicated method is elaborated to measure them with high accuracy (< 6.7% error), robustness, and low response time (< 0.2s). This method employed a microfluidic device with two identical channels: a first one for a yeast suspension and a second one for a colored culture medium. These channels merged into a single wide outlet channel, where the interface of the two fluids could be monitored. As a yeast clog formed in the first channel, the displacement of the interface between the two media was imaged and compared to a pre-calibrated image database, quantifying the flow through the clog. The hydraulic resistance of a yeast clog is then quantified under two different conditions: filtration under constant pressure and oscillating pressure (backflush cycles). In both cases, the resistance increases with the clog length. At constant pressure, the clog's permeability decreased with increased operating pressure, with no detectable changes in cell density as assessed through fluorescence imaging. In contrast, backflush cycles resulted in an approximately four times higher permeability, associated with a significant non-monotonic decrease in cell density with the operating pressure. The better understanding of the fluid-structure interplay allowed us to develop a novel physical modeling of the flow in a soft and confined porous medium that challenged the empirical power-law description used in bioclogging theory by accurately replicating the measured permeability-pressure variations.