Litcius/Paper detail

Shear-enhanced sorting of ovoid and filamentous bacterial cells using pinch flow fractionation

Guillaume de Timàry, Clothilde J. Rousseau, Laurence Van Melderen, Benoît Scheid

2022Lab on a Chip29 citationsDOIOpen Access PDF

Abstract

in a low aspect ratio pinch flow fractionation device. To that aim, we vary the Reynolds number over two orders of magnitude, while monitoring the dynamics of the cells across our device. At low flow rates, filamentous cells adopt several rotational motions in the pinched segment, which are induced both by the shear rate and by their close interactions with the nearest wall. As a result, the geometrical centre of the filamentous cells deviates towards the centre of the channel, which increases their effective sorting diameter depending on the length of their major axis as well as on the rotational mode they adopt in the pinch. As the flow rate increases, particles are forced to align vertically in the pinch, in the direction of the main shear gradient, which reduces the amplitude of the lateral deviation generated by their rotation. The trajectory of the particles in the expansion is directly determined by their position at the pinch outlet. As a consequence, the position of the filamentous cells at the outlet of the device strongly depends on the flow rate as well as on the length of their major axis. Based on these observations we optimized the flow conditions to successfully extract an ultra high purity sample of filamentous cells from a solution containing mainly ovoid cells.

Topics & Concepts

OvoidPinchFractionationShear (geology)ElectrofusionShear flowSortingMaterials scienceChemistryComposite materialMechanicsChromatographyPhysicsGeometryMechanical engineeringComputer scienceEngineeringMathematicsProgramming languageMicrofluidic and Bio-sensing TechnologiesField-Flow Fractionation TechniquesNanopore and Nanochannel Transport Studies