Litcius/Paper detail

Microfluidic techniques for separation of bacterial cells via taxis

Jyoti P. Gurung, Murat Gel, Matthew A. B. Baker

2020Microbial Cell26 citationsDOIOpen Access PDF

Abstract

The microbial environment is typically within a fluid and the key processes happen at the microscopic scale where viscosity dominates over inertial forces. Microfluidic tools are thus well suited to study microbial motility because they offer precise control of spatial structures and are ideal for the generation of laminar fluid flows with low Reynolds numbers at microbial lengthscales. These tools have been used in combination with microscopy platforms to visualise and study various microbial taxes. These include establishing concentration and temperature gradients to influence motility via chemotaxis and thermotaxis, or controlling the surrounding microenvironment to influence rheotaxis, magnetotaxis, and phototaxis. Improvements in microfluidic technology have allowed fine separation of cells based on subtle differences in motility traits and have applications in synthetic biology, directed evolution, and applied medical microbiology.

Topics & Concepts

MicrofluidicsLaminar flowMotilityNanotechnologyPhototaxisChemistryChemotaxisBiophysicsBiochemical engineeringCell biologyBiologyMaterials scienceMechanicsPhysicsBiochemistryBotanyEngineeringReceptorMicrofluidic and Bio-sensing TechnologiesMicro and Nano RoboticsGeomagnetism and Paleomagnetism Studies
Microfluidic techniques for separation of bacterial cells via taxis | Litcius