Characterization of small microfluidic valves for studies of mechanical properties of bacteria

Da Yang, Clayton M. Greer, Branndon P. Jones, Anna D. Jennings, Scott T. Retterer, Jaan Männik

Research output: Contribution to journalArticlepeer-review

4 Scopus citations

Abstract

Lab-on-a-chip platforms present many new opportunities to study bacterial cells and cellular assemblies. Here, the authors describe a new platform that allows us to apply uniaxial stress to individual bacterial cells while observing the cell and its subcellular assemblies using a high resolution optical microscope. The microfluidic chip consists of arrays of miniature pressure actuated valves. By placing a bacterium under one of such valves and partially closing the valve by externally applied pressure, the cell can be deformed. Although large pressure actuated valves used in integrated fluidic circuits have been extensively studied previously, here the authors downsize those microfluidic valves and use flow channels with rectangular cross-sections to maintain the bacteria in contact with cell culture medium during the experiments. The closure of these valves has not been characterized before. First, these valves are modeled using finite element analysis, and then compared the modeling results with the actual closing profiles of the valves, which is determined from absorption measurements. The measurements and modeling show with good agreement that the deflection of valves is a linear function of externally applied pressure and the deflection scales proportionally to the width of the flow channel. In addition to characterizing the valve, the authors show at a proof-of-principle level that it can be used to deform a bacterial cell at considerable magnitude. They found the largest deformations in 5?μm wide channels where the bacterial width and length increase by 1.6 and 1.25 times, respectively. Narrower and broader channels are less optimal for these studies. The platform presents a promising approach to probe, in a quantitative and systematic way, the mechanical properties of not only bacterial cells but possibly also yeast and other single-celled organisms.

Original languageEnglish
Article number06F202
JournalJournal of Vacuum Science and Technology B: Nanotechnology and Microelectronics
Volume33
Issue number6
DOIs
StatePublished - Nov 1 2015

Funding

FundersFunder number
National Stroke FoundationMCB-1252890
University of Tennessee
National Science Foundation1252890

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