Method Article

Real-Time Visualization of Nutrient Media Impact on Pseudomonas aeruginosa Biofilm Development Using a Microfluidic System

DOI:

10.3791/69997

May 15th, 2026

In This Article

Summary

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This protocol evaluates the influence of rich (TSB) and minimal (FAB) nutrient media compositions on Pseudomonas aeruginosa PAO1 and PA14 biofilm development in a steady state flow environment in a microchannel.

Abstract

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The pathogenic bacterium Pseudomonas aeruginosa is a major cause of numerous nosocomial infections, and its growing antimicrobial resistance has led to it posing a significant public health threat. This article presents a comprehensive protocol detailing the use of a microfluidic system for the real-time visualization and quantification of biofilm development in two key P. aeruginosa strains, PAO1 and PA14. The method employs optically transparent, multichannel microchannel plates to subject bacterial cultures to a continuous, steady flow of media, including tryptic soy broth (TSB) or modified minimal fastidious anaerobic broth (FAB) with varying carbon source concentrations, thereby mimicking conditions found in the clinical environments. Over a 24-h period, automated real-time imaging captures the growth and maturation of biofilms in the form of biofilm surface area coverage, thickness, and surface roughness in a highly reproducible manner. The experimental objective is to use the results to demonstrate that biofilm formation for both strains is significantly impacted by changes in nutrient media composition. The goal of this visualized protocol is to provide a method for researchers to study biofilm dynamics under steady laminar flow conditions, and the insights gained could be leveraged to develop alternative, non-antimicrobial strategies for eradicating early-stage P. aeruginosa biofilms in nosocomial settings.

Introduction

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The goal of this method is to observe the impact of two different culture media, i.e., tryptic soy broth (TSB) and modified minimal fastidious anaerobic broth (FAB), on the biofilm growth of two Pseudomonas aeruginosa strains, namely PAO1 and PA14. Though P. aeruginosa PAO1 and PA14 are both common laboratory reference strains, the PA14 strain infects a greater proportion of hosts from plants to invertebrates1. The TSB nutrient broth is a general-purpose culture medium with 2.5 g/L of glucose as a carbon source and is able to cultivate a wide range of bacteria due to its composition of casein and soy peptones for organic nitro....

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Protocol

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1. Glassware cleaning

  1. Submerge two 200 mL glass bottles to be used for media and agar, and three 1 L glass bottles in a 10% hydrochloric acid (HCl) bath for approximately 5 min at room temperature.
    CAUTION: Hydrochloric acid is corrosive. Perform all acid handling in a chemical fume hood while wearing appropriate personal protective equipment (lab coat, gloves, and eye protection).
  2. Subsequently, remove glassware from the HCl bath and rinse twice with tap water and once with distilled water (dH2O).

2. Tryptic soy broth media preparation

  1. Prepare the TS....

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Results

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This section outlines the representative outcomes when applying the above protocol procedure. All experiments were performed with at least three independent biological replicates, each consisting of six parallel channels, and data are presented as mean ± standard deviation. Error bars in all graphs represent standard deviation, as defined in the figure legends.

The growth of the PAO1 and PA14 strains at 37 °C, in TSB media, and under 0.01 Pa hydrodynamic wall shear stress over a 24 h .......

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Discussion

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The several critical steps that collectively form this protocol enable a more comprehensive and accurate analysis of biofilm formation than alternative, more traditional methods. A key component is the use of a 48-well microchannel plate, with microscale channels of dimensions 350 µm × 70 µm × 4 mm (W × H × L). These dimensions specifically replicate the flow conditions and microenvironments found in hospital settings, such as urinary catheters or the lung bronchioles of cystic fibrosis pati.......

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Disclosures

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The authors have nothing to disclose.

Acknowledgements

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The authors would like to thank the School of Mechanical, Aerospace and Civil Engineering (MAC) at the University of Sheffield for funding.

....

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Materials

List of materials used in this article
NameCompanyCatalog NumberComments
(NH4)2SO4Acros Organics7783-20-2For modified FAB medium
48-well 0-2 Pa microchannel plate - glass coverslipCell Microsystems910-0047-5PackMicrochannels for media flow and biofilm
growth with real-time imaging
-80 °C FreezerThermo Fisher Scientific1.16057E+15To store glycerol stocks until further use
Agar, Bacteriological GradeAcros Organics443570010For Agar plates - culturing bacteria
Analytical BalanceVWRVWRI611-2297To measure components of media used
AutoclavePriorclave4304To sterilize glassware
BioFlux 1000HTI&L Biosystemshttps://il-biosystems.com/cell- microsystems/device/bioflux-1000ht-
shear-flow-system/ 
For Microchannel flow and biofilm growth experiments
BioFlux Control ModuleI&L Biosystemshttps://il-biosystems.com/cell-
microsystems/device/bioflux-1000ht- shear-flow-system/ 
To set up and monitor media flow and biofilm growth within the microchannels
BioFlux Montage SoftwareI&L Biosystemshttps://il-
biosystems.com/app/uploads/2025/01/Bi oFlux_Overview_.pdf
To set up and monitor media flow and biofilm growth within the microchannels
CaCl2Fisher Scientific10043-52-4For modified FAB medium
CaSO4.2H2OChemCruzA1719For 1 L minimal metal solution
Clear Polystyrene 96-well PlateCorning, CostarCLS7007For viable cell count
CoSO4.7H2OSigma-Aldrich10026-24-1For 1 L minimal metal solution
CuSO4.5H2OHoneywell209198-100GFor 1 L minimal metal solution
Eppendorf Tubes 3810XEppendorf30125150For P. aeruginosa glycerol stocks
FeSO4.7H2OVWR International Ltd.284005EFor 1 L minimal metal solution
Fiji (ImageJ)National Institutes of Healthhttps://imagej.net/software/fiji/downloa
ds
Z-stack image processing
GlucoseSigma-Aldrich50-99-7For glucose modified FAB Medium
GlycerolSigma-Aldrich56-81-5For P. aeruginosa glycerol stocks
H3BO3Fisher Scientific10043-35-3For 1 L minimal metal solution
Hamamatsu Orca-Flash 4.0 Camera Model C11440-
42U
HamamatsuC11440-42UFor Microchannel flow and biofilm growth
experiment real-time imaging
KH2PO4Fisher BioReagents7778-77-04For modified FAB medium
Methylated-SpiritSigma-Aldrich2857To clean microbiology cabinet before and after
use
MgCl2Sigma-AldrichM8266-100GFor modified FAB medium
Microbiology Cabinet Class IIThermo Fisher Scientific42111226To carry-out protocol steps without
contaminating bacteria, broth or agar
Mini IncubatorLabnet Internationalsn03171014To thaw PAO1 and PA14 after -80 °C freezer and
for initial 24 h bacterial agar plate growth
MnSO4.H2OSigma-Aldrich10034-96-5For 1 L minimal metal solution
Na2HPO4.2H2OSigma-Aldrich10102-40-6For modified FAB medium
NaClSigma-AldrichS5886-500GFor modified FAB medium
NaMoO4.H2OSigma-Aldrich10102-40-6For 1 L minimal metal solution
Precision BalanceVWRVWRI611-2299To measure components of media used
Refrigerated CentrifugeHeraeus40289841Separating P. aeruginosa culture from
supernatant for glycerol stocks
Semi-Micro CuvettesAlpha LaboratoriesX72053For optical density measurements
Shaking IncubatorINFORS HThttps://infors- ht.com/en/products/incubator- shakers/multitron-standardFor overnight cultures
Sodium citrateSigma-Aldrich71498-250GFor Sodium citrate modified FAB medium
Sterile Plastic Inoculation LoopsMicrospec15782105For P. aeruginosa PAO1 and PA14 innoculation into agar plates and falcon tubes
Tryptic Soy Agar, vegitoneMillipore14432-500G-FFor Agar plates - culturing bacteria
Tryptic Soy BrothSigma-AldrichT8907Dehydrated culture media - 6 g/200 mL
Type 1 Water DispenserThermo Fisher Scientificsn42103311For distiled water
ZnSO4.7H2OFisher Scientific7446-20-0For 1 L minimal metal solution

References

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  1. Grace, A., Sahu, R., Owen, D. R., Dennis, V. A. Pseudomonas aeruginosa reference strains PAO1 and PA14: A genomic, phenotypic, and therapeutic review. Front Microbiol. 13, 1023523(2022).
  2. T8907 Tryptic Soy Broth. , Sigma-Aldrich. Available from:

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Tags

Pseudomonas AeruginosaBiofilm DevelopmentMicrofluidic SystemReal Time VisualizationNutrient MediaLaminar FlowBiofilm QuantificationSurface Area CoverageAntimicrobial ResistanceNosocomial Infections
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