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In This Article

  • Summary
  • Abstract
  • Introduction
  • Protocol
  • Results
  • Discussion
  • Disclosures
  • Acknowledgements
  • Materials
  • References
  • Reprints and Permissions

Summary

The present protocol describes a microfluidic platform to study biofilm development in quasi-2D porous media by combining high-resolution microscopy imaging with simultaneous pressure difference measurements. The platform quantifies the influence of pore size and fluid flow rates in porous media on bioclogging.

Abstract

Bacterial biofilms are found in several environmental and industrial porous media, including soils and filtration membranes. Biofilms grow under certain flow conditions and can clog pores, thereby redirecting the local fluid flow. The ability of biofilms to clog pores, the so-called bioclogging, can have a tremendous effect on the local permeability of the porous medium, creating a pressure buildup in the system, and impacting the mass flow through it. To understand the interplay between biofilm growth and fluid flow under different physical conditions (e.g., at different flow velocities and pore sizes), in the present study, a microfluidic platform is developed to visualize biofilm development using a microscope under externally-imposed, controlled physical conditions. The biofilm-induced pressure buildup in the porous medium can be measured simultaneously using pressure sensors and, later, correlated with the surface coverage of the biofilm. The presented platform provides a baseline for a systematic approach to investigate bioclogging caused by biofilms in porous media under flow conditions and can be adapted to studying environmental isolates or multispecies biofilms.

Introduction

Biofilms - bacterial colonies embedded in a self-secreted matrix of extra-polymeric substances (EPS) - are ubiquitous in natural porous media, such as soils and aquifers1, and technical and medical applications, like bioremediation2, water filtration3 and medical devices4. The biofilm matrix is comprised of polysaccharides, protein fibers, and extracellular DNA5,6, and strongly depends on the microorganisms, the availability of nutrients, as well as the environmental conditions7. Yet, the functions of the matrix are universal; it forms the scaffold of the biofilm structure, protects the microbial community from mechanical and chemical stresses, and is largely responsible for the biofilms' rheological properties5.

In porous media, the growth of biofilms can clog pores, causing the so-called bioclogging. Biofilm development is controlled by the fluid flow and pore size, defined as the distance separating two pillars, of the porous medium8,9,10. Both the pore size and the fluid flow control the nutrient transport and local shear forces. In turn, the growing biofilm clogs pores, affecting the velocity distribution of the fluid11,12,13, the mass transport, and the hydraulic conductivity of the porous medium14,15. The changes in hydraulic conductivity are reflected through increased pressure in confined systems16,17,18,19. Current microfluidic studies in biofilm development and bioclogging focus on studying the impact of flow velocities in homogeneous geometries16,20 (i.e., with a singular pore size) or heterogeneous porous media12,21,22. However, to disentangle the effects of flow rates and pore size on biofilm development and the resulting pressure changes in the bioclogged porous medium, a highly controllable and versatile experimental platform allowing the study of different porous media geometries and environmental conditions in parallel is required.

The present study introduces a microfluidic platform that combines pressure measurements with simultaneous imaging of the evolving biofilm within the porous medium. Because of its gas-permeability, bio-compatibility, and flexibility in the channel geometry design, a microfluidic device made of polydimethylsiloxane (PDMS) is a suitable tool for studying biofilm development in porous media. Microfluidics allow the control of physical and chemical conditions (e.g., fluid flow and nutrient concentration) with high precision to mimic the environment of microbial habitats23. Further, microfluidic devices can easily be imaged with micrometric resolution using an optical microscope and coupled with online measurements (e.g., the local pressure).

In this work, the experiments focus on studying the impact of pore size in a homogeneous porous medium analog under controlled imposed flow conditions. The flow of a culture medium is imposed using a syringe pump, and the pressure difference through the microfluidic channel is measured simultaneously with pressure sensors. Biofilm development is initiated by seeding a planktonic culture of Bacillus subtilis in the microfluidic channel. Regular imaging of the evolving biofilm and image analysis allows one to obtain pore scale resolved information on the surface coverage under various experimental conditions. The correlated information of pressure change and the extent of bioclogging provides crucial input for permeability estimations of bioclogged porous media.

Protocol

1. Silicon wafer preparation

  1. Design the geometries of the microfluidic channel in computer-aided design (CAD; see Table of Materials) software and print it onto a transparent film to create the photomask (Figure 1A).
  2. Fabricate the master mold by soft lithography (under clean-room conditions) following the steps below.
    1. Bake the silicon wafer at 200 °C for 2 h.
    2. Place the wafer at the center of a spin-coater and pour SU8 3050 photoresist (see Table of Materials) onto the wafer. Spin coat at 1,700 rpm for 40 s with a 10 s/100 rpm ramp time.
      NOTE: The spin-coating parameters were set to obtain a target thickness of 100 µm for the SU8 3050.
    3. After the spin-coating process, soft bake the silicon wafer at 65 °C for 600 s and 95 °C for 2,700 s. Let the wafer cool at room temperature overnight.
      NOTE: The overnight cooling enhances the adhesion of the SU8 to the wafer.
    4. Place the photomask (step 1.1) onto the wafer and expose it to UV light, with an exposure energy of 250 mJ/cm2 and at a wavelength of 350 nm.
    5. Post-exposure, bake the exposed substrate at 65 °C for 60 s and 95 °C for 300 s.
    6. Develop the silicon wafer to obtain the master mold by immersing it in a beaker filled with mrDev600 developer (see Table of Materials). Gently shake the beaker for 1,800 s to wash out the unpolymerized resist. Then, splash wash by spraying isopropanol on the silicon wafer and air dry.
    7. Hard bake the silicon wafer at 200 °C for 1,800 s.
  3. Silanize the master mold through vapor deposition of 20 µL of Trichloro (1H, 1H, 2H, 2H-perfluorooctyl) silane (see Table of Materials) placed on a glass slide next to the mold for 40 min in a vacuum desiccator, creating a gauge pressure of 100 mbar.

2. Fabrication of the microfluidic device

NOTE: The fabrication procedure described here is for a microfluidic device with one microfluidic channel. However, the same method can be applied to fabricate a microfluidic device with multiple microfluidic channels in parallel.

  1. Mix the elastomer with its crosslinker at a ratio of 10:1 (see Table of Materials) to prepare a PDMS mixture. Stir the mixture until it gets uniformly mixed and turns opaque due to the enclosed air bubbles.
  2. Degas the mixture in a vacuum desiccator, creating a gauge pressure of 100 mbar until the entrapped air bubbles are removed and it looks transparent. The time required for degassing is typically 30 min.
  3. Place the master mold (step 1) in a cell culture dish (see Table of Materials). Pour 20 g of the PDMS mixture on the master mold to produce channels with a final thickness of 5 mm.
  4. Bake the master mold at 70 °C for 2 h.
  5. Cut the cured PDMS around the microfluidic channel (at a distance of approximately 3 mm) using a blade, and then peel the PDMS microfluidic channel off the master mold.
  6. To create the microfluidic channels' inlet and outlet, punch holes with a biopsy punch (diameter of 1.5 mm) at its extremities (top of the triangles, see Figure 1A). Punch one additional hole at the center of the inlet triangle to install the pressure sensor later.
  7. Wash a glass slide and the microfluidic channel with a commercially available 1% detergent solution (see Table of Materials) for 5 min, then rinse them with deionized water. Thereafter, wash the PDMS microfluidic channel and the glass slide with isopropanol. Then, rinse them again with deionized water. Dry the PDMS microfluidic channel and the glass slide with compressed air at 1 bar for 1 min.
    NOTE: The porous structure of the PDMS must be completely dry for the bonding to be effective.
  8. Place the glass slide and the microfluidic channel in a plasma cleaner (see Table of Materials) and ensure the surfaces to be bonded are facing up. Turn on the plasma cleaner and treat the microfluidic channel and glass slide with air plasma at an airflow of 1 SL/h (standard liter per hour) for 1 min. Bond the microfluidic channel to the glass slide immediately after taking them out of the cleaner by putting them in contact with each other.
    NOTE: Ensure not to touch the treated surfaces, as this might affect the bonding. When fabricating a microfluidic device with multiple microfluidic channels, expose the microfluidic channels simultaneously and bond them in a single step.
  9. Place the bonded microfluidic device on an 80 °C hot plate for at least 15 min.
  10. Store the microfluidic device in a clean cell culture dish until the experiment starts.

3. Preparation of the bacterial suspension

  1. Grow a population of Bacillus subtilis NCIB 3610 20 h prior to the start of the experiment by directly inoculating 3 mL of nutrient broth no. 3 culture medium (see Table of Materials) from a frozen glycerol stock in a 15 mL culture tube. Incubate in a shaking incubator at 30 °C and 200 rpm overnight (for 16 h).
  2. Make a subculture from the overnight culture 4 h prior to the start of the experiment by adding 3 µL of the overnight culture in 3 mL of fresh culture medium (1:1,000 dilution) in a 15 mL culture tube. Incubate the subculture in a shaking incubator at 30 °C at 200 rpm for 3.5-4 h to obtain an optical density at 600 nm (OD600) of 0.1.

4. Biofilm growth experiment

  1. Turn on the box incubator of the microscope 3 h before the experiment to ensure a stable temperature of 25 °C. Mount the syringe pump and the pressure sensors (see Table of Materials).
  2. Connect the inlet and outlet tubing to the microfluidic device. Directly insert a needle (with an outer diameter of 0.6 mm) into the inlet tubing to secure the connection between the tubing and the syringe.
  3. Place the microfluidic device, 30 mL of deionized water, and 30 mL of culture medium in a vacuum desiccator and degas them for at least 1 h. Then, slowly pull the culture medium and the deionized water into two separate 30 mL syringes.
    NOTE: This step is crucial to prevent bubble formation in the channel while flushing with the culture medium.
  4. Mount the microfluidic device on the microscope and place the outlet tubing in a waste container.
    1. Connect the syringe filled with deionized water to the microfluidic channel through the microfluidic tubing and slowly inject the water until it exits from the pressure sensor outlet. Fill the pressure sensor with water and flush all the bubbles from the tubing connecting the microfluidic channel and the pressure sensor. Close the outlet of the pressure sensor with the screws dedicated to the pressure sensor.
      NOTE: The described filling procedure ensures that the pressure changes at the microfluidic channels' inlet will be precisely recorded. When running an experiment with multiple microfluidic channels, connect each channel to a separate syringe to ensure equal flow conditions in all channels.
  5. Fill the rest of the microfluidic channel with the deionized water.
  6. Place a 1.2 µm filter (see Table of Materials) on the culture media syringe. Then, remove the water syringe and carefully connect the culture media syringe to the inlet microfluidic tubing. Mount the syringe on the syringe pump and flush the channel with the culture medium at a flow rate of 2 mL/h for 1 h.
    NOTE: The filter prevents bacterial cells from entering the syringe during loading. Flushing the microfluidic channel with the culture media will remove the remaining bubbles in the porous structure.
  7. Set the syringe pump at the desired flow rate (here 1 mL/h) during the experiment and set the pressure reading of the pressure sensors to zero.
    NOTE: By setting the initial pressure reading to zero, only the pressure difference caused by biofilm development during the experiment will be measured.
  8. Pipette 1 mL of the bacterial culture at an OD600 of 0.1 in a 1.5 mL centrifuge vial. Load the bacterial culture into the microfluidic channel by placing the outlet tube into the centrifuge vial. After waiting for 5 min to remove any potential air bubbles from the tubes' outlet, withdraw 150 µL of bacterial solution at a flow rate of 1 mL/h, until the microfluidic channel is filled with the bacterial culture.
  9. Carefully remove the culture media syringe filter and place the outlet into the waste container. Leave the bacterial cells at zero-flow conditions in the microfluidic channel for 3 h to allow their surface attachment in the porous medium.
    NOTE: Leaving the bacterial cells at zero-flow conditions for 3 h was optimized for the attachment of the bacterial strain used while assuring a well-oxygenated bacterial culture. Other bacterial strains might require more or less time.
  10. To start the experiment, start the flow by setting the syringe pump to the desired flow rate (here 1 mL/h) and start the pressure reading at 1 Hz.
  11. Acquire images of the growing biofilm at the desired time interval, optical configuration, and magnification.
    ​NOTE: In the present study, images at 4x magnification in the bright-field mode in 18 positions spanning the entire domain of the porous medium were acquired every 6 min for 24 h.

5. Image analysis

  1. Reconstruct the entire porous medium from the image sequences recorded by stitching the images from the 18 positions using image analysis software (see Table of Materials) and a stitching algorithm24.
  2. Save the stitched image sequences as a sequence of singular images.
    NOTE: If the files are too big, at this point, the images can be rescaled and binned to a reasonable size for further processing.
  3. Create a mask of the pillars of the porous medium to remove them from the analysis.
  4. Remove the background of the images by dividing them by their background with the image taken at t = 0 h (Figure 2A) and binarize the images at a threshold suitable to segment the biofilm (Figure 2B).
  5. Compute the saturation of the biofilm by calculating the area covered by the biofilm (number of pixels attributed to the biofilm) compared to the void area of the porous domain (Figure 3).

Results

For the present study, a microfluidic device with three parallel microfluidic channels with different pore sizes was used (Figure 1) to study biofilm formation in porous media systematically. The biofilm formation process was visualized using bright-field microscopy. The bacterial cells and the biofilm appeared in the images as darker pixels (Figure 2). In addition, a gradual clogging process was observed; during a 24 h experiment, the initially randomly growing...

Discussion

Microfluidic porous media analogs coupled with pressure sensors provide a suitable tool to study biofilm development in porous media. The versatility in the design of the microfluidic porous medium, specifically the arrangement of the pillars, including diameter, irregular shapes, and pore size, allows the investigation of many geometries. These geometries range from single pores to highly complex, irregularly arranged obstacles mimicking different natural (e.g., soils) and industrial (e.g., membranes and filters) porous...

Disclosures

The authors declare no conflict of interest.

Acknowledgements

The authors acknowledge support from SNSF PRIMA grant 179834 (to E.S.), discretionary funding from ETH (to R.S.), ETH Zurich Research Grant (to R.S. and J.J.M.), and discretionary funding from Eawag (to J.J.M.). The authors would like to thank Roberto Pioli for illustrating the experimental setup in Figure 1B and Ela Burmeister for the silicon wafer preparation.

Materials

NameCompanyCatalog NumberComments
Acrodisc 25 mm Syringe Filter, 1.2 µm Versapor MembranePall CorporationPN41901.2 µm filters
BD 10 mL Syringe (Luer-Lock)BD300912used to fill the channel with deionised water
Box IncubatorLife Imaging Servicesused to have a stable temperature during the biofilm growth experiment
Cell density meter CO8000WPA biowaveOD meter
Centrifuge vialEppendorf301200861.5 mL
CETONI Base 120CETONI GmbHsyringe pump
CorelCADCorelDRAWsoftware used to design the microfluidic channel geometries
Culture tubes (14 mL, sterile)greiner bio-oneCulture tubes
Drying oven, VENTI-LineVWROven to cure the PDMS
HandyMigrosDetergent solution
Hot plate with temperature controlVRWto cure the PDMS-glass bonding after plasma treatment
ImageJFIJI Image analysis software
Innova 42 Inc Shaker (New Brunswick)EppendorfIncubator
Isopropanol (> 99.8%)Sigma Aldrich67-63-0
Masterflex transfer tubingMasterflexHV-06419-050.020'' ID, 0.06'' OD
Micro Slides, Plain, 75 x 60 mmCorning2947-75X50Glass slides
Microfluidic pressure sensor (1 bar)ElveflowPressure sensors
Miltex Biopsy puncher, diameter 1.5 mmIntegraPuncher to make the inlet and outlet holes of the microfluidic channel
mrDev600 developerMicroresist
Nikon Eclipse Ti2Nikon InstrumentsMicroscope
Nutrient broth n°3Sigma Aldrich
Omnifix Syringe with Luer-LockB.Braunsyringes of different volume
Plasma chamber ZeptoDiener ElectronicZEPTO-1 used to plasma bond the PDMS and the glass slide
Precision wipes (Kimtech Science)Kimberly ClarkKCP-7552to dry the glass slide
ScaleVWR-CH611-2605used to weigh the elastomer to crosslinking agent ratio
Silicon wafer (10 cm)Silicon Materials Inc. N//Phos <100> 1-10 Ω cm
Spincoater, Spin module SM150Sawatec
SU8 3050 PhotoresistKayakuam
Süss MA6 Mask alignerSUSS MicroTec Groupused to align the chrome-glass mask
Sylgard 184Dow Corningsilicone elastomer kit; curing agent
Techni Etch Cr01TechnicTechnic
Tissue culture dish 150TPP93150
Trichloro (1H, 1H, 2H, 2H perfluorooctyl) silaneSigma AldrichSigma Aldrichused to silanize the silicane wafer
Veeco Dektak 6 MVeecoProfilometer

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