Team:TU Delft-Leiden/Project/Microfluidics

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<p>Intro paragraph about microfluidics </p>
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                    <a href="/Team:TU_Delft-Leiden/Project/Microfluidics#Protocol">
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                    <p>Protocol</p>
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                    <a href="/Team:TU_Delft-Leiden/Project/Microfluidics#MotherMachine">
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                    <p>Mother Machine</p>
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                    <p>Microfluidics for Electron Transfer</p>
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                    <a href="/Team:TU_Delft-Leiden/Project/Microfluidics#Paper">
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                    <p>Paper Microfluidics</p>
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Revision as of 18:20, 15 October 2014


Microfluidics

Intro paragraph about microfluidics


Protocol

Materials

Mold (PDMS, Photoresist, lasercut, or similar)

PDMS

PDMS Catalyst

Microscope Cover Slips

Tygon Tubing


Equipment

Vacuum Pump

Plasma Preen Machine

Hole Cutter

Stove


Method



- Mix PDMS and catalyst with a ratio 9:1 by weight, mix thoroughly (typically, about 10-15g is needed for one device)



- Construct a tray out of foil around the mold

- Pour pdms mixture into mold to a thickness of 5-10mm



- De-gas mixture in a vacuum pump for ~20 minutes or until no bubbles are visible



- Place in an 80C stove for 10 minutes

- Cut out device from the mold with a scalpel

- Peel the device off the mold with a pair of tweezers

- Cut holes for tubing (through the top down)



- Clean a slide with ethanol and water, and dry thoroughly with a nitrogen gun



- Place PDMS plus clean cover slip in a petri dish and plasma activate for ~10s



- Press PDMS and coverslip together, making sure a full seal is made

- Brush a thin line of PDMS around the seams and place in stove at 80C for 10 minutes

- Insert tubing into device


Mother Machine

The “Mother Machine” is a microfluidic device designed at the department of Nanobiotechnology of TU Delft [1]. It is designed for the study of single e-coli cells via controlled restriction of cellular movement, through mechanical means of the design of the channels.

Three Dimensional schematic of the "Mother Machine" microfluidics device [1].

The device consists of a wide central trench, through which fluid is flowed. Smaller closed channels, ranging from 0.3 to 0.8 um width, branch off perpendicular to the main channel. This confine individual cells of E coli and thus serve as immobilising growth channels - allowing for the study of individual cells, without the need of chemical fixation. Having kindly been given a set of molds for this devices from the TU Delft department of Nanobiotechnology, we fabricate mother machines and use them to Quantify the flourescence of single cells of the BBa_k1316016 and BBa_k1316001 constructs from the landmine module.

Cell culture is Flown into the device with a syringe pump.

For resuts of the characterisation performed with the Mother Machine, please visit Landmine Module - Characterization.


Microfluidics Device for Electron Transfer

Since the final vision for Electrace is for a product which can be used by non-scientists in the field, microfluidics is a central part of this. It was therefore important to prototype a microfluidics device with built in electrodes. A proof-of-principle device was constructed and tested with cyclic voltammetry to determine whether measurable currents could be produced.


Electrodes are made by injecting carbon paste into blocked off side channels, and flowing an etchant through a main channel remove the walls, thus exposing the electrodes. [Image REF]

Incorporating electrodes adds to the complexity of the microfluidics device, especially since both carbon electrodes and silver/silver chloride electrodes need to be built in. Several options were explored, including the injection of carbon paste into the device as describes in this paper [], and the use of silver/silver chloride wire inserts.


Finally, the use of screen printed electrodes produced by Dropsens [] was chosen. These were to be embedded into the PDMS of the microfluidics device, providing a reservoir where the electrodes would be in contact with the fluid.


3d images of the microfluidics device design, seen from the top and bottom.

Dimension drawing of the mask design for the microfluidics device. With a total height of 200 microns, this creates a volume of 33 microlitres.

Since the design features comparatively large dimensions, the complex high precision methods such as photo-lithography were not required to make the mold. Instead, we considered several simpler approaches. 3D printing was first considered, but was discarded for it's limited resolution and poor surface finish (at this point, 3d printers still create a rough finish which would be problematic at the small scales of microfluidics. Laser-cutting was considered next. Several materials were considered and tested with the laser-cutter, before PVC electrical tape was chosen- as described here. This can be applied to a slide - and layered to vary the height - and cut either by hand for quick prototypes, or with a laser-cutter for greater precision.


Electrical tape applied to a glass slide provides a quick "low-tech" solution for making microfluidic mould, a popular method amongst "DIY-Biologists". Patterns can either be cut by hand, or with a laser cutter.

The screen printed electrode was lightly bonded to the mold with a thin film of vacuum grease (a very light adhesive was needed - something to hold the electrode in position for pouring, but would still allow removal from the mold later), before being poured with PDMS. This resulted in the electrode being fully encased for PDMS except for where it was in contact to the tape - namely the fluid reservoir, and the opening for the electrical contacts. Since the introduction of a rigid material in the PDMS made tearing a greater risk, a higher ratio of catalyst than typical (8:1 PDMS:catalyst by weight) was used to create a firmer, more durable device.


The screen printed electrode was pressed onto the mold and held in place with vacuum grease

PDMS cast with embedded electrode (the final dimensions of the channels were altered in light of early tests).

The device features a 33uL reservoir with an inter-digitated electrode (carbon-carbon-silver/silver chloride). Wires can be soldered onto the three exposed contacts for connection with a potentiostat or other instrumentation. This makes the device perfect for electrochemical analysis of small quantities of analyte.


The completed microfluidics devices

Paper Microfluidics

Paper microfluidics offer a simple, low cost method for employing some of the advantages of microfluidics for analytical purposes. Disposable analytical devices can be made easily and quickly with no specialised equipment. We plan to combine a paper microfluidic device with our Electrace E. coli, and printed electrodes, to create a “test strip” for our analyte, which can be used to measure the voltage output of our biosensor. There are several methods that can be employed to create a paper microfluidic device. The two we chose to look at due to their simplicity and potential for good results were FLASH (Andres W. Martinez et al) - which utilises a form of photolithography, and a method utilising Parafilm, by E. M. Dunfield et al.

Parafilm Method

We first tested the Parafilm method, as described here. This involves stacking a piece of filter paper, a heat resistant mask (in the shape of the desired fluid channels) and a layer of Parafilm, and applying heat and pressure to this stack. The principle is that the Parafilm melts, and is forced into the filter paper, creating a hydrophobic area. The mask prevents the Parafilm entering the paper, thus this area remains hydrophilic - providing the fluid channels. A regular clothes iron was used to provide heat, and pressure was provided by simply pressing down on the iron. We tested several types of paper, including tissue paper, coffee filter, filter paper (?) and Whattman grade 1) thicker grades of paper resulted in failure, as the Parafilm would not fully penetrate the paper. Best results were had with the coffee filter paper.


The Parafilm method allows simple devices to be made with no specialist equipment.

With a heat press, such as those used to print images on to t-shirts, more heat and pressure could be applied in a consistent manner, likely improving results even in thicker grades of paper, however such a device was not accessible. Whilst we has some degree of success with this method, it had several shortcomings which made us move onto the second method, namely:

- Didn’t work with thicker grade of pressure (with our methods)

-Some Parafilm “leakage” across the edges of the mask, results in a degree of imprecision in the creation of the channels.

-The need to cut out the mask limits its ability to be used for complex shapes and small dimensions, particular if access to a laser cutter or similar is not possible.


FLASH Method

The FLASH method employs SU-8 photoresist to create the hydrophobic areas in the paper. Photoresist is an epoxy which polymerises when exposed to light. The PACE method involves soaking the paper in photoresist, placing a mask over the paper (inkjet printed onto transparency film) exposing to UV. The UV polymerises the photoresist not covered by the mask, creating a hydrophobic paper/epoxy composite. The paper can then be rinsed in acetone to remove all un-set photoresist from the masked areas, creating the hydrophilic channels.


First we tested whether undiluted SU-8 could fully penetrate the filter paper. Three types of paper were tested: coffee filters, a thin grade filter paper, and Whattman grade 1. The photoresist was applied to a sample of each with a small paint brush and visual inspection was used to check whether each sample had become fully saturated with the resin. Full saturation was not possible with thick papers such as the Whattman grade 1.


A batch of SU-8 soaked filter paper was made up and dried, and cut into 20x40mm samples strips. Each strip was to be tested for its hydrophobic/hydrophilic properties (and thus determining if the photoresist had worked as intended) by pipetting a small drop of loading dye on to the paper. One strip was soaked in a bath of acetone and rinsed with ethanol prior to any UV Exposure as a negative control. All of the SU-8 appeared to be washed off, as the paper resumed its original hydrophilic properties. A second strip was exposed to sunlight for 15 minutes before being soaked in acetone and rinsed with ethanol. This strip remained hydrophobic. Various UV were tested, however it is important to note that the optimal wavelength for th SU-8 is 365nM, so the UV source should be as close to this as possible - several of the UV sources tested were unsuccessful. Finally a 370nM lamp (name of device?) was used for exposure of 5 minutes.


Masked SU-8 soaked paper being exposed to UV light

After exposure, the sample was placed on a ~90°c hotplate, where an instantaneous change of colour was noted. The sample was left on the hot plate for 5 minutes to cure. This was also carried out with a masked sample, which was equally successful. A clear colour difference could be observed between the masked and unmasked areas.


Proposed concept for a paper microfluidics device for the Electrace cells.

To test the microfluidic strips, a drop of loading dye was applied to the end of the channel on the sample, where it moved up the channel through capillary action. The progress from capillary action was fairly slow however. Paper microfluidics hold great potential for low cost diagnostic devices, and could one day be used with a system such as Electrace. However the need for a way of immobilising cells in the device, and to incorporate electrodes, amongst other challenges, made the use of paper microfluidics infeasible for the scope of the project, so further development was terminated.


Completed paper microfluidic slips, with blue loading dye applied

Special thanks to

Dominik Schmeiden
Marteen Gorseling
Sriram Tiruvadi Krishnan
Victor Marin Lizarraga
Dropsens

References

1. M Charl Moolman†, Zhuangxiong Huang et al., “Moolman et al.: Electron beam fabrication of a microfluidic device for studying submicron-scale bacteria. Journal of Nanobiotechnology 2013 11:12”

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