Team:ETH Zurich/Process/Validation

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|style="font-size:2em; height: 30px" class="process"|Evaluation
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|style="border-left: none;"|[[#Experimental Setup|Experimental Setup]]
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|[[#Results |Results ]]
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|[[#Analysis |Analysis]]
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|colspan="2"|'''This page presents a biological experiment which showed that the setup of the flow channel works as predicted by the models (compare plots in the [[Team:ETH_Zurich/Modeling/Microfluidics#Simulation|modeling section]]).'''
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== Experimental Setup ==
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[[File:Setup_test.png|400px|left|thumb|'''Figure 1: Experimental setup for the diffusion test in agarose filled tubes.''' ]]
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To validate that we can create a gradient of a small molecule along our agarose filled tube, we filled a tube (2 mm diameter, 7 cm long) with agarose and ''E. coli'' (see Figure 1). The E. coli cells were engineered to express an IPTG-inducible GFP. The cells were incubated at 37 °C overnight. One end of the tube was connected to a sample medium (1 ml) containing 10 mM IPTG solution.
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= Final Setup and Validation =
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'''This page presents description of our final channel design as well as description of its construction, which we did by ourselves. Our final channel is built out of polydimethylsiloxane (PDMS) and constructed with a technique called photolithography. Finally we performed some experiments in the channel in order to validate our design.'''
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== Results ==
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== Final Channel Design==
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Fluorescence pictures of the tube (see Figure 2) showed a clear gradient of the fluorescence signal over approximately 5cm of the tube. After 5cm, the signal strength dropped under the background noise.
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[[File:ETHZ Gradient.png|800px|center|thumb|'''Figure 2: GFP gradient in tube:''' ''E. coli'' with IPTG-inducable GFP were incubated in a tube (2 mm diameter, 7 cm long). GFP expression was assessed under the fluorescent microscope after overnight incubation, with a excitation wavelength of 480 nm and a emission wavelength of 510 nm. The 15 microscope photos were reassembled into one using [http://research.microsoft.com/en-us/um/redmond/groups/ivm/ICE/ the Microsoft Research Image Composite Editor].]]
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== Analysis ==
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We quantified the fluorescence signal using a moving average of 80×80 pixel, which moved along the symmetry axis of the tube (see Figure 3), in red you can see the according reaction diffusion model.
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[[File:Quantification.png|600px|center|thumb|'''Figure 3: Quantification of the gradient''' in Figure 2: The light intensity of the IPTG-induced GFP signal was quantified by a 80×80 pixel moving average. The peak at around 1.2cm is due to an air bubble in the channel (see Figure 2).]]
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[[File:ETHZ_Channels.png|400px|left|thumb|'''Figure 1:''' Final design of our microfluidic chips containing the channels. The three chips differ in shape and dimensions ]]
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The fluorescence distribution of this experiment has a similar shape as the distributions predicted by the model (see [[Team:ETH_Zurich/Modeling/Microfluidics#Simulation|modeling section]]). The difference in the experimental results compared to the simulations can be explained mainly due to the different diffusing molecules: the simulations were obtained for acetaldehyde, whereas the experiments were carried out with IPTG. We expect the different values of the diffusion as well as of the degradation constants of the two molecules to be the main reason for the differences.
 
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On the left is the design of our final microfluidic devices, which we made out of polydimethylsiloxane (PDMS). The three chips differ between themselves in their shape and dimensions. On the left side of the chips, each design has a reservoir attached to one end of the channels.
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'''Dimensions of the chips:'''
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* The size of the first two chips is 15 x 33 mm, the size of the last one is 23 x 46 mm.
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* The width of the channels is either 0.5 or 1 mm
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* Channel length:
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- Large chip: (from top to bottom) 30 mm, 15 mm and ca. 60 mm <br>
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- Small chip: all 20mm
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{{:Team:ETH Zurich/Templates/SectionEnd}}
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{{:Team:ETH Zurich/Templates/SectionStart}}
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== Final Channel Construction==
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To construct the microfluidic channels, we used the technique photolithography. Photolithography is done by photopatterning of structures by using a mask (drawing of channels in 2D) and is based on the utilization of particular substances (photoresists) that become soluble to particular solvents after being exposed to UV light [[#Ref1|[1]]].<br><br>
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Hereafter a brief description of the photolithography technique: [[#Ref2|[2]]]
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First, a mask for the microfluidic devices is made by printing the design on glass or quartz or simply on a regular transparency. Then, an SU-8 negative photoresist is spun onto a Si wafer until the final thickness of the photoresist is achieved. The transparency photomask is placed over the Si waver coated with photoresist and the photoresist is exposed to UV light, after which a postexposure bake is performed to crosslink selectively the exposed portions of the photoresist causing the solidification of the material. The sample is put in a beaker containing SU-8 developer to remove the unexposed SU-8. After the sample containing the exposed SU-8 only is is taken out of the baker and dried, PDMS is applied over the SU-8 mold and allowed to cure. SU-8 is removed and a glass is bounded to the PDMS. The channels are constructed. [[#Ref2|You can read more about the technique here.]]<br><br>
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[[File:ETHZ_photolithography.png|800px|center|thumb|'''Figure 2:''' The process of designing the microfluidic devises. Graphic taken from [[#Ref2|[2]]] ]]
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You can see below some photos of the channel building process:
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<center>
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<gallery widths=240px heights=240px perrow=3 caption="Gallery: Producing the channel">
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File:ETH MasK mikro.png
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File:Mikrofluidic negative.JPG
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File:Negative and PDMS.JPG
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File:Making holes.JPG
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File:Cleaning.JPG
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File:Plasmaofen.JPG
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</gallery>
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</center>
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:::'''Figure 3: Fabrication of the PDMS channel'''
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==Setup Validation==
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[[File:ETH arabinose channel.jpg|900px|center|thumb|'''Figure 4:  arabinose-induced GFP production in a 30 mm channel.''' The system was induced with a 1 %w/v arabinose solution in the reservoir on the left side of the channel. Pictures were taken 5 h after induction.]]
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To test the different PDMS channels, we engineered an arabinose-dependent sfGFP reporter plasmid, with which ''e.coli'' BW27783 strain [[#Ref3|[3]]] was transformed. A liquid preculture was grown until an OD<sub>600</sub> of 1 was reached. Cells then were diluted by 1/5 in LB and 15 %w/v agar was added to the suspension. Then the suspension was poured into the channels and solidified afterwards. To induce GFP production, solutions with different concentrations of arabinose were added to the reservoir on one side of the chips.
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Afterwards, the chips were incubated at 37 °C. Therefore, they were put into a petri dish filled with water. This should prevent evaporation and thus draining of the channels. We further sealed all the entrances to the channels for the same reason and also to avoid accidential dilution of arabinose in the reservoir.
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Samples were taken after regular time periods. Pictures were taken by using a fluorescence microscope with an ecitation wavelength of 480 nm and an emission wavelength of 510 nm. As visible in figure 3 and 4, a gradient in GFP fluorescence could be observed as expected.
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Thus we successfully designed a PDMS channel which is compatible with the SmoColi system, allowing us to do time course measurements with a fluorescence microscope over a longer span of time without risking to drain the channel.
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[[File:ETHZ_arabinose_gradient.png|500px|center|thumb|'''Figure 5: Proof of principle''', arabinose-inducible GFP gradient created in the microfluidic PDMS device.]]
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= References =
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<span id="Ref1">[1] [http://www.elveflow.com/microfluidic/16-start-with-microfluidic http://www.elveflow.com/microfluidic/16-start-with-microfluidic]</span>
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<span id="Ref2">[2] [http://www.springerlink.com/content/q744ww56gvg05753/#section=91916&page=1 '''Microfluidic Techniques: Reviews and Protocols''', Shelley D. Minteer,<br> '''Chapter 3: Fabrication of Polydimethylsiloxane Microfluidics Using SU-8 Molds''', Rabih Zaouk, Benjamin Y. Park and Marc J. Madou]</span>
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<span id="Ref3">[3] [http://mic.sgmjournals.org/content/147/12/3241/F4.expansion.html A. Khlebnikov, K. Datsenko, T. Skaug, B. Wanner and J. Keasling: Homogeneous expression of the PBAD promoter in Escherichia coli by constitutive expression of the low-affinity high-capacity AraE transporter, Microbiology, 2001, (147): 3241–3247]</span>
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Latest revision as of 01:56, 29 October 2011

Can you feel the smoke tonight?
 

Contents

Final Setup and Validation

This page presents description of our final channel design as well as description of its construction, which we did by ourselves. Our final channel is built out of polydimethylsiloxane (PDMS) and constructed with a technique called photolithography. Finally we performed some experiments in the channel in order to validate our design.

Final Channel Design

Figure 1: Final design of our microfluidic chips containing the channels. The three chips differ in shape and dimensions


On the left is the design of our final microfluidic devices, which we made out of polydimethylsiloxane (PDMS). The three chips differ between themselves in their shape and dimensions. On the left side of the chips, each design has a reservoir attached to one end of the channels.


Dimensions of the chips:

  • The size of the first two chips is 15 x 33 mm, the size of the last one is 23 x 46 mm.
  • The width of the channels is either 0.5 or 1 mm
  • Channel length:

- Large chip: (from top to bottom) 30 mm, 15 mm and ca. 60 mm
- Small chip: all 20mm



Final Channel Construction

To construct the microfluidic channels, we used the technique photolithography. Photolithography is done by photopatterning of structures by using a mask (drawing of channels in 2D) and is based on the utilization of particular substances (photoresists) that become soluble to particular solvents after being exposed to UV light [1].

Hereafter a brief description of the photolithography technique: [2]

First, a mask for the microfluidic devices is made by printing the design on glass or quartz or simply on a regular transparency. Then, an SU-8 negative photoresist is spun onto a Si wafer until the final thickness of the photoresist is achieved. The transparency photomask is placed over the Si waver coated with photoresist and the photoresist is exposed to UV light, after which a postexposure bake is performed to crosslink selectively the exposed portions of the photoresist causing the solidification of the material. The sample is put in a beaker containing SU-8 developer to remove the unexposed SU-8. After the sample containing the exposed SU-8 only is is taken out of the baker and dried, PDMS is applied over the SU-8 mold and allowed to cure. SU-8 is removed and a glass is bounded to the PDMS. The channels are constructed. You can read more about the technique here.

Figure 2: The process of designing the microfluidic devises. Graphic taken from [2]


You can see below some photos of the channel building process:

Figure 3: Fabrication of the PDMS channel


Setup Validation

Figure 4: arabinose-induced GFP production in a 30 mm channel. The system was induced with a 1 %w/v arabinose solution in the reservoir on the left side of the channel. Pictures were taken 5 h after induction.

To test the different PDMS channels, we engineered an arabinose-dependent sfGFP reporter plasmid, with which e.coli BW27783 strain [3] was transformed. A liquid preculture was grown until an OD600 of 1 was reached. Cells then were diluted by 1/5 in LB and 15 %w/v agar was added to the suspension. Then the suspension was poured into the channels and solidified afterwards. To induce GFP production, solutions with different concentrations of arabinose were added to the reservoir on one side of the chips.

Afterwards, the chips were incubated at 37 °C. Therefore, they were put into a petri dish filled with water. This should prevent evaporation and thus draining of the channels. We further sealed all the entrances to the channels for the same reason and also to avoid accidential dilution of arabinose in the reservoir. Samples were taken after regular time periods. Pictures were taken by using a fluorescence microscope with an ecitation wavelength of 480 nm and an emission wavelength of 510 nm. As visible in figure 3 and 4, a gradient in GFP fluorescence could be observed as expected.


Thus we successfully designed a PDMS channel which is compatible with the SmoColi system, allowing us to do time course measurements with a fluorescence microscope over a longer span of time without risking to drain the channel.


Figure 5: Proof of principle, arabinose-inducible GFP gradient created in the microfluidic PDMS device.


References

[1] [http://www.elveflow.com/microfluidic/16-start-with-microfluidic http://www.elveflow.com/microfluidic/16-start-with-microfluidic]

[2] [http://www.springerlink.com/content/q744ww56gvg05753/#section=91916&page=1 Microfluidic Techniques: Reviews and Protocols, Shelley D. Minteer,
Chapter 3: Fabrication of Polydimethylsiloxane Microfluidics Using SU-8 Molds, Rabih Zaouk, Benjamin Y. Park and Marc J. Madou]

[3] [http://mic.sgmjournals.org/content/147/12/3241/F4.expansion.html A. Khlebnikov, K. Datsenko, T. Skaug, B. Wanner and J. Keasling: Homogeneous expression of the PBAD promoter in Escherichia coli by constitutive expression of the low-affinity high-capacity AraE transporter, Microbiology, 2001, (147): 3241–3247]


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