Team:EPF Lausanne/Microfluidics/Designing

From 2014.igem.org

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<p>Control layer design & Flow layer design.</p>
<p>Control layer design & Flow layer design.</p>
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<p>Both layers overlapped.</p>
<p>Both layers overlapped.</p>
<p class="lead">Aim of SmashColi: To be able to separate the chip in 4 different compartments and apply 4 different pressure on each row of chambers.</p>
<p class="lead">Aim of SmashColi: To be able to separate the chip in 4 different compartments and apply 4 different pressure on each row of chambers.</p>
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<img src="https://static.igem.org/mediawiki/2014/0/06/Microfdes6.png" width="50%" class="pull-right">
<h3>BioPad: Final Device</h3>
<h3>BioPad: Final Device</h3>
<p class="lead">For our final device, the idea was to have a large sized microfluidic chip where the cells can grow in chambers, each chambers will act as a ‘pixel’. </p>
<p class="lead">For our final device, the idea was to have a large sized microfluidic chip where the cells can grow in chambers, each chambers will act as a ‘pixel’. </p>
<p class="lead">The design is pretty simple, consisting of only a flow layer.</p>
<p class="lead">The design is pretty simple, consisting of only a flow layer.</p>
<p class="lead">NB - the white circle is the size of a 4inch wafer.</p>
<p class="lead">NB - the white circle is the size of a 4inch wafer.</p>
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<img src="https://static.igem.org/mediawiki/2014/0/06/Microfdes6.png" width="50%">
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Revision as of 20:28, 11 October 2014



DESIGNING A CHIP

The creation of the SmashColi


When we started microfluidic experiments, the experiments required flowing cells in chambers and exposing them to different solutions and so we used the chip that was already available to us : the MITOMI chip.

However for our project, where mechanical pressure will induce our touch sensitive bacteria, we thought of designing a new chip with bigger chamber (to increase the emission of the signal per chamber) and to add ‘huge buttons’ above the chambers to enable us to ‘squish the cells’, thus the SmashColi was designed.

This chip is able to separate the array of chambers in 4, permitting us to flow in different cells and different solutions on one chip. Additionally, an input was designated for every 7 columns of buttons allowing us to put 4 different pressures on each row of cells. One row out of two was deprived of buttons to be used as a negative control. With all of this in mind, one chip is able to have 4 different cells and for each type of cells 4 pressures can be applied on them giving a total of 16 different experiments on just one chip!

You may wonder why we didn’t just have chambers and press on the chip with a pen or our finger. Well the possibility of the SmashColi is that by applying the pressure through a machine, it is possible to quantify how the cells react towards a specific pressure. Once the cells were ready we would be able to quantify the intensity of the signal based on the pressure applied to them.

Control layer design & Flow layer design.

Both layers overlapped.

Aim of SmashColi: To be able to separate the chip in 4 different compartments and apply 4 different pressure on each row of chambers.

BioPad: Final Device

For our final device, the idea was to have a large sized microfluidic chip where the cells can grow in chambers, each chambers will act as a ‘pixel’.

The design is pretty simple, consisting of only a flow layer.

NB - the white circle is the size of a 4inch wafer.

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