Team:EPF Lausanne/Hardware

From 2014.igem.org

Hardware



Having successfully engineered touch responsive bacteria, the next major step to build a functional BioPad is to detect and process the emitted signals. The microfluidic chip containing our engineered organisms has the advantage of being small and portable. We aimed to keep these characteristics all along the project. That is why, instead of using a big and cumbersome device to detect signals, we opted for a small and cheap Raspberry Pi. Let the adventure for building the BioPad Detector begin!

Raspberry Pi

Raspberry Pi

The Raspberry Pi is a small and cheap (40.- CHF) single-board computer. The raspberry Pi will be used to monitor the light emitted by each chamber of the microfluidic chip. We will be able to detect and process all emitted signals through this small device!

When brainstorming how to build the detector, we initially drafted the follwing setup:

Raspberry Pi


As seen in the picture above, the camera is directly linked to the Raspberry Pi and is able to get a clear view of the whole chip. Our final device thus needed a small and high-resolution camera able to easily track signal emission from our touch responsive organisms (including signals emitted in the infrared spectrum).

Raspberry Pi

The camera best suited to the characteristics above was the Raspberry Pi NoIR. The Raspberry Pi NoIR is a 5 MegaPixel, 1080p, 20mm x 25mm x 9mm CMOS camera. It is especially good for low intensity signals. Moreover, NoIR stands for No Infrared Filter, meaning that with this camera we are able to see near infrared wavelength.

The near-infrared spectrum correspond to wavelengths between 700 and 1000nm. We will use the ability of the Raspberry Pi NoIR to detect near-infrared to track the IFP signal emitted by our CpxR - split IFP1.4 stress responsive cells. The emission of IFP in these wavelengths is especially useful for us, as few things emit auto-fluorescence in the infrared spectrum. This drastically increases the precision of our device as it reduces background noise.

Taking into account all the information above, the main idea driving the way we plan to detect signals through our BioPad detector is to collect the entire light spectrum including near infrared wavelengths and then use a filter to eliminate the visible spectrum.


Raspberry Pi Plan

Light tracking

To track the signal dynamics in the chambers via our detector, we wrote a custom C++ code using OpenCV able to specifically detect the exact position of the signal as well as its nature and intensity. The entire code as well as all the supporting files can be found here: https://github.com/arthurgiroux/igemtracking/. An extract of the main code is given here:




Check out the result of our program here:



YCrCb
Representation of the YCrCb color space

To detect the signal, we need to be able to get the information that we need from the pixels. The most common color space used in programming is RGB - pixel colors can be split into three components (Red, Green, and Blue) each taking a value between 0 and 255.

We used another color space, better adapted for this application as we were especially interested in light intensity and color nuances. We therefore chose the YcrCb color space.


In the YCrCb color space, each pixel is decomposed into three components:

  • Y – the luma value (intensity)
  • Cr – the red difference
  • Cb – the blue difference

This allows us to extract the necessary information for our application.

Lenses

The Raspberry Pi camera that we use has a fixed lens which is not adapted to what we want to do, as we cannot change the focus, the aperture or the zoom.

We searched for a different lens which would allow us more control, and found that the easiest way was to remove the initial Raspberry Pi lens, put a CS mount on it and attach a much bigger lens.

The first thing we did was to unplug the camera module from the PCB. Then, the lens was carefully removed by unscrewing it and the new lens was mounted.

Camera


You will then see the camera sensor (CMOS).

Camera


The CS mount was screwed on the board and the lens plugged in.

Camera


You can see here what the lens sees:

Camera

We can clearly see the chambers of the microfluidic chip.

GFP tracking

Once we had our device we wanted to test it with the microfluidic chip and to be as close as possible to the device we wanted at the beggining.

We decided to load some sfGFP on the microfluidic chip and track the emission coming from the chambers.

We did the following installation:

Device


In order to excite the sfGFP we built a little circuit composed of a LED with the right wavelength (470nm) and a resistor to protect the LED from burning out. We used an arduino board to have more control over it.

Device


HSV

With this set-up we retrieved a video of the microfluidic chip illuminated by the LED. To analyze this video we built another OpenCV C++ program that use another different color space named HSV that decompose a pixel into three components, the Hue (color), Saturation (the intensity) and the Value (the brightness).



With this code this is the result that we get:

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