Team:Calgary/Project/OurSensor/Prototype

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Prototype

Initial Ideas

When we started thinking about how to turn our project into a product that could be readily used by the beef industry we wanted something that was portable and easy to use. Initial discussions with industry also pointed out that speed was important, as if it took 24 hours to get the result then the infected cow would have already been processed. To get inspiration we went for a walk around our local pharmacy to see what kind of sensors we could buy and explore. As we were walking through the aisles we saw digital and colour change thermometers, pressure based heart rate monitors, blood glucose meters, and pregnancy tests. While the idea of having a digital output was initially interesting to us, we soon realized that the home pregnancy test was one of the easiest and well known sensors with an output that can be understood by anyone. Another bonus was that the designs have already been optimized to use biological molecules as the recognition elements, just like we were planning to do.

With that in mind we sent two of our male advisors (Robert & Iain) to pick out their favourite pregnancy tests. The fruits of their labour can be seen to the right in Figure 1 (they even got two different kinds!).

Playing with Pregnancy Tests

After some very strange looks from our professors, we wanted to disassemble the tests we bought to see what made them tick. Before risking the integrity of the device though, our male prototypers wanted to watch it work, and thankfully the cup of water we dipped it in (no, we didn't get guys to pee on it) was not pregnant. With our curiosity sated we began pulling it apart. The components can be seen below in Figure 2

There were more components than we had expected, with an applicator, transfer wick, nitrocellulose, dragging wick, and a dessicator stone at the end. Through playing with the components we found that the dragging wick (after the nitrocellulose to pull the liquid sample as far as possible) was not completely necessary, but did seem to aid in covering the nitrocellulose. We believe the dessicator is for long term storage of the device, as it played no discernable role in our bench testing.

To test if our system of using ferritin would give us a readable output from a prototype we blotted prussian blue ferritin onto nitrocellulose. We then enclosed the blotted nitrocellulose in one of the pregnancy tests along with the applicator and wicks that came with it before exposing it to the TMB substrate. Unfortunately we didn't see any change after our first test, but after taking it apart to look inside we found that the solution had only flowed through approximately one third of the device. With that in mind we built our second prototype out of another pregnancy test, but this time we shortened the distace by cutting part of the applicator off. The downside of this modification was that the applicator was rendered useless, so filter paper was used to draw the solution into the device instead. In this prototype, shown below, we were able to observe a change in prussian blue ferritin after the addition of the substrate TMB.

Sample Preparation

In order for our test to work we need the DNA to be accessible for our TALEs. Unfortunately, bacteria keep their DNA contained inside their membranes, meaning that we need to lyse the cells in order for our test to work. Most methods that lyse cells either take upwards of 10 minutes, needs human intervention, or involves the use of larger equipment than the industry wants to use (i.e: requiring an electrical outlet). With that in mind we scoured the literature for an alternate method and discovered a paper where the authors lysed bacteria with a brief exposure to electricity (Besant et al., 2013). With that in mind we designed our rudimentary lysis device, shown to the right, that used the electrodes from a broken elecrophoresis setup to electrocute a sample.

To test the lysis capabilities of this device we took 50 µL of an overnight RFP culture and exposed it to 0, 10, 20, 30, or 40 V of electricity from a power pack for 5 seconds. We then plated the electrocuted samples to see if they were capable of growing, but even before the results came in there was a marked change in the appearance of the sample, changing from red and cloudy to clear and yellow. When the cells were grown and exposed to UV light for easy visibility it was noted that only the 0 V and 10 V samples grew, with the 20, 30, and 40 V treatments killing all cells.

Final System Testing

TAYLORS IMAGES AND DATA HERE