Team:Consort Alberta/project

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Our Project

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Our Project

   Introduction      The Science

  

Comparison     Final Result    Modelling

 

 

 

Introduction...

 

     For this season our team is working on expanding and perfecting our project. Our goal is to create a biobrick and a working prototype that will detect levels of xylene, which is linked directly to carcinogens found in petroleum products such as benzene and its derivatives. Our biobrick will create different amounts of fluorescent protein in the presence of xylene bound to xylR. The economy in our rural community is based largely on agriculture and oil and gas industries. Oil spills have detrimental effects on the environment, economy, and general health. This year we will be testing out two different indicators to allow options concerning scale and intensity of colour change. In future years our project will allow early identification of contamination will facilitate rapid clean-up and minimize health risks to members of our community and to the consumers who rely on the food we produce.

 

The Science...

 

Comparison...

 

Final Result...

 

Modelling...

 

PROTOTYPE #1: Our first prototype has a positive pressure creating a current(blue) from the left box and pushing the xylene particles (orange) from the sample in the middle box that holds our E. Coli culture, producing our indicator protein. This was a plausible idea, as it would require fairly non-expensive materials and could be maintained by the average business person. However, we thought it could be more efficient in it's design, and so we kept looking for ideas.

 

PROTOTYPE #2: In a container, we combine our soil sample and our alginate beads, mix them around, and then sift out the beads. The beads produce our indicator protein from the contamination levels of the soil. This design was inspired by the Peking 2013 Team that used alginate encapsulation beads. Their reasoning and justification for using alginate beads stood out to us, as they stated that it was stable and inexpensive and easy to shape and manipulate, such as to impregnate the beads with our structure. Upon further research into the use of these beads, we discovered that this prototype could be more efficient and easier to use then our first prototype that required a few different pieces to the system.