Difference between revisions of "Team:Washington/Design"

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<h2>Design</h2>
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<h2>Design of Paper Platform for Yeast Biosensors</h2>
  
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<p>After learning about the problems that Washington State faces in regards to marine biotoxins and the enormous cost of performing toxin screening in the local shellfish industry, we wanted to develop a paper-based biosensor for detecting small molecules, which could later be applied to detecting shellfish toxins. To do this, we first decided to develop a paper platform to house biosensing yeast.</p>
By talking about your design work on this page, there is one medal criterion that you can attempt to meet, and one award that you can apply for. If your team is going for a gold medal by building a functional prototype, you should tell us what you did on this page. If you are going for the <a href="https://2015.igem.org/Judging/Awards#SpecialPrizes">Applied Design award</a>, you should also complete this page and tell us what you did.  
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<p>In order to be considered for the <a href="https://2015.igem.org/Judging/Awards#SpecialPrizes">Best Applied Design award</a> and/or the <a href="https://2015.igem.org/Judging/Awards#Medals">functional prototype gold medal criterion</a>, you must fill out this page.</p>
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<p>This is a prize for the team that has developed a synthetic biology product to solve a real world problem in the most elegant way. The students will have considered how well the product addresses the problem versus other potential solutions, how the product integrates or disrupts other products and processes, and how its lifecycle can more broadly impact our lives and environments in positive and negative ways.</p>
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<p>After talking with experts in the shellfish industry (as described in our Integrated Human Practices page), we developed a set of criteria that our device should meet.  First, the device should be small and portable (no larger than 4cm by 5cm) so that it could be used as a point-of-care diagnostic test.  Secondly, it should be cheap and easy to manufacture (no more than $5 per test strip), without complex machinery or inaccessible materials.  Third, it must have a barrier that protects the yeast from the non-sterile outside conditions, while containing the yeast to prevent spread of genetically engineered organisms into the environment. Lastly, it must be fast (less than three hours), as traditional lab-based detection methods often take 24 to 48 hours.  While the testing time is a property of the biological detection pathway, the other conditions can be met by the paper device itself.</p>
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<p>We constructed the device by cutting strips of heavy-duty filter paper and taping a 1mm sheet of PDMS polymer to either side to act as the yeast containment area.  This basic device was then autoclaved to ensure sterility, and media and biosensing cells were added to the yeast containment area.  A target molecule in solution could then travel up the paper to reach the yeast.  After testing our device with a cell lysis assay and our theophylline detection pathway, we can clearly show that our device is functional.</p>
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<p>This platform is both simple and generalizable, and could be functionalized with a wide variety of yeast biosensors. Such technology, if developed into a commercial product, could therefore have a significant impact on industry, making detection of toxins, pathogens, environmental contaminants, heavy metals, and other molecules much easier and more affordable.  </p>
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<p>With any disposable device, many environmental concerns should be taken into account.  It is important that engineered yeast are not able to grow in the environment after a consumer has disposed of the device housing them.  Thus, any yeast biosensor in our finished product should have a biological killswitch.  Additionally, as we develop our device, we hope to integrate biodegradable materials to cut down on waste.  </p>
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<h2>Demonstration of a Functional Prototype</h2>
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<p>INSERT VIDEO HERE!!!</p>
  
 
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If you are working on art and design as your main project, please join the art and design track. If you are integrating art and design into the core of your main project, please apply for the award by completing this page.
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Revision as of 01:51, 19 September 2015



Design of Paper Platform for Yeast Biosensors

After learning about the problems that Washington State faces in regards to marine biotoxins and the enormous cost of performing toxin screening in the local shellfish industry, we wanted to develop a paper-based biosensor for detecting small molecules, which could later be applied to detecting shellfish toxins. To do this, we first decided to develop a paper platform to house biosensing yeast.



After talking with experts in the shellfish industry (as described in our Integrated Human Practices page), we developed a set of criteria that our device should meet. First, the device should be small and portable (no larger than 4cm by 5cm) so that it could be used as a point-of-care diagnostic test. Secondly, it should be cheap and easy to manufacture (no more than $5 per test strip), without complex machinery or inaccessible materials. Third, it must have a barrier that protects the yeast from the non-sterile outside conditions, while containing the yeast to prevent spread of genetically engineered organisms into the environment. Lastly, it must be fast (less than three hours), as traditional lab-based detection methods often take 24 to 48 hours. While the testing time is a property of the biological detection pathway, the other conditions can be met by the paper device itself.



We constructed the device by cutting strips of heavy-duty filter paper and taping a 1mm sheet of PDMS polymer to either side to act as the yeast containment area. This basic device was then autoclaved to ensure sterility, and media and biosensing cells were added to the yeast containment area. A target molecule in solution could then travel up the paper to reach the yeast. After testing our device with a cell lysis assay and our theophylline detection pathway, we can clearly show that our device is functional.



This platform is both simple and generalizable, and could be functionalized with a wide variety of yeast biosensors. Such technology, if developed into a commercial product, could therefore have a significant impact on industry, making detection of toxins, pathogens, environmental contaminants, heavy metals, and other molecules much easier and more affordable.



With any disposable device, many environmental concerns should be taken into account. It is important that engineered yeast are not able to grow in the environment after a consumer has disposed of the device housing them. Thus, any yeast biosensor in our finished product should have a biological killswitch. Additionally, as we develop our device, we hope to integrate biodegradable materials to cut down on waste.

Demonstration of a Functional Prototype

INSERT VIDEO HERE!!!