Difference between revisions of "Team:Washington"
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<h2> Lab on a Strip: Developing a Novel Platform for Yeast Biosensors </h2> | <h2> Lab on a Strip: Developing a Novel Platform for Yeast Biosensors </h2> | ||
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<h2>Overview </h2> | <h2>Overview </h2> | ||
<p>Biosensors for detecting small molecules have many applications in medicine, food, and the environment. Our project aims to combine the emerging fields of synthetic biology and paper diagnostics to create an affordable and accessible platform for a new class of biological sensors that could detect a wide variety of molecules. We first developed a paper microfluidic device housing Saccharomyces cerevisiae, which was then modified to accommodate two different biological detection systems. In one system, the Auxin/IAA-Degron pathway is used in conjunction with beta-galactosidase to produce a visible signal in response to the plant hormone auxin. In the other system, aptazymes, a combination of RNA aptamers and ribozymes, are used to bind theophylline and allow fluorescent protein to be produced. Both pathways serve as models for future real-world applications of our device, including the detection of marine biotoxins in the Pacific Northwest. </p> | <p>Biosensors for detecting small molecules have many applications in medicine, food, and the environment. Our project aims to combine the emerging fields of synthetic biology and paper diagnostics to create an affordable and accessible platform for a new class of biological sensors that could detect a wide variety of molecules. We first developed a paper microfluidic device housing Saccharomyces cerevisiae, which was then modified to accommodate two different biological detection systems. In one system, the Auxin/IAA-Degron pathway is used in conjunction with beta-galactosidase to produce a visible signal in response to the plant hormone auxin. In the other system, aptazymes, a combination of RNA aptamers and ribozymes, are used to bind theophylline and allow fluorescent protein to be produced. Both pathways serve as models for future real-world applications of our device, including the detection of marine biotoxins in the Pacific Northwest. </p> | ||
− | < | + | <p>For commercial shellfish farmers and recreational hunters alike, marine biotoxins pose a significant threat to health and welfare. With this project, we aim to create an inexpensive and easy-to-use test kit for the detection of the shellfish toxin okadaic acid using engineered yeast strains and DNA aptamers on a paper device. We also hope that this project paves the way for a new class of biosensors capable of detecting a wide range of small molecules. </p> |
− | <p>......</p> | + | <h2>What is the context of this research? </h2> |
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+ | <p>Marine toxins are an increasing problem in Washington State waters. Produced in high concentrations by microorganisms during algae blooms, they are ingested by filter-feeding shellfish, causing illness and death in human consumers. Biotoxins are also difficult to detect; contrary to popular belief, algal blooms are not always the striking crimson of “red tides.” Thus, blooms may not be discovered until after a poisoned shellfish is found. The Washington State Department of Health and commercial shellfish farmers conduct periodic surveys of local beaches to catch contaminations early, but these methods are costly, time-consuming, and not always effective. This can especially pose a dilemma for individual shellfish hunters, who do not have the resources to screen their shellfish for toxins. </p> | ||
+ | <h2>What is the significance of this project? </h2> | ||
+ | <p>Our project aims to combine the emerging fields of synthetic biology and paper diagnostics to create an affordable, accessible, and accurate diagnostic test kit that would allow farmers and the public to test shellfish for common biotoxins. This “lab on a strip” will be a critical step forward in marine toxin detection, as it will cut nearly 20 hours off the time needed to obtain results, allowing farmers to screen at a lower cost and empowering individual hunters to confirm the safety of their shellfish. This is also the first project to attempt to grow yeast on a paper device, and if successful, could open the door to a wide range of similar biosensors. Such sensors would have applications in medicine, food, and the environment worldwide. </p> | ||
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Revision as of 16:30, 7 September 2015
Lab on a Strip: Developing a Novel Platform for Yeast Biosensors
Overview
Biosensors for detecting small molecules have many applications in medicine, food, and the environment. Our project aims to combine the emerging fields of synthetic biology and paper diagnostics to create an affordable and accessible platform for a new class of biological sensors that could detect a wide variety of molecules. We first developed a paper microfluidic device housing Saccharomyces cerevisiae, which was then modified to accommodate two different biological detection systems. In one system, the Auxin/IAA-Degron pathway is used in conjunction with beta-galactosidase to produce a visible signal in response to the plant hormone auxin. In the other system, aptazymes, a combination of RNA aptamers and ribozymes, are used to bind theophylline and allow fluorescent protein to be produced. Both pathways serve as models for future real-world applications of our device, including the detection of marine biotoxins in the Pacific Northwest.
For commercial shellfish farmers and recreational hunters alike, marine biotoxins pose a significant threat to health and welfare. With this project, we aim to create an inexpensive and easy-to-use test kit for the detection of the shellfish toxin okadaic acid using engineered yeast strains and DNA aptamers on a paper device. We also hope that this project paves the way for a new class of biosensors capable of detecting a wide range of small molecules.
What is the context of this research?
Marine toxins are an increasing problem in Washington State waters. Produced in high concentrations by microorganisms during algae blooms, they are ingested by filter-feeding shellfish, causing illness and death in human consumers. Biotoxins are also difficult to detect; contrary to popular belief, algal blooms are not always the striking crimson of “red tides.” Thus, blooms may not be discovered until after a poisoned shellfish is found. The Washington State Department of Health and commercial shellfish farmers conduct periodic surveys of local beaches to catch contaminations early, but these methods are costly, time-consuming, and not always effective. This can especially pose a dilemma for individual shellfish hunters, who do not have the resources to screen their shellfish for toxins.
What is the significance of this project?
Our project aims to combine the emerging fields of synthetic biology and paper diagnostics to create an affordable, accessible, and accurate diagnostic test kit that would allow farmers and the public to test shellfish for common biotoxins. This “lab on a strip” will be a critical step forward in marine toxin detection, as it will cut nearly 20 hours off the time needed to obtain results, allowing farmers to screen at a lower cost and empowering individual hunters to confirm the safety of their shellfish. This is also the first project to attempt to grow yeast on a paper device, and if successful, could open the door to a wide range of similar biosensors. Such sensors would have applications in medicine, food, and the environment worldwide.