Team:Aberdeen Scotland/Notebook

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<li><a href="https://2014.igem.org/Team:Aberdeen_Scotland/Safety">Safety</a></li>
<li><a href="https://2014.igem.org/Team:Aberdeen_Scotland/Safety">Safety</a></li>
<li><a href="https://2014.igem.org/Team:Aberdeen_Scotland/Attributions">Attributions</a></li>
<li><a href="https://2014.igem.org/Team:Aberdeen_Scotland/Attributions">Attributions</a></li>
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<li><a href="https://2014.igem.org/Team:Aberdeen_Scotland/Ethics">Ethics & Outreach</a></li>
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<h1>Before the Poject start</h1>
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<h1>Before Poject Start</h1>
<h3>Activities and planning before the start of the project in the summer</h3>
<h3>Activities and planning before the start of the project in the summer</h3>
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<li><b>Tetrodotoxin detector</b><br>Designing a biosensor which would be able to detect lethal concentrations of tetrodotoxin in prepared Fugu fish, allowing a decision whether it is safe to consume</li>
<li><b>Tetrodotoxin detector</b><br>Designing a biosensor which would be able to detect lethal concentrations of tetrodotoxin in prepared Fugu fish, allowing a decision whether it is safe to consume</li>
<li><b>Recycling nappies</b><br>A bacterium which would be able to degrade a filling used in baby nappies</li>
<li><b>Recycling nappies</b><br>A bacterium which would be able to degrade a filling used in baby nappies</li>
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<li><b>Polyester degradation</b><br>Engineering bacteria to degrade polyester and hence enable recycling of polyester based thrash, e.g. margarine packages and yoga mats</li>
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<li><b>Polyester degradation</b><br>Engineering bacteria to degrade polyester and hence enable recycling of polyester based trash, e.g. margarine packages and yoga mats</li>
<li><b>Biological night light</b><br>Engineering plants to express luminescent luciferase in order to create a touch-activated night light for children which wouldn't require electricity</li>
<li><b>Biological night light</b><br>Engineering plants to express luminescent luciferase in order to create a touch-activated night light for children which wouldn't require electricity</li>
<li><b>Bacterial pen</b><br>Filling a pen with bacteria manipulated to synthesize dye. Such a pen would never run out of ink as long as we would feed it with nitrogen and sugar. A water-soluble and insoluble dyes could be synthesized.</li>
<li><b>Bacterial pen</b><br>Filling a pen with bacteria manipulated to synthesize dye. Such a pen would never run out of ink as long as we would feed it with nitrogen and sugar. A water-soluble and insoluble dyes could be synthesized.</li>
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<li><b>Biofilm degradation</b><br>The idea is to engineer bacteria to synthesize an enzyme capable of degrading extracellular polymeric substances which create biofilms. This would ideally reduce biofilm-associated infections by disrupting quorum sensing, decreasing antibiotic resistance in bacteria and increasing their sensitivity to cleaning agents. Engineered bacteria could be incorporated into a toothpaste.</li>
<li><b>Biofilm degradation</b><br>The idea is to engineer bacteria to synthesize an enzyme capable of degrading extracellular polymeric substances which create biofilms. This would ideally reduce biofilm-associated infections by disrupting quorum sensing, decreasing antibiotic resistance in bacteria and increasing their sensitivity to cleaning agents. Engineered bacteria could be incorporated into a toothpaste.</li>
<li><b>Water contamination detectors</b><br>Engineered bacteria would sense a presence of one of the following in water and respond via a colour change upon detection.
<li><b>Water contamination detectors</b><br>Engineered bacteria would sense a presence of one of the following in water and respond via a colour change upon detection.
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<ol type="i">
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<ol type="i">
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<li>Vibrio cholerae</li>
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<li>Vibrio cholerae</li>
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<li>arsenic</li>
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<li>Arsenic</li>
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<li>aluminium</li>
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<li>Aluminium</li>
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<li>fluoride</li>
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<li>Fluoride</li>
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<li>asbestos</li>
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<li>Asbestos</li>
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</ol>
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</li>
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<li><b>Bacterial drones</b><br>Engineering bacteria to carry particular substances to specific locations via manipulation of chemotaxis</li>
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<li><b>Greenhouse gas reduction bacteria</b><br>An anaerobic bacteria that uses NO2 to get Methane and then 'digests' Methane into CO2 and H20. The idea is to get the bacteria to stop at Methane and thus suck it from the atmosphere.</li>
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<li><b>Bacterial drones</b><br>Engineering bacteria to carry particular substances to specific locations via manipulation of chemotaxis</li>
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<li><b>CO Detector bacteria</b><br>Use modified bacteria that is equipped with receptors for CO to signal a high concentration of CO in air. The bacteria could emit light, change colour or other type of signal.</li>
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<li><b>Bacterial drones</b><br>Engineering bacteria to carry particular substances to specific locations via manipulation of chemotaxis</li>
+
<li><b>Computer Bacteria</b><br>Use bacteria that conducts electricity and modify it in a way that it will conduct or not depending on a certain environmental condition. This way, we can make the bacteria mimic a computational process.</li>
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<li><b>Bacterial drones</b><br>Engineering bacteria to carry particular substances to specific locations via manipulation of chemotaxis</li>
+
<li><b>Fire detector bacteria</b><br>Fire detectors work by constantly checking for contamination in the air from smoke particles. They achieve this by flowing a current through a radioactive emitter, which decreases/stops emitting radiation when surrounded by smoke particles. This fall in current, triggers the detector. We could try imitating this behaviour with the electricity conducting bacteria, by making it not able to conduct electricity when smoke particles are with high concentration.</li>
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<li><b>Bacterial drones</b><br>Engineering bacteria to carry particular substances to specific locations via manipulation of chemotaxis</li>
+
<li><b>Bio-deodorant</b><br>A bacteria that would compete with the naturally-occurring skin bacteria by also metabolising secretions but crucially not producing smelly waste products.  We really liked this one and it doesn't seem so far-fetched.</li>
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<li><b>Bacterial drones</b><br>Engineering bacteria to carry particular substances to specific locations via manipulation of chemotaxis</li>
+
<li><b>Contaminated water detector</b><br>Use E.coli to secrete colour in reaction to certain toxins in water. Problematic as in pure water witn only toxin diluted, there is no energy source for the bacteria.</li>
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<li><b>Bacterial drones</b><br>Engineering bacteria to carry particular substances to specific locations via manipulation of chemotaxis</li>
+
<li><b>Break down of oil spills</b><br>Make a bacteria break down oil into non-harmful matter in order to clean up oil spills.</li>
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<li><b>Bacterial drones</b><br>Engineering bacteria to carry particular substances to specific locations via manipulation of chemotaxis</li>
+
<li><b>Reduce saturated fat intake in humans</b><br>Use a similar idea to the previous one, but in this case, bacteria will extract saturated fat from food intake and make it indigestible or the bacteria itself could break it down to something less harmful.</li>
</ol>
</ol>
</li>
</li>
</ul>
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<p>We have worked all summer towards what we hope would turn out to be some peace of mind for a lot of people. The goal is to develop a novel method for diagnosing Trypanosomiasis. A simpler, cheaper alternative to current methods that would be more versatile in developing countries and their remote regions. We wish to create a test that would be portable, endure harsh environmental conditions and most importantly be sensitive to the early stages of the disease.</p>
 
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<p>This would give a lot of unsuspecting sufferers the chance to get diagnosed early. This way they can get cured quickly, before the disease reaches its later stages, when it is virtually incurable.</p>
 
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Latest revision as of 02:38, 18 October 2014

Team:Aberdeen Scotland/Notebook - 2014.ogem.org



Before Poject Start

Activities and planning before the start of the project in the summer


Initial brainstorming meetings (February-June)

  • Our initial project ideas:
    1. Bacterial drones
      Engineering bacteria to carry particular substances to specific locations via manipulation of chemotaxis
    2. Defrosting streets in winter
      To engineer bacteria expressing anti-freeze proteins from an arctic fish in order to provide an alternative for using salt in winter to defrost streets
    3. Light sensor
      Engineering bacteria that would sense the intensity of light in our surrounding and respond when it falls below a certain threshold by producing light (e.g. to keep optimal light levels when reading). Geobacter could be used since it can transmit an electric current
    4. Tetrodotoxin detector
      Designing a biosensor which would be able to detect lethal concentrations of tetrodotoxin in prepared Fugu fish, allowing a decision whether it is safe to consume
    5. Recycling nappies
      A bacterium which would be able to degrade a filling used in baby nappies
    6. Polyester degradation
      Engineering bacteria to degrade polyester and hence enable recycling of polyester based trash, e.g. margarine packages and yoga mats
    7. Biological night light
      Engineering plants to express luminescent luciferase in order to create a touch-activated night light for children which wouldn't require electricity
    8. Bacterial pen
      Filling a pen with bacteria manipulated to synthesize dye. Such a pen would never run out of ink as long as we would feed it with nitrogen and sugar. A water-soluble and insoluble dyes could be synthesized.
    9. Supplementation of Vitamin C
      Engineering probiotic bacteria to synthesize vitamin C in order to produce Vit. C fortified food products
    10. Biofilm degradation
      The idea is to engineer bacteria to synthesize an enzyme capable of degrading extracellular polymeric substances which create biofilms. This would ideally reduce biofilm-associated infections by disrupting quorum sensing, decreasing antibiotic resistance in bacteria and increasing their sensitivity to cleaning agents. Engineered bacteria could be incorporated into a toothpaste.
    11. Water contamination detectors
      Engineered bacteria would sense a presence of one of the following in water and respond via a colour change upon detection.
      1. Vibrio cholerae
      2. Arsenic
      3. Aluminium
      4. Fluoride
      5. Asbestos
    12. Greenhouse gas reduction bacteria
      An anaerobic bacteria that uses NO2 to get Methane and then 'digests' Methane into CO2 and H20. The idea is to get the bacteria to stop at Methane and thus suck it from the atmosphere.
    13. CO Detector bacteria
      Use modified bacteria that is equipped with receptors for CO to signal a high concentration of CO in air. The bacteria could emit light, change colour or other type of signal.
    14. Computer Bacteria
      Use bacteria that conducts electricity and modify it in a way that it will conduct or not depending on a certain environmental condition. This way, we can make the bacteria mimic a computational process.
    15. Fire detector bacteria
      Fire detectors work by constantly checking for contamination in the air from smoke particles. They achieve this by flowing a current through a radioactive emitter, which decreases/stops emitting radiation when surrounded by smoke particles. This fall in current, triggers the detector. We could try imitating this behaviour with the electricity conducting bacteria, by making it not able to conduct electricity when smoke particles are with high concentration.
    16. Bio-deodorant
      A bacteria that would compete with the naturally-occurring skin bacteria by also metabolising secretions but crucially not producing smelly waste products. We really liked this one and it doesn't seem so far-fetched.
    17. Contaminated water detector
      Use E.coli to secrete colour in reaction to certain toxins in water. Problematic as in pure water witn only toxin diluted, there is no energy source for the bacteria.
    18. Break down of oil spills
      Make a bacteria break down oil into non-harmful matter in order to clean up oil spills.
    19. Reduce saturated fat intake in humans
      Use a similar idea to the previous one, but in this case, bacteria will extract saturated fat from food intake and make it indigestible or the bacteria itself could break it down to something less harmful.