"
Team:Aberdeen Scotland/Notebook
From 2014.igem.org
(Difference between revisions)
| Line 70: | Line 70: | ||
<li><b>Bacterial drones</b><br>Engineering bacteria to carry particular substances to specific locations via manipulation of chemotaxis</li> | <li><b>Bacterial drones</b><br>Engineering bacteria to carry particular substances to specific locations via manipulation of chemotaxis</li> | ||
<li><b>Defrosting streets in winter</b><br>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</li> | <li><b>Defrosting streets in winter</b><br>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</li> | ||
| - | <li><b> | + | <li><b>Light sensor</b><br>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</li> |
| - | <li><b> | + | <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> | + | <li><b>Recycling nappies</b><br>A bacterium which would be able to degrade a filling used in baby nappies</li> |
| - | <li><b> | + | <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> |
| - | <li><b> | + | <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 | + | <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> | + | <li><b>Supplementation of Vitamin C</b><br>Engineering probiotic bacteria to synthesize vitamin C in order to produce Vit. C fortified food products</li> |
| - | <li><b> | + | <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> | + | <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. |
| + | <ol type="i"> | ||
| + | <li>Vibrio cholerae</li> | ||
| + | <li>arsenic</li> | ||
| + | <li>aluminium</li> | ||
| + | <li>fluoride</li> | ||
| + | <li>asbestos</li> | ||
| + | </ol> | ||
| + | </li> | ||
<li><b>Bacterial drones</b><br>Engineering bacteria to carry particular substances to specific locations via manipulation of chemotaxis</li> | <li><b>Bacterial drones</b><br>Engineering bacteria to carry particular substances to specific locations via manipulation of chemotaxis</li> | ||
<li><b>Bacterial drones</b><br>Engineering bacteria to carry particular substances to specific locations via manipulation of chemotaxis</li> | <li><b>Bacterial drones</b><br>Engineering bacteria to carry particular substances to specific locations via manipulation of chemotaxis</li> | ||
Revision as of 17:01, 15 October 2014
Before the Poject start
Activities and planning before the start of the project in the summer
Initial brainstorming meetings (February-June)
-
Our initial project ideas:
- Bacterial drones
Engineering bacteria to carry particular substances to specific locations via manipulation of chemotaxis - 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 - 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 - 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 - Recycling nappies
A bacterium which would be able to degrade a filling used in baby nappies - Polyester degradation
Engineering bacteria to degrade polyester and hence enable recycling of polyester based thrash, e.g. margarine packages and yoga mats - 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 - 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. - Supplementation of Vitamin C
Engineering probiotic bacteria to synthesize vitamin C in order to produce Vit. C fortified food products - 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. - Water contamination detectors
Engineered bacteria would sense a presence of one of the following in water and respond via a colour change upon detection.- Vibrio cholerae
- arsenic
- aluminium
- fluoride
- asbestos
- Bacterial drones
Engineering bacteria to carry particular substances to specific locations via manipulation of chemotaxis - Bacterial drones
Engineering bacteria to carry particular substances to specific locations via manipulation of chemotaxis - Bacterial drones
Engineering bacteria to carry particular substances to specific locations via manipulation of chemotaxis - Bacterial drones
Engineering bacteria to carry particular substances to specific locations via manipulation of chemotaxis - Bacterial drones
Engineering bacteria to carry particular substances to specific locations via manipulation of chemotaxis - Bacterial drones
Engineering bacteria to carry particular substances to specific locations via manipulation of chemotaxis - Bacterial drones
Engineering bacteria to carry particular substances to specific locations via manipulation of chemotaxis - Bacterial drones
Engineering bacteria to carry particular substances to specific locations via manipulation of chemotaxis
- Bacterial drones
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.
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.
