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| - | For the 2008 iGEM competition, the Imperial team is designing a biofabricator using the Gram-positive bacterium ''Bacillus subtilis'' as our chassis. We will exert fine control over its movement via a recently-discovered clutch mechanism, using light as our stimulus to localise the bacteria. We then intend to trigger production and secretion of a self-assembling biomaterial in a set 3D pattern. | + | {{Imperial/Box1||For the 2008 iGEM competition, the Imperial team is designing a biofabricator using the Gram-positive bacterium ''Bacillus subtilis'' as our chassis. We will exert fine control over its movement via a recently-discovered clutch mechanism, using light as our stimulus to localise the bacteria. We then intend to trigger production and secretion of a self-assembling biomaterial in a set 3D pattern. |
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| - | 3D bio-scaffold materials have many applications in tissue engineering. Our blue-sky aim is to synthesise a precise biofabricator that can accelerate tissue engineering processes, hence making a contribution to the field of regenerative medicine. | + | 3D bio-scaffold materials have many applications in tissue engineering. Our blue-sky aim is to synthesise a precise biofabricator that can accelerate tissue engineering processes, hence making a contribution to the field of regenerative medicine.}} |
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Revision as of 11:21, 26 September 2008
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| Welcome to the Imperial 2008 iGEM project page. It's Sunday, May 19 and a great day to read about an awesome iGEM project!
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For the 2008 iGEM competition, the Imperial team is designing a biofabricator using the Gram-positive bacterium Bacillus subtilis as our chassis. We will exert fine control over its movement via a recently-discovered clutch mechanism, using light as our stimulus to localise the bacteria. We then intend to trigger production and secretion of a self-assembling biomaterial in a set 3D pattern.
3D bio-scaffold materials have many applications in tissue engineering. Our blue-sky aim is to synthesise a precise biofabricator that can accelerate tissue engineering processes, hence making a contribution to the field of regenerative medicine.
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This diagram gives an overview of how our system works. Initially, B. subtilis are motile and are not producing biomaterials. If we want to construct an "I" shaped 3D bio-scaffold, we shine a 3D hologram of the correct wavelength (red is used as an arbitrary example here) onto the growth medium.
Bacteria will sense that light and start to produce a clutch molecule. The clutch disengages the flagella from the motor quite quickly, rendering the subtilis stationary. Coupled with the clutch is a gene for expression for biomaterial synthesis. Should any individuals stray from the correct area, the clutch should disengage and material synthesis should stop.
We hope to build up our bio-scaffold material pixel by pixel in the defined area - the basis of our 3D biofabrication process.
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Please continue on to our project pages - you may want to start with our >>> Project Specifications >>>...
Imperial's 2008 iGEM team has received sponsorship from a number of generous companies...
   
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