Team:Imperial College/Overview
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Through discussions with social scientists and waste management legislators we have discovered that solutions to deal with waste after it has been produced are only part of the solution to the waste issue. This has led us to devise several methods by which we can communicate the need to reduce the production of waste in the first place. | Through discussions with social scientists and waste management legislators we have discovered that solutions to deal with waste after it has been produced are only part of the solution to the waste issue. This has led us to devise several methods by which we can communicate the need to reduce the production of waste in the first place. | ||
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<h1>Collaborations</h1> | <h1>Collaborations</h1> |
Revision as of 13:47, 22 September 2013
Contents |
Overview
Our project has many different aspects and we would like you to see them all. So you do not miss anything here is a brief overview to help you get orientated.
The MAPLE System Modules:
Our project is Plasticity. The project can be divided into 3 modules. Firstly, we designed a waste degradation module, which can be further sub-divided into 3 separate modules. These sub-modules are that of PolyURethane [http://en.wikipedia.org/wiki/Polyurethane PUR] degradation, PolyLactic Acid [http://en.wikipedia.org/wiki/Polylactic_acid PLA] degradation, and Poly-3-HydroxyButyrate [http://en.wikipedia.org/wiki/Polyhydroxybutyrate P3HB] degradation. As many plastic products are produced as mixed plastics, this conglomerate of degradative bacteria will successfully degrade petrochemical plastics and bioplastics. In addition to this, using our second module, we will have bioplastic recycling. We intend to synthesise P3HB, a bioplastic from its constituent monomers, that are in themselves, a byproduct of our degradation pathway. The third is the secretion toolkit. This will incorporate the existing secretion biobricks contained within the registry along with those that we have designed and chemically synthesised. These will be transformed into a plasmid in our chassis, E. coli. This will thus permit any future iGEM team to extract their desired secretion tags for use in their construct. With the addition of characterisation data, this will provide a thorough platform to inform decision making for secretion tags.
Achievements
We have proven that MG1655 can live and flourish in SRF.
A Project for the World Today
We have consulted with many different people and organisations in the course of the project. All have helped shape what we have done. We have spoken to waste recovery companies, bioplastic producers and the waste management team for the Greater London Authority. This has ensured that we are producing an appropriate solution to a genuine problem in a commercially realistic way.
A Project for the World Tomorrow
Technologies change us and we change technologies. We have carefully considered how our system will be received and how it might change with the future needs of society.
Waste management requires more than technological solutions
Through discussions with social scientists and waste management legislators we have discovered that solutions to deal with waste after it has been produced are only part of the solution to the waste issue. This has led us to devise several methods by which we can communicate the need to reduce the production of waste in the first place.
Collaborations
We have collaborated with several different teams throughout the competition.