Team:University College London/Research
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= Research = | = Research = | ||
- | == | + | == Background == |
- | + | There are numerous regions of the ocean with an accumulation of micro-plastic pollution. Plastic is estimated to account for 60-80% of marine debris, where the majority accumulate in gyres, centres of subtropical and anti-cyclonic currents. Micro-plastics are a result of release of the plastic waste into the oceans. The waste from Gyres enter the digestive systems of resident organism, which are affected either by the physical size of the plastic or its toxicity from absorbing organic pollutants. | |
+ | |||
+ | == Aim == | ||
+ | Our team came up with three modules that aim to solve the micro-plastic pollution in the marine environment. We are engineering bacteria to be able to detect and aggregate micro-plastics into larger pieces to facilitate removal. <br /> | ||
+ | For the micro-plastics that cannot be aggregated we have an alternative approach which is to degrade the micro-plastics. <br /> | ||
+ | We are pursuing these as three separate modules which we will assemble once we have tested their competence. | ||
+ | |||
+ | == Detection Module == | ||
+ | Receptors based detection is a first step for both aggregation and degradation. The main receptor is human oestrogen receptor that binds to different types of micro-plastics. | ||
+ | |||
+ | == Aggregation Module == | ||
+ | In the case of aggregation, receptors on bacteria detect micro-plastics and induce the production of sticky extensions of cell membrane. First this allows bacteria stick to the plastics and once covered in bacteria allows micro-plastics to stick to one another. | ||
+ | |||
+ | == Degredation Module == | ||
+ | The degradation module, which is separate from aggregation module, also comes after receptor detection. This system metabolizes the micro-plastics and their derivatives that are otherwise toxic to the environment. As a result of degradation these materials are converted into non-toxic ones. | ||
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Revision as of 16:27, 22 June 2012
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Research
Background
There are numerous regions of the ocean with an accumulation of micro-plastic pollution. Plastic is estimated to account for 60-80% of marine debris, where the majority accumulate in gyres, centres of subtropical and anti-cyclonic currents. Micro-plastics are a result of release of the plastic waste into the oceans. The waste from Gyres enter the digestive systems of resident organism, which are affected either by the physical size of the plastic or its toxicity from absorbing organic pollutants.
Aim
Our team came up with three modules that aim to solve the micro-plastic pollution in the marine environment. We are engineering bacteria to be able to detect and aggregate micro-plastics into larger pieces to facilitate removal.
For the micro-plastics that cannot be aggregated we have an alternative approach which is to degrade the micro-plastics.
We are pursuing these as three separate modules which we will assemble once we have tested their competence.
Detection Module
Receptors based detection is a first step for both aggregation and degradation. The main receptor is human oestrogen receptor that binds to different types of micro-plastics.
Aggregation Module
In the case of aggregation, receptors on bacteria detect micro-plastics and induce the production of sticky extensions of cell membrane. First this allows bacteria stick to the plastics and once covered in bacteria allows micro-plastics to stick to one another.
Degredation Module
The degradation module, which is separate from aggregation module, also comes after receptor detection. This system metabolizes the micro-plastics and their derivatives that are otherwise toxic to the environment. As a result of degradation these materials are converted into non-toxic ones.