Team:TU Darmstadt
From 2014.igem.org
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<h1>E. Grätzel – Solar BioEnergy</h1> | <h1>E. Grätzel – Solar BioEnergy</h1> | ||
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<p>This year the team aims to achieve victory in the championship of synthetic biology by investigating a new approach to produce a plant pigment called Anthocyanin in Escherichia coli (E. coli). This class of pigment not only stains blossoms in blue, violet or red but also is enclosed in fruits and is valued for its antioxidant effect as well as the ability to lower the risks for cancer. | <p>This year the team aims to achieve victory in the championship of synthetic biology by investigating a new approach to produce a plant pigment called Anthocyanin in Escherichia coli (E. coli). This class of pigment not only stains blossoms in blue, violet or red but also is enclosed in fruits and is valued for its antioxidant effect as well as the ability to lower the risks for cancer. | ||
Conventional Anthocyanin production has three major problems: First, the growth of plants depends on agricultural land needed amongst others to grow crops for food production. Secondly, the extraction process includes toxic and environmentally hazardous chemicals like methanol, acetone and sulfur dioxide. Lastly, the high energy costs of the extraction and purification process is economically inefficient. | Conventional Anthocyanin production has three major problems: First, the growth of plants depends on agricultural land needed amongst others to grow crops for food production. Secondly, the extraction process includes toxic and environmentally hazardous chemicals like methanol, acetone and sulfur dioxide. Lastly, the high energy costs of the extraction and purification process is economically inefficient. |
Revision as of 19:11, 15 August 2014
E. Grätzel – Solar BioEnergyProject descriptionThis year the team aims to achieve victory in the championship of synthetic biology by investigating a new approach to produce a plant pigment called Anthocyanin in Escherichia coli (E. coli). This class of pigment not only stains blossoms in blue, violet or red but also is enclosed in fruits and is valued for its antioxidant effect as well as the ability to lower the risks for cancer.
Conventional Anthocyanin production has three major problems: First, the growth of plants depends on agricultural land needed amongst others to grow crops for food production. Secondly, the extraction process includes toxic and environmentally hazardous chemicals like methanol, acetone and sulfur dioxide. Lastly, the high energy costs of the extraction and purification process is economically inefficient.
In the team’s technological approach, the anthocyanin dye can be utilised to build so-called “Grätzel cells”. These electrochemical dye-sensitized solar cells use the produced dye instead of a semiconductor material for the absorption of light. The objective is to investigate an innovative approach for a sustainable energy source; wherever and whenever needed. In the course of the project phase, the team will construct a Grätzel cell testing their dye that was produced in E. coli.
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