Team:Yale

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What does it take to make bacteria produce an electrical circuit? One of the most exciting uses for synthetic biology is in the design of biological systems that can replace and improve industrial processes. By achieving industrial goals using biological processes, we predict dramatic reductions in economic and environmental manufacturing costs. Our project is a first step towards biologically synthesized electronic circuits. Based on precedence of naturally redox-capable bacteria, we generated a system in E. coli that reduces metal in solution. Depending on the application, this system has the ability to form a conductive copper sulfide that can be localized with high precision. In the future our bacteria could catalyze metal deposition to form electrical circuits of any desired dimension and complexity.
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    What would it take to make bacteria produce an electrical circuit? One of the most exciting uses for synthetic biology is in the design of biological systems that can replace and improve industrial processes. By achieving industrial goals using biological processes, we predict dramatic reductions in economic and environmental manufacturing costs. Our project is a first step towards biologically synthesized electronic circuits. Based on precedence of naturally redox-capable bacteria, we generated a system in E. coli that reduces metal in solution. Depending on the application, this system has the ability to form a conductive copper sulfide that can be localized with high precision. In the future our bacteria could catalyze metal deposition to form electrical circuits of any desired dimension and complexity.
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<a id="nav" href="https://2010.igem.org/Team:Yale/Our Project"> >> to learn more about our project: </a>
<a id="nav" href="https://2010.igem.org/Team:Yale/Our Project"> >> to learn more about our project: </a>
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A first year entrant to the iGEM competition, our team is comprised of students from a wide range of backgrounds, talents, and experience. Membership in Yale's iGEM includes seniors, juniors, and sophomores in a variety of disciplines that are connected by a passion for synthetic biology and its applications. After many discussion and wetlab sessions (and much help from our advisors!), our team has both successfully created its copper-depositing bacteria, and had a blast doing it!
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A first year entrant to the iGEM competition, our team is comprised of students from a wide range of backgrounds connected by a common passion for synthetic biology and its applications. After much brainstorming and many wetlab sessions, our team has succeeded in developing a genomic platform for bacterial circuit construction.

Latest revision as of 17:49, 27 October 2010

iGEM Yale

welcome to igem yale

What would it take to make bacteria produce an electrical circuit? One of the most exciting uses for synthetic biology is in the design of biological systems that can replace and improve industrial processes. By achieving industrial goals using biological processes, we predict dramatic reductions in economic and environmental manufacturing costs. Our project is a first step towards biologically synthesized electronic circuits. Based on precedence of naturally redox-capable bacteria, we generated a system in E. coli that reduces metal in solution. Depending on the application, this system has the ability to form a conductive copper sulfide that can be localized with high precision. In the future our bacteria could catalyze metal deposition to form electrical circuits of any desired dimension and complexity. >> to learn more about our project:

Applications
about us

A first year entrant to the iGEM competition, our team is comprised of students from a wide range of backgrounds connected by a common passion for synthetic biology and its applications. After much brainstorming and many wetlab sessions, our team has succeeded in developing a genomic platform for bacterial circuit construction. >> read more about our team