Team:Exeter
From 2013.igem.org
(Difference between revisions)
Line 5: | Line 5: | ||
== Creating the World's First Full Colour Biocamera == __NOTOC__ | == Creating the World's First Full Colour Biocamera == __NOTOC__ | ||
- | <div style="text-align: | + | <div style="text-align: right;"> |
[[File:Paint_by_coli.png|right|300px|]] Exeter iGEM 2013 are a team comprising of 11 second year undergraduates from the colleges of Engineering, Physics and Biological sciences. Together we plan to engineer E. coli to detect red, green and blue light and produce the correct mix of cyan, magenta and yellow pigments to accurately recreate an exposed image. Our project aims to build a foundation for the precise optical control of biological systems using multiple wavelength light. This has potential in material manufacturing, imaging and will advance our understanding of synthetic biology as a whole. </div> | [[File:Paint_by_coli.png|right|300px|]] Exeter iGEM 2013 are a team comprising of 11 second year undergraduates from the colleges of Engineering, Physics and Biological sciences. Together we plan to engineer E. coli to detect red, green and blue light and produce the correct mix of cyan, magenta and yellow pigments to accurately recreate an exposed image. Our project aims to build a foundation for the precise optical control of biological systems using multiple wavelength light. This has potential in material manufacturing, imaging and will advance our understanding of synthetic biology as a whole. </div> | ||
Revision as of 14:41, 30 September 2013
Creating the World's First Full Colour Biocamera
Exeter iGEM 2013 are a team comprising of 11 second year undergraduates from the colleges of Engineering, Physics and Biological sciences. Together we plan to engineer E. coli to detect red, green and blue light and produce the correct mix of cyan, magenta and yellow pigments to accurately recreate an exposed image. Our project aims to build a foundation for the precise optical control of biological systems using multiple wavelength light. This has potential in material manufacturing, imaging and will advance our understanding of synthetic biology as a whole.