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Project Scope

the ABCs of Automatic Biological Circuit Design

One ultimate goal of synthetic biology is to program complex biological networks that could achieve desired phenotype and produce significant metabolites in purpose of real world application, by fabricating standard components from an engineering-driven perspective. This project explores the application of theoretical approaches to automatically design synthetic complex biological networks with desired functions defined as dynamical behavior and input-output property.

We propose a novel design scheme highlighted in the notion of trade-off that synthetic networks could be obtained by a compromise between performance and robustness. Moreover, series of eligible strategies, which consist of various topologies and possible standard components such as BioBricks, provide multiple choices to facilitate the wet experiment procedure. Description of all feasible solutions takes advantage of SBML and SBGN standard to guarantee extensibility and compatibility.

The Campus

University of Science and Technology of China, or as we abbreviate it for USTC, locates in Hefei, east of China. It's typical subtropic continent climate here, as midsummer could be sizzling while you'll have plenty of snow to expect in winter. Like the higher education in China itself, founded in Sept 20, 1958, USTC is a young campus packed with vigorous and young faces. There are two major parts, the east campus where physical, chemical sciences and SGY locates, and the west campus where we are here endeavoring together for iGEM. Going against the prevailing trend of expanding enrollment, USTC is subject to our pride to be one of the very few USTCers for all these years.

Members of USTC_Software, in front of main building of School of Life Sciences

The main building of School of Life Sciences is among the most advanced and eye-catching buildings on campus. Another reason for young guys' eyes to be caught here is due to the breakdown of USTC's characteristic guy-to-girl ratio here :-). Usually young men here will willingly (or unwillingly, anyways it never matters) leave the front row for ladies in a classroom with a typical capacity of 200 people. However here, inside the life sciences building, Goddess bless it, the ratio almost rises to 2-1! No wonder the Biology Department is always the among majors hardest to get enrolled in.

Automatic Biological Circuits Design

Team Logo: wanna know more about the hinding metaphors and inspirations in this little red square? Click to check out how much fun this year's iGEM has brought us!

Sponsorship

Teaching Affair Office, USTC

School of Life Sicences, USTC

Foreign Affair Office, USTC

Graduate School, USTC

School of Information Science and Technology, USTC

School for the Gifted Young, USTC

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-The ultimate goal of synthetic biology is to program complex biological networks that could achieve desired phenotype and produce significant metabolites in purpose of real world application, by fabricating standard components from an engineering-driven perspective. This project explores the application of theoretical approaches to automatically design synthetic complex biological networks with desired functions defined as dynamical behavior and input-output property.
+One ultimate goal of synthetic biology is to program complex biological networks that could achieve desired phenotype and produce significant metabolites in purpose of real world application, by fabricating standard components from an engineering-driven perspective. This project explores the application of theoretical approaches to automatically design synthetic complex biological networks with desired functions defined as dynamical behavior and input-output property.
 We propose a novel design scheme highlighted in the notion of trade-off that synthetic networks could be obtained by a compromise between performance and robustness. Moreover, series of eligible strategies, which consist of various topologies and possible standard components such as BioBricks, provide multiple choices to facilitate the wet experiment procedure. Description of all feasible solutions takes advantage of SBML and SBGN standard to guarantee extensibility and compatibility.
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 [[Image:USTC_Software.jpg|right|350px|thumb|Members of USTC_Software, in front of main building of School of Life Sciences]]
-The main biuding of School of Life Sciences is among the most advanced and eye-catching buildings on campus. Another reason for young guys' eyes to be caught here is due to the breakdown of USTC's characteristic guy-to-girl ratio here :-). Usually young men here will willingly (or unwillingly, anyways it never matters) leave the front row for ladies in a classroom with a typical capacity of 200 people. However here, inside the life sciences building, Goddess bless it, the ratio almost rises to 2-1! No wonder the Biology Department is always the among majors hardest to get enrolled in.
+The main building of School of Life Sciences is among the most advanced and eye-catching buildings on campus. Another reason for young guys' eyes to be caught here is due to the breakdown of USTC's characteristic guy-to-girl ratio here :-). Usually young men here will willingly (or unwillingly, anyways it never matters) leave the front row for ladies in a classroom with a typical capacity of 200 people. However here, inside the life sciences building, Goddess bless it, the ratio almost rises to 2-1! No wonder the Biology Department is always the among majors hardest to get enrolled in.
 |}
 |valign = "top"|