Difference between revisions of "Team:UT-Tokyo/Description"

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           <h2>PROJECT DESCRIPTION</h2>
 
           <h2>PROJECT DESCRIPTION</h2>
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           <p>How do Zebrafish get their stripes? Why do we have only 5 digits on each hand?</p>
            How do Zebrafish get their stripes? Why do we have only 5 digits on each hand?
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     <p>Here's one possible answer: Turing Pattern.</p>
          <p>
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          Here's one possible answer: Turing Pattern.
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     <p>Turing Pattern is a type of spatial pattern suggested by the British mathematician Alan Turing . He proposed that these patterns      could be created by the network of two chemicals which have different diffusion rate. These two molecules are called the activator      and inhibitor.</p>
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     <p>Because of its simplicity, the theory has attracted scientists in many fields, and thus various research has been carried out in      the last 60 years. However, it was not easy to prove directly if those patterns are produced by the reaction-diffusion systems or      another mechanism because living systems are so complex.</p>
          Turing Pattern is a type of spatial pattern suggested by the British mathematician Alan Turing.
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          He proposed that these patterns could be created by the network of two chemicals which have different diffusion rate. These two molecules are called the activator and inhibitor.
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     <p>We therefore reconstructed a Turing system using two advantages of synthetic biology; simplicity and controllability. We designed a controllable system for pattern formation by creating spacial differences of <i>E. coli</i> concentrations by controlling their  growth rate. This project leads to further understanding of Turing Pattern, especially characteristics of Turing Pattern generated      by genetic circuits. It points the way to understanding of development of living things, and can be applied to tissue regeneration.</p>
          </p>
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          <p>
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     <p>Now, the new door of synthetic biology has opened and awaits you to come in!</p>
          Because of its simplicity, the theory has attracted scientist in many fields, and thus various research has been carried out in the last 60 years.
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          However, it was not easy to prove directly if those patterns are produced by the reaction-diffusion systems or another mechanism.
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          Living systems are so complex that most research was exclusively theoretical. Biologists still face a big problem: identification of proper molecules acting as activator and inhibitor.
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          <p>
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          We therefore reconstructed a Turing system using two advantages of synthetic biology; controllability and biological directness.
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          By letting whole <i>E. Coli</i> cells, whose motility were controlled, communicate with each other, we succeeded in making the whole system work more identically than any previous researches.
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          This project should surely be a great step for understanding more about morphology and some other related fields of science.
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          Now, the new door of synthetic biology has opened and awaits you to come in!
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Revision as of 09:06, 13 November 2015

PROJECT DESCRIPTION

How do Zebrafish get their stripes? Why do we have only 5 digits on each hand?

     

Here's one possible answer: Turing Pattern.

     

Turing Pattern is a type of spatial pattern suggested by the British mathematician Alan Turing . He proposed that these patterns      could be created by the network of two chemicals which have different diffusion rate. These two molecules are called the activator      and inhibitor.

     

Because of its simplicity, the theory has attracted scientists in many fields, and thus various research has been carried out in      the last 60 years. However, it was not easy to prove directly if those patterns are produced by the reaction-diffusion systems or      another mechanism because living systems are so complex.

     

We therefore reconstructed a Turing system using two advantages of synthetic biology; simplicity and controllability. We designed a controllable system for pattern formation by creating spacial differences of E. coli concentrations by controlling their  growth rate. This project leads to further understanding of Turing Pattern, especially characteristics of Turing Pattern generated      by genetic circuits. It points the way to understanding of development of living things, and can be applied to tissue regeneration.

     

Now, the new door of synthetic biology has opened and awaits you to come in!