Team:INSA-Lyon/Modeling

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   <td>Mathematical equations</td>
   <td>Mathematical equations</td>
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   <td>Widely spread, it enables you to efficiently modelise about anything ! </td>
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   <td><div align="justify">Widely spread, it enables one to modelise about anything !</div> </td>
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   <td><font color="red">équation + graphe</font></td>
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   <td><div align="center"><img src="https://static.igem.org/mediawiki/2014/a/a2/CurlyonEquaDiffeq.png" alt="graphe de l'equation" width="325px"/></div></td>
   <td><i>Ugh! No thank you...</i></td>
   <td><i>Ugh! No thank you...</i></td>
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   <td>Numerical simulations</td>
   <td>Numerical simulations</td>
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   <td>Sometimes easier to use, but there may not exist a program yet for what you want to modelise...</td>
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   <td><div align="justify">Sometimes easier to use, but there may not exist a program yet for what you want to modelise...</div></td>
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   <td><font color="red">image sybyl</font></td>
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   <td><div align="center"><img src="https://static.igem.org/mediawiki/2014/4/45/WtFace1.jpg" alt="CsgAWTSybyl" width="280px"/></div></td>
   <td><i>I'm not really good with computers. ^^"</td>
   <td><i>I'm not really good with computers. ^^"</td>
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   <td>Drawings and outlines</td>
   <td>Drawings and outlines</td>
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   <td>A plain drawing is often enough to explain the processes behind a given mechanism without explaining what is happening at every levels, especially in biology !</td>
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   <td><div align="justify">A plain drawing is often enough to explain the processes behind a given mechanism without explaining what is happening at every levels, especially in biology !</div></td>
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   <td><font color="red">schéma mitose</font></td>
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   <td><div align="center"><img src="https://static.igem.org/mediawiki/2014/a/af/CurlyonMitosis.png" alt="schema mitose" width="300px"/></div></td>
   <td><i>OH ! I know this one !</i></td>
   <td><i>OH ! I know this one !</i></td>
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Revision as of 21:17, 13 October 2014

Curly'on - IGEM 2014 INSA-LYON

What is modeling?

Modeling is building and using a model. What is a model then? It is a theoretical way to explain a phenomenon in a simpler fashion than the real thing. It is observing a problem or a phenomenon, identifying what parameters may influence it and sort them out so that only the most important ones are kept, and finally finding out how they are related, in order to explain what happens accurately enough to be able to predict what would happen under different conditions. As such, it can take many shapes. Here are some examples of models:

Mathematical equations
Widely spread, it enables one to modelise about anything !
graphe de l'equation
Ugh! No thank you...
Numerical simulations
Sometimes easier to use, but there may not exist a program yet for what you want to modelise...
CsgAWTSybyl
I'm not really good with computers. ^^"
Drawings and outlines
A plain drawing is often enough to explain the processes behind a given mechanism without explaining what is happening at every levels, especially in biology !
schema mitose
OH ! I know this one !
CurLy'on team's modeling work

As very little litterature exists about curli models, especially about it's structure, this year we chose to work along two directions:
  1. we studied a molecular model of the curlin elementary subunit, CsgA, and it's engineered form;
  2. we developped both a mathematical model describing the polymerisation of CsgA, and a simulation program of the same phenomenon ; our aim was for those two models to serve as a basis for future teams working with curli.