Difference between revisions of "Team:GO Paris-Saclay/model"

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<html>

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}

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<html>

+

<body>

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<~~/style>~~

+

−

~~</head~~>

+

−

~~<body>~~

+

−

~~<div class="bannercontainer" >~~

+

−

<img src="https://static.igem.org/mediawiki/2018/1/1b/T--GO_Paris-Saclay--~~tableau_banner~~.png"

+

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~~class~~="~~bannerimg superposedbanner1~~">

+

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~~<img src~~="~~https://static.igem.org/mediawiki/2018/9/90/T--GO_Paris-Saclay--empty-banner.png~~"

+

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~~class~~="~~bannerimg superposedbanner2~~">

+

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~~<div class="headlinetext">Model</div>~~

+

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~~</div~~>

+

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<~~mat-card~~ class="~~dashboard~~-~~card largemargin~~">

+

−

<h1 id="~~Introduction~~">~~Introduction~~</h1>

+

<div>

+

+

</div>

+

<h1 id="titreh1">INTRODUCTION</h1>

−

<~~p class~~="~~withlettrine~~">In order to degrade drugs in hospital wastewater in a sustainable way, our biological system

+

+

In order to degrade drugs in hospital wastewater in a sustainable way, our biological system

split

into two distinct populations with

different biological properties. Specifically the growth of the "stem" cell population may be faster that the

degrader population.

−

Here, degrader cells produce two enzymes, folC and CPG2, which can be lethal in high concentration. ~~<br>~~

+

Here, degrader cells produce two enzymes, folC and CPG2, which can be lethal in high concentration.

−

+

</div>

−

</p>

+

−

<p>We analyse the population dynamics for several scenarios. It could happen in hospital effluents, where drugs

+

+

We analyse the population dynamics for several scenarios. It could happen in hospital effluents, where drugs

release

depend of many parameters like human errors, schedule of health services, etc. Finally, we prove the effectiveness

−

of our system by proving it can degrade drugs in many scenarios.</p>

+

of our system by proving it can degrade drugs in many scenarios.

+

</div>

+

<h1 id="titreh1">MODEL CONSTRUCTION</h1>

−

<h1 id="~~ModelConstruction~~">~~Model construction.~~</h1>

+

<h2 id="titreh2">A first approach : the exponential phase</h2>

+

+

Let's denote $n_1(t)$ the population of degradation cells, $n_2(t)$ the population of "stem" cells and $m(t)$ the

+

quantity of methotrexate in solution.

+

</div>

−

<h2 id="~~AFirstApproach~~"~~>A first approach : the exponential phase</h2>~~

+

−

<p>

+

Let's denote $n_1(t)$ the population of degradation cells, $n_2(t)$ the population of "stem" cells and $m(t)$ the

quantity of methotrexate in solution.

−

</p>

+

</div>

+

+

According to our experiments, and general theoretical consideration, we can write the following reactions :

+

\begin{{ '{' }}array}{{ '{' }}clll}

+

n_1 & \xrightarrow{{ '{' }}r_1} & n_1 & \text{{ '{' }}(degrader cells growth)} \\

+

n_2 & \xrightarrow{{ '{' }}r_2} & n_2 & \text{{ '{' }}("stem" cells growth.)} \\

+

n_1 + m & \xrightarrow{{ '{' }}-A} & n_1 & \text{{ '{' }}(degradation of methotrexate)} \\

+

\star & \xrightarrow{{ '{' }}p} & m & \text{{ '{' }}(methotrexate input)} \\

+

\end{{ '{' }}array} <br>

+

The letter above the arrow is the rate at which the transformation happens. Here, all theses rates are assumed to be

+

positive.

+

</div>

+

+

<p><img src="https://static.igem.org/mediawiki/2018/2/2d/T--GO_Paris-Saclay--tab1bon.png"

+

alt="tableauinterlab">

+

</p>

+

</figure>

+

<p>

According to our experiments, and general theoretical consideration, we can write the following reactions :

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 {{Template:GO_Paris-Saclay/navbarcssgene}}
+{{Template:GO_Paris-Saclay/templatestyle}}
 <html>
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 }
+<html>
+<body>
-</style>
+<div class="container">
-</head>
-<body>
+   <img src="https://static.igem.org/mediawiki/2018/9/9b/T--GO_Paris-Saclay--interlabpage.png" alt="page template gps" width="1000" height="300">
-<div class="bannercontainer" >
-   <img src="https://static.igem.org/mediawiki/2018/1/1b/T--GO_Paris-Saclay--tableau_banner.png"
-       class="bannerimg superposedbanner1">
-  <img src="https://static.igem.org/mediawiki/2018/9/90/T--GO_Paris-Saclay--empty-banner.png"
-       class="bannerimg superposedbanner2">
-  <div class="headlinetext">Model</div>
-</div>
-<mat-card class="dashboard-card largemargin">
+  <div class="topleft"><a href="https://2018.igem.org/Team:GO_Paris-Saclay/JOUDOU3"><img src="https://static.igem.org/mediawiki/2018/0/01/T--GO_Paris-Saclay--logogoparissaclay.png" alt="logoparissaclay"></a></div>
-  <h1 id="Introduction">Introduction</h1>
+<div>
+<img id="carretitrepincipal" src="https://static.igem.org/mediawiki/2018/f/fd/T--GO_Paris-Saclay--carretitreprinci.png" alt="carretitreprinci">
+</div>
+<h1 id="titreh1">INTRODUCTION</h1>
-  <p class="withlettrine">In order to degrade drugs in hospital wastewater in a sustainable way, our biological system
+<div id="paragraphe">
+In order to degrade drugs in hospital wastewater in a sustainable way, our biological system
      split
      into two distinct populations with
      different biological properties. Specifically the growth of the "stem" cell population may be faster that the
      degrader population.
-     Here, degrader cells produce two enzymes, folC and CPG2, which can be lethal in high concentration. <br>
+     Here, degrader cells produce two enzymes, folC and CPG2, which can be lethal in high concentration.
+</div>
-  </p>
-  <p>We analyse the population dynamics for several scenarios. It could happen in hospital effluents, where drugs
+<div id="paragraphe">
+We analyse the population dynamics for several scenarios. It could happen in hospital effluents, where drugs
      release
      depend of many parameters like human errors, schedule of health services, etc. Finally, we prove the effectiveness
-     of our system by proving it can degrade drugs in many scenarios.</p>
+     of our system by proving it can degrade drugs in many scenarios.
+</div>
+<h1 id="titreh1">MODEL CONSTRUCTION</h1>
-  <h1 id="ModelConstruction">Model construction.</h1>
+<h2 id="titreh2">A first approach : the exponential phase</h2>
+<div id="paragraphe">
+    Let's denote $n_1(t)$ the population of degradation cells, $n_2(t)$ the population of "stem" cells and $m(t)$ the
+    quantity of methotrexate in solution.
+</div>
-  <h2 id="AFirstApproach">A first approach : the exponential phase</h2>
+<div id="paragraphe">
-  <p>
      Let's denote $n_1(t)$ the population of degradation cells, $n_2(t)$ the population of "stem" cells and $m(t)$ the
      quantity of methotrexate in solution.
-   </p>
+</div>
+<div id="paragraphe">
+    According to our experiments, and general theoretical consideration, we can write the following reactions :
+    \begin{{ '{' }}array}{{ '{' }}clll}
+    n_1 &amp; \xrightarrow{{ '{' }}r_1} &amp; n_1 &amp; \text{{ '{' }}(degrader cells growth)} \\
+    n_2 &amp; \xrightarrow{{ '{' }}r_2} &amp; n_2 &amp; \text{{ '{' }}("stem" cells growth.)} \\
+    n_1 + m &amp; \xrightarrow{{ '{' }}-A} &amp; n_1 &amp; \text{{ '{' }}(degradation of methotrexate)} \\
+    \star &amp; \xrightarrow{{ '{' }}p} &amp; m &amp; \text{{ '{' }}(methotrexate input)} \\
+    \end{{ '{' }}array} <br>
+    The letter above the arrow is the rate at which the transformation happens. Here, all theses rates are assumed to be
+    positive.
+</div>
+<figure id="figure1">
+   <p><img src="https://static.igem.org/mediawiki/2018/2/2d/T--GO_Paris-Saclay--tab1bon.png"
+    alt="tableauinterlab">
+</p>
+</figure>
    <p>
      According to our experiments, and general theoretical consideration, we can write the following reactions :