Team:Grenoble-EMSE-LSU/Project/Modelling/Density

From 2013.igem.org

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<p>In this first figure, the density of living cells $C(t)$ is displayed in $OD_{600} units. When the light intensity is too strong, all bacteria die, when it is too weak, they grow exponentially. A particular value of the light intensity allows to get a constant density of living cells. Note that this light intensity {I*} should be precisely regulated, since 10% increase or decrease around this particular light intensity will result in a X% decrease or increase of the living cell density after 10h. </p>
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<p id="AliveCells">In this first figure, the density of living cells $C(t)$ is displayed in $OD_{600} units. When the light intensity is too strong, all bacteria die, when it is too weak, they grow exponentially. A particular value of the light intensity allows to get a constant density of living cells. Note that this light intensity {I*} should be precisely regulated, since 10% increase or decrease around this particular light intensity will result in a X% decrease or increase of the living cell density after 10h. </p>
<center><img src="https://static.igem.org/mediawiki/2013/2/2c/Control_3_cells.png"></center>
<center><img src="https://static.igem.org/mediawiki/2013/2/2c/Control_3_cells.png"></center>
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<h2 id=MCBP">Method to Control a Bacterial Population</h2>
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<h2 id=MCBP">Heuristic method to Control the density of living cells in a bacterial population</h2>
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<p>When the model's parameters were <a href="https://2013.igem.org/Team:Grenoble-EMSE-LSU/Project/Modelling/Parameters#Results">calculated</a>, it appeared that some of them ($b$, $k$ and $l$) were very variable, their value depended a lot on the preparation of the experiment. Sadly, it is important that they are the more accurate possible, the quality of the predictions depend greatly on them. That is the reason why those 3 parameters shall be slightly modified for each experiment.</p>
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<p>We previously <a href="https://2013.igem.org/Team:Grenoble-EMSE-LSU/Project/Modelling/Parameters#Results">observed</a> that some of the parameters of our model ($b$, $k$ and $l$) were quite variable, from experiment to experiment. Since the quality of the predictions greatly depends on them, it is important to determine them accurately. We therefore designed a procedure to obtain them during each experiment.</p>
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<p>$1$ A first period of approximately 100 minutes without illumination to let the bacteria grow and produce KillerRed.<p>
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<p>$2$ A second one with an illumination at maximal intensity. As the effects of light appear, it becomes possible to improve the fit of the volatile parameters ($b$, $k$ and $l$). The length of this period depends on the precision wanted for the parameters: the more it lasts, the more the effects of ligth are obvious, and the more the improvement of the fit is efficient.</p>
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<p>$1$ Cells are first incubated in the dark during a first period of approximately 100 minutes without illumination to let the bacteria grow and produce KillerRed.<p>
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<p> These two first steps are also essential, according to the model, to accelerate the apparition of the level of the amount of living bacteria. If the light of stabilization is switched on from the beginning, the level will appear after 8 hours. But if bacteria are exposed to an important intensity, they will stabilized quicker.</p>
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<p>$3$ Once the parameters are chosen, the model is used to determinate the light intensity that will stabilised our system.</p>
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<p>$2$ During a second period, the cell suspension was illuminated at maximal intensity ($I=1). This makes it possible to determine precisely the capricious parameters ($b$, $k$ and $l$). The length of this period depends on the precision wanted for the parameters: the longer it lasts, the largest the effects of light are, and more efficiently is the fit improved.</p>
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<p>$4$ The third step passed, the model and its parameters are fixed. But the light intensity still can be modified to control the system if its measured values are drifting away from the trajectory calculated.</p>
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<p>$3$ Once the parameters are chosen, the model is used to determinate the light intensity predicted to stabilize our system.</p>
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<p>$4$ At this stage, the parameters of the model are fixed. But the light intensity can still be modified to better control the system when the measured values are drifting away from the trajectory calculated. This stabilization could be automatically performed by the model predictive control. We instead run our model to determine changes to apply to the light intensity to reach the desired cell density value</p>
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<p>It is not already the model predictive control, it is the first way to stabilize safely and quickly the population of living bacteria. This experimement is the one used as a <a href="https://2013.igem.org/Team:Grenoble-EMSE-LSU/Project/Validation">proof of concept</a>.</p>
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<p>Another fact should be take into consideration. We want to stabilize the living cell density in the minimum time, because otherwise the cell culture may become contaminated or run out of nutrients.  We empirically observed that the two first steps of our procedure are essential to speed up the stabilization of the living bacteria population. If the light is set at the stabilizing value I* from the beginning, the living cell density stabilizes after 8 hours (see the <a href=#AliveCells">predition of living cells</a>). Exposing the bacteria to a large intensity, then reducing the light, makes the living cell population to stabilize more quickly.</p>

Revision as of 13:15, 3 October 2013

Grenoble-EMSE-LSU, iGEM


Grenoble-EMSE-LSU, iGEM

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