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

From 2013.igem.org

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<h3> Third Model</h3>
<h3> Third Model</h3>
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<p> Until now, our equations describe the phototoxic effect of KillerRed as instantaneous: in the presence of light Killer Red produces ROS, which immediately kills a certain proportion of the bacteria but has no lasting effect. It is well-known, however, that cells can repair damages due to ROS, up to a certain level. We can thus consider that bacteria are unable to instantly repair all the damages caused by ROS, and with damages mounting up, they are more and more fragile and close to death. Considering this accumulation allows us to shift the effect of illumination, and so to have a more accurate model.</p>
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<p> Until now, our equations describe the phototoxic effect of KillerRed as instantaneous: in the presence of light Killer Red produces ROS, which immediately kills a certain proportion of the bacteria but has no lasting effect. It is well-known, however, that cells can repair damages due to ROS, up to a certain level. We can thus consider that bacteria are unable to instantly repair all the damages caused by ROS, and with damages mounting up, they are more and more fragile and close to death.In other words, the effect of a certain amount of KR at a certain time $u$, $K(u)$, illuminated by a light intensity $I(u)$, will affect cell growth at time $t$ later than $u$, weighted by a factor $e^{-p(t-u)} that vanishes as $t$ increases. The effect of this ROS production at time $u$ will thus exponentially decrease with time. The term $– kI.K$  (photokilling) was thus replaced by the integral:</p>
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<center style="font-size:150%">
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$-\int_{u=0}^t k'I(u)K(u)e^{-p(t-u)}du$
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</center>
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<p> And the equation of bacterial growth:</p>
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<center style="font-size:150%;">
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$
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\frac{dC}{dt}(t)=rC(t)-\int_{u=0}^t k'I(u)K(u)e^{\ln(l)(t-u)}du
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$
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</center>
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<br>
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<p> There is no analytical solution for this equation. But it is simple to treat it in its discrete-time form.</p>
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<br>
<br>
<p> Written in its discrete-time form, the evolution of $C$ was described by </p>
<p> Written in its discrete-time form, the evolution of $C$ was described by </p>
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</p>
</p>
<br>
<br>
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<p> This new equation can also be written in continuous-time form:</p>
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<center style="font-size:150%;">
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$
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\frac{dC}{dt}(t)=rC(t)-\int_{u=0}^t k'I(u)K(u)e^{\ln(l)(t-u)}du
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$
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<p>Considering this accumulation allows us to shift the effect of illumination, and so to have a more accurate model.</p>
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</center>
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<p> But there is no analytical solution for this equation. We will therefore rely on numerical solutions in what follows.</p>
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<br>
<br>

Revision as of 10:59, 2 October 2013

Grenoble-EMSE-LSU, iGEM


Grenoble-EMSE-LSU, iGEM

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