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

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<p> Our model now considers the maturation of KillerRed and the accumulation of damages done to the bacteria. It is able to describe the evolution of all three quantities that are observed: the optical density of the suspension, its fluorescence and the density of living cells. But we still have to find suitable parameter values to reproduce the experimental data and to simulate the model.</p>
<p> Our model now considers the maturation of KillerRed and the accumulation of damages done to the bacteria. It is able to describe the evolution of all three quantities that are observed: the optical density of the suspension, its fluorescence and the density of living cells. But we still have to find suitable parameter values to reproduce the experimental data and to simulate the model.</p>
<p> $r$: the rate of growth of bacteria in $min^{-1}$</p>
<p> $r$: the rate of growth of bacteria in $min^{-1}$</p>
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<p> $a$: the production of KillerRed per bacteria in $UF.OD^{-1}.min^{-1}$</p>
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<p> $a$: the production of KillerRed per bacteria in $RFU.OD^{-1}.min^{-1}$</p>
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<p> $b$: the efficiency of photobleaching in $UF.UL^{-1}.min^{-1}$</p>
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<p> $b$: the efficiency of photobleaching in $RFU.UL^{-1}.min^{-1}$</p>
<p> $m$: the maturation rate of KillerRed in $min^{-1}$</p>
<p> $m$: the maturation rate of KillerRed in $min^{-1}$</p>
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<p> $k$: the toxicity of KillerRed in $OD.UF^{-1}.UL^{-1}.min^{-1}$</p>
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<p> $k$: the toxicity of KillerRed in $OD.RFU^{-1}.UL^{-1}.min^{-1}$</p>
<p> $l$: the rate of reparation of the bacteria by step of time. unit less</p>
<p> $l$: the rate of reparation of the bacteria by step of time. unit less</p>
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<p> With the units :</p>
<p> With the units :</p>
<p> $OD$ is the Optical Density at $\lambda = 600nm$</p>
<p> $OD$ is the Optical Density at $\lambda = 600nm$</p>
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<p> $UF$ is an arbitrary Unit of Fluorescence (with $\lambda_absorption=585nm$ and $\lambda_emission=610nm$</p>
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<p> $RFU$ is an arbitrary Unit of Fluorescence (with $\lambda_absorption=585nm$ and $\lambda_emission=610nm$</p>
<p> $UL$ is an arbitrary Unit of Light, related to the energy received by the bacteria. $1 UL$ shall be the energy of light received by an Erlenmeyer flask with a MR16 LED on its side at full power.</p>
<p> $UL$ is an arbitrary Unit of Light, related to the energy received by the bacteria. $1 UL$ shall be the energy of light received by an Erlenmeyer flask with a MR16 LED on its side at full power.</p>
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Revision as of 01:05, 5 October 2013

Grenoble-EMSE-LSU, iGEM


Grenoble-EMSE-LSU, iGEM

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