Team:ETH Zurich/modeling/diffmodel

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(Difference between revisions)
(Deriving diffusion rates)
(Deriving diffusion rates)
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According to Fick's law of diffusion, the incoming flow of AHL &Phi;(AHL<sub>int</sub>) (number of molecules per second) into the cells and the incoming flow of AHL &Phi; (AHL<sub>ext</sub>) into the bead
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According to Fick's law of diffusion, the flow of AHL &Phi;(AHL<sub>int</sub>) (number of molecules per second) from the bead into the cells and the flow of AHL &Phi; (AHL<sub>ext</sub>) from cells into the bead into the bead are
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$$\Phi(AHL_{bead \rightarrow cells}) = \sigma \mathcal{A} ([AHL_{ext}]-[AHL_{int}]) \\ \Phi(AHL_{cells \rightarrow bead }) = N \sigma \mathcal{A} ([AHL_{int}]-[AHL_{ext}])$$
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$$\Phi(AHL_{bead \rightarrow cells}) = N\sigma \mathcal{A} ([AHL_{ext}]-[AHL_{int}]) \\ \Phi(AHL_{cells \rightarrow bead }) = N \sigma \mathcal{A} ([AHL_{int}]-[AHL_{ext}])$$
where &sigma; is the membrane permeability and A is the area of the membrane.  
where &sigma; is the membrane permeability and A is the area of the membrane.  

Revision as of 17:05, 15 October 2014

iGEM ETH Zurich 2014