Difference between revisions of "Team:Aix-Marseille/Collaborations"

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Where alpha is the growth yield in <div lang="latex">g/l/cell</div>. The remaining functions and parameters in equations 1 and 2 are the division rate <div lang="latex">\sigma (\mathbf{z,c})</div> and the partitioning 2 function <div lang="latex">p(\mathbf{z,z',c})</div>. There is less consensus in the litterature for an at least empirically appropriate form for these equations. To remain simple we propose:<br/><br/>
 
Where alpha is the growth yield in <div lang="latex">g/l/cell</div>. The remaining functions and parameters in equations 1 and 2 are the division rate <div lang="latex">\sigma (\mathbf{z,c})</div> and the partitioning 2 function <div lang="latex">p(\mathbf{z,z',c})</div>. There is less consensus in the litterature for an at least empirically appropriate form for these equations. To remain simple we propose:<br/><br/>
  
<div lang="latex">\sigma (\mathbf{z,c}) = \sigma \times H[2.0] = 0  & \text{if } z_0 < 2.0 \\ \sigma (\mathbf{z,c}) = \sigma \times H[2.0] = \sigma  & \text{if } z_0 \geq 2.0</div><br/><br/>
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<div lang="latex">\sigma (\mathbf{z,c}) = \sigma \times H[2.0] = 0  & \text{if } z_0 < 2.0 \\ \sigma (\mathbf{z,c}) = \sigma \times H[2.0] = \sigma  & \text{if } z_0 \geq 2.0</div>(6)<br/><br/>
  
 
Here we assume that there is a fixed rate of division <div lang="latex">\sigma</div> once cells are big enough to divide (<div lang="latex">H[]</div> is the Heaviside function).
 
Here we assume that there is a fixed rate of division <div lang="latex">\sigma</div> once cells are big enough to divide (<div lang="latex">H[]</div> is the Heaviside function).
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<div lang="latex">p(\mathbf{z,z',c}) = p(z_0,z'_0) \times p(z_1,z'_1) \times p(z_2,z'_2)</div> (7)<br/><br/>
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<div lang="latex">p(z_0,z'_0) = \delta_{z_0,\frac{z'_0}{2}} = 1 & \text{if } z_0 = z'_0/2.0 \\
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p(z_0,z'_0) = \delta_{z_0,\frac{z'_0}{2}} = 0 & \text{if } z_0 \ne z'_0/2.0.</div> (7)<br/><br/>
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<div lang="latex">p(z_1,z'_1) = 0.5^{z'_1} \begin{pmatrix} z_1 \\ z'_1 \\ \end{pmatrix} = 0.5^{z'_1} \frac{z'_1 !}{(z'_1-z_1)! z_1 !}</div>(8)<br/><br/>
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In these equations we assume that the partitioning of the three internal state variables are independant.
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That cells divide exactly in half, that is the maturity parameter is exactly halved when the cells divide
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(<div lang="latex">\delta</div> is a Kronecker delta function).
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That the two plasmids segregate independantly and as individual plasmids according to a binomial distribution.
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These assumptions are probably the most suspect in the model.
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This initial version of the model has no contention, that is <div lang="latex">z_1</div> and <div lang="latex">z_2</div> do not influence the growth rate <div lang="latex">\mu </div>.
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In order to develop the model for the system envisaged this needs to be introduced.
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Revision as of 15:47, 17 October 2016