Team:Aberdeen Scotland/Modeling

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== Our Ordinary Differential Equations ==
== Our Ordinary Differential Equations ==
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<a href="http://www.codecogs.com/eqnedit.php?latex=\frac{d[M1]}{dt} = \frac{{}\lambda _1[GAL]^{n1}}{k_{1}^{n1}@plus;[GAL]^{n1}} - (\mu _1@plus;T)[M1]" target="_blank"><img src="http://latex.codecogs.com/gif.latex?\frac{d[M1]}{dt} = \frac{{}\lambda _1[GAL]^{n1}}{k_{1}^{n1}+[GAL]^{n1}} - (\mu _1+T)[M1]" title="\frac{d[M1]}{dt} = \frac{{}\lambda _1[GAL]^{n1}}{k_{1}^{n1}+[GAL]^{n1}} - (\mu _1+T)[M1]" /></a>
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<math>\frac{d[M1]}{dt} = \frac{{}\lambda _1[GAL]^{n1}}{k_{1}^{n1}+[GAL]^{n1}} - (\mu _1+T)[M1]" title="\frac{d[M1]}{dt} = \frac{{}\lambda _1[GAL]^{n1}}{k_{1}^{n1}+[GAL]^{n1}} - (\mu _1+T)[M1]" /></math>

Revision as of 11:48, 16 July 2010

A MATLAB program has been compiled that describes how the concentrations of DNA, mRNA and Proteins respond to different experimental parameters. Much more to follow.

Our Ordinary Differential Equations

<math>\frac{d[M1]}{dt} = \frac{{}\lambda _1[GAL]^{n1}}{k_{1}^{n1}+[GAL]^{n1}} - (\mu _1+T)[M1]" title="\frac{d[M1]}{dt} = \frac{{}\lambda _1[GAL]^{n1}}{k_{1}^{n1}+[GAL]^{n1}} - (\mu _1+T)[M1]" /></math>