Team:Paris/Analysis/Construction2

From 2008.igem.org

(Difference between revisions)
(Kinetics)
(Kinetics)
Line 14: Line 14:
* We use a logistic equation. This captures the fact that at low population density, the concentration of cells in the chemostat (c) increase exponentialy with a growth rate α<sub>cell</sub> and at high population density, the population reaches a maximum concentration c<sub>max</sub>. As a consequence, the concentration of cells in the medium can be expressed in terms of a production (positive) term and degradation (negative) terms, as follows:
* We use a logistic equation. This captures the fact that at low population density, the concentration of cells in the chemostat (c) increase exponentialy with a growth rate α<sub>cell</sub> and at high population density, the population reaches a maximum concentration c<sub>max</sub>. As a consequence, the concentration of cells in the medium can be expressed in terms of a production (positive) term and degradation (negative) terms, as follows:
<br>
<br>
-
<center>[[Image:population_evolution_full_2.jpg]].</center>
+
<center>[[Image:population_evolution_full_2.jpg]],</center>
<br>
<br>
 +
where...
*To model the quorum sensing dynamics, we consider the production of HSL as:
*To model the quorum sensing dynamics, we consider the production of HSL as:

Revision as of 23:14, 25 October 2008

Model Construction


Description

  • We chose to use a chemostat. We want to impose to our model the fact that the rate of production has to be proportional to the existing population and to the amount of available resources.
  • We assume a logistic model for the population kinetics in the chemostat (reference).
  • To archieve synchronization we use QS. Explain the principle?

Kinetics

  • We use a logistic equation. This captures the fact that at low population density, the concentration of cells in the chemostat (c) increase exponentialy with a growth rate αcell and at high population density, the population reaches a maximum concentration cmax. As a consequence, the concentration of cells in the medium can be expressed in terms of a production (positive) term and degradation (negative) terms, as follows:


Population evolution full 2.jpg,


where...

  • To model the quorum sensing dynamics, we consider the production of HSL as:

eqHSL 1,

the transport of HSL is given by:

HSLext sum 2.jpg,

which gives:

HSLext final 2.jpg,          where     Cell number volume.jpg;

and the activation of envZ depends of the concentration of HSL according to:

eqHSL 3.


Parameters Search

manly from literature but also from S0 analysis.

Parameters
 
Chemostat Parameter Meaning Original Value Normalized Value Unit Source
figure / equations of Chemostat αcell Growth rate 0.0198 1 min-1 wet-lab
cmax Carrying capacity for cell growth 0.1 0.1 µm3 [3]
Drenewal Dilution rate 0.00198 0.1 min-1 wet-lab ([3])
d Death rate 0.0099 0.5 min-1 wet-lab
 
Quorum Sensing Parameter Meaning Original Value Normalized Value Unit Source
figure / equations of Quorum Sensing γHSL Degradation rate 0.0053 0.2690 min-1 wet-lab
γHSLext

Degradation rate 0.0106 0.5380 min-1 [6]
βHSL Production rate 0.3168 16 min-1
η Diffusion rate 10 505 min-1 [2]
nHSL Hill coefficient   4   [3]
θHSL Hill characteristic concentration for the second operator   0.5 c.u [3]
Retrieved from "http://2008.igem.org/Team:Paris/Analysis/Construction2"