Team:Paris/Modeling

From 2008.igem.org

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                        <a href="https://2008.igem.org/Team:Paris/Modeling/linear_approach">Preliminary approach</a>
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[[Team:Paris/Modeling/Bibliography|Bibliographic References]] - [[Team:Paris/Modeling/linear_approach|Depreciated BoB page]] - [[Team:Paris/Modeling/Roadmap|Depreciated Roadmad page]]
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[[Team:Paris/Modeling/Bibliography|Bibliographic References]] - [[Team:Paris/Modeling/linear_approach|Old BoB approach]] - [[Team:Paris/Modeling/Roadmap|Depreciated Roadmad]]
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Revision as of 14:39, 27 August 2008

We had different approaches to model the biological system. We found interesting to explain at least two ways that we went throught. It is important to understand that both models aim at different goals in the process of understanding our system.

Contents


BoB (Based on Bibliography) Approach

Our first approach is quite rough and simple but effective. The goal here was to guess the behavior of our Bacteri'OClock, considering the overall system. Since it is a preliminary approach, we could not yet fill the model with data from the wet lab. This is why our work is mainly based on a bibliographic work, which allow us to use parameters and datas from scientific articles.

The keys points of this approach:

  • Simplicity for itself is not so much important, what we were looking for was understandability at first.
  • We used linear equations as much as possible: when it as already been proved in a paper than one interaction is efficiently modeled with an elementary expression, we tried to keep it.
  • Too many parameters in a model means less relevancy. In addition, the more parameters you have, the hardest it becomes to tune the system in order to have the behavior you are looking for.

Read more

Parameters Estimation Approach

This second approach was motivated by our will to understand our system in the most precise way. We decided to examine each part of our project (Oscillation, FIFO, Synchronization) incrementally, and tried to take into account the fundamental kinetics processes.

  • We hereby use mostly Hill function, hence the name of this approach. We analyzed in the most precise fashion every interaction that took place. The Hill functions are introduced to describe relationships between transcription factors and promoters, since we thought secondary to take into acount the translation phases.
  • Let's go see our , which we would like to study as deeply as possible !

Read more

  • What is at stake here is to determine the real parameters that govern the dynamics of our system.
    • First of all, you can find here the description of how we intend to find relevent parameters for our models.
    • We will need many parameters to fully describe the system according to the asumptions of the previous models. A natural way to have access to their value, after looking them up in the litterature, is to design specific experiments. As a consequence of the characterization of the promoters activity, some Hill functions could be obtained.
    • In a second step, we shall try to find a way to translate the natural noise to our model, given the numerical values obtained in the wet lab.
      • Firstly, we could compute the standard deviation for each set of points at a given inducer concentration, and to normalize it according to the mean value of the set itself.
      • The next stage is to get the mean of those normalized sd values at every inducer concentration.
      • Since the β parameter of the Hill function has a linear influence, it is possible to translate this error directly on the parameter; for example: β_err = random('norm',β,err) where β is the estimated value of the parameter and err is the mean of the normalized standard deviations of the experimental values.
      • For each cell in the model, we could use such noised values for Vmax parameter, in order to reproduce randomness estimated in the wet lab.

Links

Bibliographic References - Depreciated BoB page - Depreciated Roadmad page