Team:Valencia Biocampus/Modeling
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For the case of the Heat Shock promoter, we decided to model the static transfer function of the Fluorescent Intensity as a result of the Temperature with the folow equation: | For the case of the Heat Shock promoter, we decided to model the static transfer function of the Fluorescent Intensity as a result of the Temperature with the folow equation: | ||
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Revision as of 11:20, 26 September 2012
Modeling
Mathematical modeling: Introduction
Mathematical modeling plays a central role in Synthetic Biology, one of its mayor abilities: to predict the behavior of a biological circuit and then is an important bridge between the ideas and concepts, and biological experiments.
The main idea is to interact with the experimental part of the project in two ways. In one hand to characterize the constructed biobricks and identify parameters of the models allowing to a better understanding of the biology behind and on the other hand to direct the way in which experiments are performed to verify a prediction from the modeling.
Then we started the characterization of each part created in the lab, some of the mathematical model parameters were estimated thanks to several experiments we performed within the project (others were derived from literature) and they were used to predict the final behavior of each construction.
Experimental procedures for parameter estimation are discussed and simulation experiments performed, using ODEs with MATLAB and Global optimization algorithm for MINLP's based on Scatter Search (SSm by Process Engineering Group IIM-CSIC). == '''Modeling Bacteria''' == Here we modeled several of the Bacteria constructions. === '''Are you hot?''' === For the case of the Heat Shock promoter, we decided to model the static transfer function of the Fluorescent Intensity as a result of the Temperature with the folow equation: