Team:SDU-Denmark/project-bc

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=== Description of the model ===
=== Description of the model ===
The model we will be using to predict biochemical behaviour of the system is a simplification of the real system.<br>  
The model we will be using to predict biochemical behaviour of the system is a simplification of the real system.<br>  
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The simplified model does not consider the normal metabolism in the cell. It only includes the most important enzymes in the normal ''E. coli'' chemotaxis pathway and the proteins responsible for coupling the phototaxis to the chemotaxis.<br>
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The simplified model does not consider the normal metabolism in the cell. It only includes the most important enzymes in the normal ''E. coli'' chemotaxis pathway and the proteins responsible for coupling phototaxis to chemotaxis.<br>
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Below, you will se a schematic representation of the system our biochemical modelling was performed on. The crossed-over enzymes and proteins have not been modelled as a differential equation but considered as a constant in the system.<br>
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Below, you will find a schematic representation of the system our biochemical modelling was performed on. The crossed-over enzymes and proteins have not been modelled as a differential equation but considered as constants in the system.<br>
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[[Image: Team-SDU-Denmark-biomodelling.png |thumb|550px |center| '''Figure 2''': Schematics of the system we want to make. The enzymes that are crossed-over are considered constant in our system]]
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[[Image: Team-SDU-Denmark-biomodelling.png |thumb|550px |center| '''Figure 2''': Schematics of the system we want to make. The enzymes that are crossed-over are considered constant in our system.]]
The important enzymes in the system are mathematically represented by a differential equation under the assumption of steady state in the system and modelled in a demo version of the program [http://www.berkeleymadonna.com/ Berkeley Madonna].
The important enzymes in the system are mathematically represented by a differential equation under the assumption of steady state in the system and modelled in a demo version of the program [http://www.berkeleymadonna.com/ Berkeley Madonna].
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Revision as of 21:31, 27 October 2010