Difference between revisions of "Team:Manchester/Model"

1. The statistical Design of Experiments (DoE) was used to design the most efficient experiments to determine the factors influencing the expression of our key enzyme. Two rounds of DoE enabled us to identify the optimal conditions for testing of our experimental system.

2. Continuous culture modelling was used to predict the rate at which Phosphostore devices could be produced on different substrates. This allowed us to estimate the yearly cost of treating wastewater using phosphostore. As a result we performed a major re-design of the intended Phosphostore device, assessing the cost reduction potential of different growth conditions and experimental strategies by computational modelling.

3. An innovative ensemble modelling approach was used to predict the behaviour of our recombinant phosphate starvation operon in addition to native PHO regulon as a regulatory system for controlling microcompartment synthesis. This helped us to choose the appropriate regulatory parts for our experimental design.

Design of Experiments

Continuous Culture

Phosphate Starvation Operon

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+<p>We used modelling in three ways to inform different parts of the project:</p>
-<p style="margin-left: 40px">1. We used statistical Design of Experiments (DoE) to design the most efficient experiments to determine the factors influencing the activity of our key enzyme. Two rounds of DoE enabled us to identify the optimal conditions for testing of our experimental system</p>
+<p style="margin-left: 40px">1. The statistical Design of Experiments (DoE) was used to design the most efficient experiments to determine the factors influencing the expression of our key enzyme. Two rounds of DoE enabled us to identify the optimal conditions for testing of our experimental system.</p>
-<p style="margin-left: 40px">2. We used an innovative ensemble modelling approach to predict the behaviour of our recombinant phosphate starvation operon in addition to native PHO regulon as a regulatory system for controlling microcompartment synthesis. This helped us to choose the appropriate regulatory parts for our experimental design</p>
+<p style="margin-left: 40px">2. Continuous culture modelling was used to predict the rate at which Phosphostore devices could be produced on different substrates. This allowed us to estimate the yearly cost of treating wastewater using phosphostore. As a result we performed a major re-design of the intended Phosphostore device, assessing the cost reduction potential of different growth conditions and experimental strategies by computational modelling.</p>
-<p style="margin-left: 40px">3. Continuous culture modelling was used to predict the rate at which Phosphostore devices could be produced on different substrates. This allowed us to estimate the yearly cost of treating wastewater using phosphostore. As a result we performed a major re-design of the intended Phosphostore device, assessing the cost reduction potential of different growth conditions and experimental strategies by computational modelling</p>
+<p style="margin-left: 40px">3. An innovative ensemble modelling approach was used to predict the behaviour of our recombinant phosphate starvation operon in addition to native PHO regulon as a regulatory system for controlling microcompartment synthesis. This helped us to choose the appropriate regulatory parts for our experimental design.</p>
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