Team:TU-Delft/Modeling
From 2012.igem.org
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+ | = Single-Cell Model = | ||
+ | '''The single-cell model of our system consists of three connected but easily separable modules: the sensor, the band detector and the filter. The sensor detects toxic substances from cigarette smoke. The band detector produces green fluorescent protein upon a detection of a certain range (band) of toxic substance concentration. After the toxic substance concentration crosses a certain threshold, the filter turns the system red (red fluorescent protein is expressed). The single-cell model helped us understand in detail whether and how our synthetic circuit works, especially to explore the characteristics of the GFP band and get a feeling of how it is related to concentration of our input substance. ''' | ||
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+ | {{:Team:TU-Delft/Templates/SecEnd}} | ||
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+ | {{:Team:TU-Delft/Templates/SecStart}} | ||
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+ | = Single-Cell Model = | ||
+ | '''The single-cell model of our system consists of three connected but easily separable modules: the sensor, the band detector and the filter. The sensor detects toxic substances from cigarette smoke. The band detector produces green fluorescent protein upon a detection of a certain range (band) of toxic substance concentration. After the toxic substance concentration crosses a certain threshold, the filter turns the system red (red fluorescent protein is expressed). The single-cell model helped us understand in detail whether and how our synthetic circuit works, especially to explore the characteristics of the GFP band and get a feeling of how it is related to concentration of our input substance. ''' | ||
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Revision as of 07:35, 3 September 2012
Modeling overview
If you want to get a better overview of the modeling, take a tour through our slides and click on them for detailed explanation of the respective sections.
Single-Cell Model
The single-cell model of our system consists of three connected but easily separable modules: the sensor, the band detector and the filter. The sensor detects toxic substances from cigarette smoke. The band detector produces green fluorescent protein upon a detection of a certain range (band) of toxic substance concentration. After the toxic substance concentration crosses a certain threshold, the filter turns the system red (red fluorescent protein is expressed). The single-cell model helped us understand in detail whether and how our synthetic circuit works, especially to explore the characteristics of the GFP band and get a feeling of how it is related to concentration of our input substance.
Single-Cell Model
The single-cell model of our system consists of three connected but easily separable modules: the sensor, the band detector and the filter. The sensor detects toxic substances from cigarette smoke. The band detector produces green fluorescent protein upon a detection of a certain range (band) of toxic substance concentration. After the toxic substance concentration crosses a certain threshold, the filter turns the system red (red fluorescent protein is expressed). The single-cell model helped us understand in detail whether and how our synthetic circuit works, especially to explore the characteristics of the GFP band and get a feeling of how it is related to concentration of our input substance.
Single-Cell Model
The single-cell model of our system consists of three connected but easily separable modules: the sensor, the band detector and the filter. The sensor detects toxic substances from cigarette smoke. The band detector produces green fluorescent protein upon a detection of a certain range (band) of toxic substance concentration. After the toxic substance concentration crosses a certain threshold, the filter turns the system red (red fluorescent protein is expressed). The single-cell model helped us understand in detail whether and how our synthetic circuit works, especially to explore the characteristics of the GFP band and get a feeling of how it is related to concentration of our input substance.