Team:SJTU-BioX-Shanghai/Project/project3
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Based on diffusion equation, by solving it under different boundary values, we found that the cluster system can increase production significantly. | Based on diffusion equation, by solving it under different boundary values, we found that the cluster system can increase production significantly. | ||
{{Template:12SJTU_part_summary_foot}} | {{Template:12SJTU_part_summary_foot}} | ||
- | + | ==Basic Assumptions== | |
:1. Protein clusters locate on the membrane, which means the products of our device diffuse in an area of hemisphere. We assume that the membrane has no extra effect on the behavior of molecular diffusion. So the concentration will be doubled compared to the diffusion progress in a volume of sphere. | :1. Protein clusters locate on the membrane, which means the products of our device diffuse in an area of hemisphere. We assume that the membrane has no extra effect on the behavior of molecular diffusion. So the concentration will be doubled compared to the diffusion progress in a volume of sphere. | ||
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:The diffusion area is regarded as a hemisphere which radius is R with an enzyme located on the center which occupies a region of r<sub>0</sub>. So we have the equaction: | :The diffusion area is regarded as a hemisphere which radius is R with an enzyme located on the center which occupies a region of r<sub>0</sub>. So we have the equaction: | ||
[[Image:12SJTU_formula1.png|200px]] | [[Image:12SJTU_formula1.png|200px]] | ||
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::While: | ::While: | ||
- | + | [[Image:12SJTU_formula11.png|200px]] | |
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:By solving the equations we can show how the concentration floats with radius and time (''Fig.1'' ): | :By solving the equations we can show how the concentration floats with radius and time (''Fig.1'' ): | ||
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:We place another downstream enzyme beside the current enzyme, so the production will be consumed. The consumption rate is considered to be Michaelis-Menten equation, and simplified as proportional to the product concentration. | :We place another downstream enzyme beside the current enzyme, so the production will be consumed. The consumption rate is considered to be Michaelis-Menten equation, and simplified as proportional to the product concentration. | ||
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::While: | ::While: | ||
- | + | [[Image:12SJTU_formula12.png|200px]] | |
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:Then we have three-dimensional graphics as following (''Fig.2'' ): | :Then we have three-dimensional graphics as following (''Fig.2'' ): | ||
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===Enzymatic Reaction with Product Inhibition=== | ===Enzymatic Reaction with Product Inhibition=== | ||
- | + | [[Image:12SJTU_formula2.png|200px]] | |
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:Solving these equations we have: | :Solving these equations we have: | ||
- | + | [[Image:12SJTU_formula21.png|250px]] | |
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[[Image:12SJTU_Modelling6.png|thumb|500px|center|''Fig.4'' : Production in enzymatic reaction with product inhibition]] | [[Image:12SJTU_Modelling6.png|thumb|500px|center|''Fig.4'' : Production in enzymatic reaction with product inhibition]] |
Latest revision as of 03:58, 27 September 2012
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