Team:SDU-Denmark/project-t

From 2010.igem.org

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== Theory ==
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= Theory =
In this section we will review the theory behind our approach to establishing a flow through a microtube.  
In this section we will review the theory behind our approach to establishing a flow through a microtube.  
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==Phototaxis==
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===Phototaxis===
'''Background:'''
'''Background:'''
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SopII-HtrII-Tsr fusion,chimer coding sequence: BBa_K343003 (Sandboxed)<br><br>
SopII-HtrII-Tsr fusion,chimer coding sequence: BBa_K343003 (Sandboxed)<br><br>
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== Hyperflagellation ==
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=== Hyperflagellation ===
'''Background:'''<br>
'''Background:'''<br>
To maximize the microflow system's effectivity, we want to increase the force each single bacterium can generate. Since the main motor for the flow is the flagellum we will have to modify this factor for increasing the force. Flagella in E.Coli rotate at a maximum speed around 6000 rpm, which can not easily be exceeded. So if we wanted to increse the generated force we would have to opt for more flagella on the surface of our bacteria, instead of faster flagella. This is called hyperflagellation, which is a process that is not all too well studied in normally-flagellated coli, so we will have to test it out.<br>
To maximize the microflow system's effectivity, we want to increase the force each single bacterium can generate. Since the main motor for the flow is the flagellum we will have to modify this factor for increasing the force. Flagella in E.Coli rotate at a maximum speed around 6000 rpm, which can not easily be exceeded. So if we wanted to increse the generated force we would have to opt for more flagella on the surface of our bacteria, instead of faster flagella. This is called hyperflagellation, which is a process that is not all too well studied in normally-flagellated coli, so we will have to test it out.<br>

Revision as of 17:53, 3 July 2010