Team:Grenoble-EMSE-LSU/Project/Instrumentation/Fluo

From 2013.igem.org

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                                         <p align="center"><img src="https://static.igem.org/mediawiki/2013/5/51/Oscilloscope.png" alt="Oscillogram" width="650px" /></p>
                                         <p align="center"><img src="https://static.igem.org/mediawiki/2013/5/51/Oscilloscope.png" alt="Oscillogram" width="650px" /></p>
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                                         <p id="legend">Figure 3.<br>Oscillograms showing the two different mode of the photodiode.</br>The first oscillogramm shows the pulse train mode and the second the 50% duty cycle mode</br></br></p>
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                                         <p id="legend">Figure 3.<br>Oscilloscope recordings showing the two different modes of the photodiode.</br>The first recording shows the pulse train mode and the second the 50% duty cycle mode</br></br></p>
                                         <p>Since this frequency will be calculated by the Arduino controller, it may cause some trouble to the program to use a pulse train because the duration of the pulse is always 500ns and can be missed by the controller. The square wave (50% duty cycle) seems to be a better solution because of the 50% duty cycle. It means that the pulse duration depends on the frequency. Its duration is equal to 1/2f and since the light intensity we want to measure will be low, this type of signal can be easily detected by Arduino.</br></br></p>
                                         <p>Since this frequency will be calculated by the Arduino controller, it may cause some trouble to the program to use a pulse train because the duration of the pulse is always 500ns and can be missed by the controller. The square wave (50% duty cycle) seems to be a better solution because of the 50% duty cycle. It means that the pulse duration depends on the frequency. Its duration is equal to 1/2f and since the light intensity we want to measure will be low, this type of signal can be easily detected by Arduino.</br></br></p>
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<p id="legend">Figure 4.<br>Characterization of the algorithm in Arduino</br>
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<p id="legend">Figure 4.<br>Characterization of the algorithm in Arduino
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The first graph shows us the reponse of Arduino in pulse train mode, the second one shows us the response of Arduino in 50% duty cycle mode, and the last one gives us the standard deviation of the 50% duty cycle mode</br></br></p>
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The first graph displays the reponse of Arduino in pulse train mode, the second one displays the response of Arduino in 50% duty cycle mode, and the last one gives us the standard deviation of the 50% duty cycle mode</br></br></p>
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                                         <p>For the proof of concept of the optical part we use a LED lamp - MR16 (GU5.3)- and a cube filter from a fluorescence microscope with excitation and emission filters and an adjustable lens. The LED lamp was chosen so that we didn't have to buy <strong>high-power LEDS</strong> and build a <strong>card with heat sinks</strong>. This lamp illuminates with <strong>520 lumens in a 40° cone under 12V and 6W</strong>. The low voltage was chosen as <strong>a safety measure</strong> and the small angle to <strong>avoid losing too much light</strong>. The excitation filter is a <strong>green interferential filter</strong> to excite the red fluorescent protein and the <strong>red emission filter</strong> is only a colored filter to collect all the red light in order to have a more precise measure. In the cube there is also a <strong>dichroic mirror</strong> that reflects all the green light and transmits all the red light. This mirror enables us to <strong>separate the photodiode from the light source completely</strong>.</br></br></p>
                                         <p>For the proof of concept of the optical part we use a LED lamp - MR16 (GU5.3)- and a cube filter from a fluorescence microscope with excitation and emission filters and an adjustable lens. The LED lamp was chosen so that we didn't have to buy <strong>high-power LEDS</strong> and build a <strong>card with heat sinks</strong>. This lamp illuminates with <strong>520 lumens in a 40° cone under 12V and 6W</strong>. The low voltage was chosen as <strong>a safety measure</strong> and the small angle to <strong>avoid losing too much light</strong>. The excitation filter is a <strong>green interferential filter</strong> to excite the red fluorescent protein and the <strong>red emission filter</strong> is only a colored filter to collect all the red light in order to have a more precise measure. In the cube there is also a <strong>dichroic mirror</strong> that reflects all the green light and transmits all the red light. This mirror enables us to <strong>separate the photodiode from the light source completely</strong>.</br></br></p>
                                         <p align="center"><img src="https://static.igem.org/mediawiki/2013/c/ca/Optique.png" alt="Fluorometer_igem2013_Grenoble-EMSE-LSU" width="600px" /></p>
                                         <p align="center"><img src="https://static.igem.org/mediawiki/2013/c/ca/Optique.png" alt="Fluorometer_igem2013_Grenoble-EMSE-LSU" width="600px" /></p>
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                                         <p id="legend">Figure 5.<br>TALKE'coli: C2M part<br>
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                                         <p id="legend">Figure 5.<br>Talk'E.coli: C2M part
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                                        On the left: the real device, on the right: functional schematic<br>
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On the left: the real device, on the right: functional scheme</br>
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                                        The light from the LED lamp goes through the green excitation filter and illuminate the sample thanks to a dichroic mirror. Then the red fluorescent protein is now excited and re-emits red light that goes through a lens that concentrate it on the photodiode.</br></br>  
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The light from the LED lamp goes through the green excitation filter and illuminateS the sample thanks to a dichroic mirror. Then the red fluorescent protein is now excited and re-emits red light that goes through a lens that concentrateS it on the photodiode.</br></br>  
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<p>With the setup shown above, we put different culture in a 50mL rounded tube and to protect the photodiode from the outside lamp we place all the component in a large box. These are the results we obtained:</br></br></p>
<p>With the setup shown above, we put different culture in a 50mL rounded tube and to protect the photodiode from the outside lamp we place all the component in a large box. These are the results we obtained:</br></br></p>

Revision as of 02:10, 5 October 2013

Grenoble-EMSE-LSU, iGEM


Grenoble-EMSE-LSU, iGEM

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