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> | ||
- | <p id="legend">Figure 3.<br> | + | <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 | + | <p id="legend">Figure 4.<br>Characterization of the algorithm in Arduino |
- | The first graph | + | 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> | ||
- | <p id="legend">Figure 5.<br> | + | <p id="legend">Figure 5.<br>TalkE'coli: C2M part |
- | + | On the left: the real device, on the right: functional scheme</br> | |
- | + | 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> | |
</p> | </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> | <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> | ||
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<p align="center"></br></br><img src="https://static.igem.org/mediawiki/2013/0/0a/Charac_fluo_measure.png" alt="Charac_fluo_measure" width="600px" /></br></br></p> | <p align="center"></br></br><img src="https://static.igem.org/mediawiki/2013/0/0a/Charac_fluo_measure.png" alt="Charac_fluo_measure" width="600px" /></br></br></p> | ||
<p id="legend">Figure 6.<br>Characterization of the fluorescence measurements</p> | <p id="legend">Figure 6.<br>Characterization of the fluorescence measurements</p> | ||
- | <p>The fluorescence readings of | + | <p>The fluorescence readings of TalkE'coli and of the Tristar microplate reader are <strong>linearly related</strong>. Furthermore, the precision of both measurements are comparable. Our device is therefore <strong>able to detect KillerRed fluorescence with enough precision</strong> to allow proper cell growth control. |
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</br>The MOS transistor is controlled by Arduino and is used like a switch. It allows us to control the average light intensity of the LED lamp.</br></br> | </br>The MOS transistor is controlled by Arduino and is used like a switch. It allows us to control the average light intensity of the LED lamp.</br></br> | ||
</p> | </p> | ||
- | <p>The first part of this circuit – all components above the MOS transistor BS170 - stabilizes the current of the LED | + | <p>The first part of this circuit – all components above the MOS transistor BS170 - <strong>stabilizes the current of the LED lamp</strong> and the second part – consisting in the MOS transistor and Arduino microcontroller- allows us to <strong>control the average light intensity</strong>.</br> |
The nominal power of the LED is 6W when 12V is applied. That means that the current through the LED lamp is 0.5A.</br> | The nominal power of the LED is 6W when 12V is applied. That means that the current through the LED lamp is 0.5A.</br> | ||
To ensure that the power supply is stable enough, we stabilized it thanks to a bipolar transistor, three diodes and two resistors.</br></br> | To ensure that the power supply is stable enough, we stabilized it thanks to a bipolar transistor, three diodes and two resistors.</br></br> | ||
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<img src="https://static.igem.org/mediawiki/2013/a/a8/Servo_pos2.png" alt="Position2_servo" width="450px" /></p> | <img src="https://static.igem.org/mediawiki/2013/a/a8/Servo_pos2.png" alt="Position2_servo" width="450px" /></p> | ||
<p id="legend">Figure 9.<br>On the left, the first position of the servomotor and on the right, the second position of the servomotor.</br> | <p id="legend">Figure 9.<br>On the left, the first position of the servomotor and on the right, the second position of the servomotor.</br> | ||
- | + | </p> | |
- | <p align="left"><strong>L</strong>: distance between the center of the servomotor S and the center of the hole in the box A (6.5cm)</br> | + | <p align="left">Known dimensions :</br> |
+ | <strong>L</strong>: distance between the center of the servomotor S and the center of the hole in the box A (6.5cm)</br> | ||
<strong>h</strong>: height from A to S (2cm)</br> | <strong>h</strong>: height from A to S (2cm)</br> | ||
<strong>R</strong>: radius of the filter and also the hole in the box (1cm)</br> | <strong>R</strong>: radius of the filter and also the hole in the box (1cm)</br> | ||
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<h3>The lens holder</h3> | <h3>The lens holder</h3> | ||
- | <p>To focus the beam of the fluorescence, we | + | <p>To focus the beam of the fluorescence, we used a microscope objective, held in place by a tailored mold.</p> |
<h3>The LED lamp box</h3> | <h3>The LED lamp box</h3> | ||
- | <p>To avoid illuminating the entire box | + | <p>To avoid illuminating the entire box we inserted the LED in a smaller box with an opening that matches the size of the lamp cap. Since the illumination angle of the lamp is small, the light goes almost in one direction and only lights up the filters or the mirrors.</p> |
<h3>The servomotor holder</h3> | <h3>The servomotor holder</h3> | ||
- | <p>Since the servomotor will move the filter rack, it needed to be securely attached onto the box. We designed a part with two arms | + | <p>Since the servomotor will move the filter rack, it needed to be securely attached onto the box. We designed a part with two arms where you can screw the servomotor and a flat support to hold it on the box. We drilled many holes so that we can easily adjust the height of the servomotor.</br></br> |
As said previously we used a 3D-printer to built these parts, but because of the complexity of the filter rack and its rail they had to be done with a another 3D-printing method. These two parts were completed through Selective Laser Sintering and all the other were made by Fused Deposition Modeling</p> | As said previously we used a 3D-printer to built these parts, but because of the complexity of the filter rack and its rail they had to be done with a another 3D-printing method. These two parts were completed through Selective Laser Sintering and all the other were made by Fused Deposition Modeling</p> |
Latest revision as of 03:10, 5 October 2013