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− | < | + | <h4><u><center>Engineering</center></u></h4> |
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<h2>The team started with performing PCR for the plasmids as it is a general technique and the results would serve as a standard to compare the results of LAMP and RPA, the other relatively new amplification techniques we used for the project.</h2> | <h2>The team started with performing PCR for the plasmids as it is a general technique and the results would serve as a standard to compare the results of LAMP and RPA, the other relatively new amplification techniques we used for the project.</h2> | ||
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− | < | + | <h4><u><center>Results</center></u></h4> |
<h4><ins>PCR</ins></h4> | <h4><ins>PCR</ins></h4> | ||
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− | < | + | <h4><u><center>Sample Collector</center></u></h4> |
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<h2>The Collection Device is a portable, sturdy, and easy to use sample collection device. Its current version provides a small form factor that may be further reduced. Sample collection is done by brushing the sterile cotton swab against a sample. The device contains a sterile watertight chamber for TE buffer solution for safe transportation and use. This chamber is sealed with a thin watertight film that maintains the liquid in the chamber until it is needed. A funnel maintains the film in place through pressure with the use of three screws. Once sample collection occurs, TE buffer is released through the press of a plunger, which the funnel guides into the cotton swab with the sample. The sample is washed out of the cotton by the flow of liquid. A lid may be used to direct the liquid flow directly into the microfluidic chip inlet, making the transition between sample collection and sample preparation seamless. </h2> | <h2>The Collection Device is a portable, sturdy, and easy to use sample collection device. Its current version provides a small form factor that may be further reduced. Sample collection is done by brushing the sterile cotton swab against a sample. The device contains a sterile watertight chamber for TE buffer solution for safe transportation and use. This chamber is sealed with a thin watertight film that maintains the liquid in the chamber until it is needed. A funnel maintains the film in place through pressure with the use of three screws. Once sample collection occurs, TE buffer is released through the press of a plunger, which the funnel guides into the cotton swab with the sample. The sample is washed out of the cotton by the flow of liquid. A lid may be used to direct the liquid flow directly into the microfluidic chip inlet, making the transition between sample collection and sample preparation seamless. </h2> | ||
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− | < | + | <h4><u><center>The Microfluidics</center></u></h4> |
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<h2> A proper proof of concept is essential for communicating the breakthroughs in research and the proper creation of a working device. As such, before building the device and integrating engineering and biology, each biological reaction was tested and the engineering working principles were verified and documented. More details on the process and tests themselves may be found in <a href="https://2018.igem.org/Team:NYU_Abu_Dhabi/Biology">the biology</a> and <a href="https://2018.igem.org/Team:NYU_Abu_Dhabi/Engineering">the engineering</a> lab notebooks. </h2> | <h2> A proper proof of concept is essential for communicating the breakthroughs in research and the proper creation of a working device. As such, before building the device and integrating engineering and biology, each biological reaction was tested and the engineering working principles were verified and documented. More details on the process and tests themselves may be found in <a href="https://2018.igem.org/Team:NYU_Abu_Dhabi/Biology">the biology</a> and <a href="https://2018.igem.org/Team:NYU_Abu_Dhabi/Engineering">the engineering</a> lab notebooks. </h2> | ||
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<h2>When a sterile cotton bud is used to collect a real life sample, amplification of the target gene and thus presence of the subject pathogen can be colorimetrically visualised in normal light conditions. Immediately after the LAMP reaction with WarmStart Colorimetric Mastermix is completed, there is a notably lighter appearance to the reaction tube containing the transformed bacteria with the target gene (<i>lmo0733</i>). On the other hand, the sample of uncontaminated beef and the negative control remain a bright red colour, the difference is more noticeable 15 minutes after the reaction. The gel electrophoresis confirms the amplification that occured. This set of experiments provides evidence that LAMP results can be visualised on real food samples with bacterial cells and not only on purified DNA samples. </h2> | <h2>When a sterile cotton bud is used to collect a real life sample, amplification of the target gene and thus presence of the subject pathogen can be colorimetrically visualised in normal light conditions. Immediately after the LAMP reaction with WarmStart Colorimetric Mastermix is completed, there is a notably lighter appearance to the reaction tube containing the transformed bacteria with the target gene (<i>lmo0733</i>). On the other hand, the sample of uncontaminated beef and the negative control remain a bright red colour, the difference is more noticeable 15 minutes after the reaction. The gel electrophoresis confirms the amplification that occured. This set of experiments provides evidence that LAMP results can be visualised on real food samples with bacterial cells and not only on purified DNA samples. </h2> | ||
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</i></center></h2> | </i></center></h2> | ||
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− | < | + | <h4><u><center>Chip Flow</center></u></h4> |
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<h2>Confirming the hydrophilicity of the chip, a prototype made from double sided tape and film was tested. The chip had a channel width of 200µm, which is a conventional width for PDMS microfluidic chip. However, the liquid did not flow to the wells. Through varying different width of the microfluidic chip, we realized that maximizing the surface area exposed to the hydrophilic film is more important than varying surface pressure of the wells. The finalized chip had a 600µm width to ensure good flow but prevent flowback. </h2> | <h2>Confirming the hydrophilicity of the chip, a prototype made from double sided tape and film was tested. The chip had a channel width of 200µm, which is a conventional width for PDMS microfluidic chip. However, the liquid did not flow to the wells. Through varying different width of the microfluidic chip, we realized that maximizing the surface area exposed to the hydrophilic film is more important than varying surface pressure of the wells. The finalized chip had a 600µm width to ensure good flow but prevent flowback. </h2> | ||
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− | < | + | <h4><u><center>Amplification</center></u></h4> |
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<h2>The reagents for two positive as well as two negative NEB LAMP reactions were added to four different wells on PDMS chip. Each reaction contained 12.5µl of mastermix, 9µl of water and 1µl of miniprep DNA. Positive control reactions contained 2.5µl of primers, while in negative control reactions, the same volume of water was added instead. After the reagents were added to the chip, it was covered with hydrophobic PCR tape in order to prevent evaporation of the reagents throughout the reactions.The reactions were then run for 30 minutes by placing the chip on a hot plate heated to a temperature of 65°C. Figure 1 shows the chip as viewed under blue light. The wells containing positive are marked with a + symbol while the negative controls are marked with a - symbol. | <h2>The reagents for two positive as well as two negative NEB LAMP reactions were added to four different wells on PDMS chip. Each reaction contained 12.5µl of mastermix, 9µl of water and 1µl of miniprep DNA. Positive control reactions contained 2.5µl of primers, while in negative control reactions, the same volume of water was added instead. After the reagents were added to the chip, it was covered with hydrophobic PCR tape in order to prevent evaporation of the reagents throughout the reactions.The reactions were then run for 30 minutes by placing the chip on a hot plate heated to a temperature of 65°C. Figure 1 shows the chip as viewed under blue light. The wells containing positive are marked with a + symbol while the negative controls are marked with a - symbol. | ||
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</i></center></h2> | </i></center></h2> | ||
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<h2>The heating device provides a platform that sustains the designated temperature under which the RPA, LAMP reaction should run. There are three modes for the device: in the first mode, the | <h2>The heating device provides a platform that sustains the designated temperature under which the RPA, LAMP reaction should run. There are three modes for the device: in the first mode, the | ||
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</i></center></h2> | </i></center></h2> | ||
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− | < | + | <h4><u><center>Visualization</center></u></h4> |
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<h2>Ten NEB LAMP reactions were run, five of which were positive controls with both DNA and primers added, while the other five were negative with DNA added but with no primers. The reactions were run in PCR tubes at 65°C for 30 minutes. The completed reactions were then pipetted into the wells of a ten-well PDMS chip, alternating between positive and negative. | <h2>Ten NEB LAMP reactions were run, five of which were positive controls with both DNA and primers added, while the other five were negative with DNA added but with no primers. The reactions were run in PCR tubes at 65°C for 30 minutes. The completed reactions were then pipetted into the wells of a ten-well PDMS chip, alternating between positive and negative. | ||
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− | < | + | <h4><u><center>For 3M Chip</center></u></h4> |
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<img src="https://static.igem.org/mediawiki/2018/a/a4/T--NYU_Abu_Dhabi--cost7.JPG"class="center"> | <img src="https://static.igem.org/mediawiki/2018/a/a4/T--NYU_Abu_Dhabi--cost7.JPG"class="center"> | ||
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</h2> | </h2> | ||
− | < | + | <h4><u><center>For Sample Collector</center></u></h4> |
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− | < | + | <h4><u><center>For Heating Device<\center></u></h4> |
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Revision as of 21:58, 17 October 2018