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/* background-image: url("https://static.igem.org/mediawiki/2018/d/df/T--NYU_Abu_Dhabi--Homepage.png"); */ | /* background-image: url("https://static.igem.org/mediawiki/2018/d/df/T--NYU_Abu_Dhabi--Homepage.png"); */ | ||
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<button class="tablinks2" onclick="openTab(event, 'biology')">Biology</button> | <button class="tablinks2" onclick="openTab(event, 'biology')">Biology</button> | ||
<button class="tablinks3" onclick="openTab(event, 'engineering')">Engineering</button> | <button class="tablinks3" onclick="openTab(event, 'engineering')">Engineering</button> | ||
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− | <div id="Key | + | <div id="Key Achievements" class="tabcontent"> |
<article> | <article> | ||
<center> | <center> | ||
− | <h2> | + | <br> |
+ | |||
+ | <h4><u><center>Biology</center></u></h4> | ||
+ | <br><br> | ||
+ | <h2>Optimised the protocol for RPA to reduce the reaction volume up to 10 μL. <a href="https://2018.igem.org/Team:NYU_Abu_Dhabi/Biology">Click here for more details.</a> | ||
+ | </h2> | ||
+ | |||
+ | <br> | ||
+ | <img src="https://static.igem.org/mediawiki/2018/1/1e/T--NYU_Abu_Dhabi--key1.JPG"class="center2"> | ||
+ | <br> | ||
+ | |||
+ | <h2>Optimised PCR, LAMP and RPA reactions to achieve the limit of detection of 0.1 ng/μL. <a href="https://2018.igem.org/Team:NYU_Abu_Dhabi/Results">Click here for more details.</a> | ||
+ | </h2> | ||
+ | <br> | ||
+ | |||
+ | <br> | ||
+ | <img src="https://static.igem.org/mediawiki/2018/7/7b/T--NYU_Abu_Dhabi--key3.JPG"class="center"> | ||
+ | <br> | ||
+ | |||
+ | <h4><u><center>Engineering</center></u></h4> | ||
+ | <br><br> | ||
+ | |||
+ | <h2><b><u>Sample collector</u></b>: Developed sterile, easy to use sample collection mechanism for the end user which may be modifiable for any form of diagnostic test. <a href="https://2018.igem.org/Team:NYU_Abu_Dhabi/Engineering">Click here for more details.</a> | ||
+ | </h2> | ||
+ | |||
+ | <br> | ||
+ | <img src="https://static.igem.org/mediawiki/2018/f/f4/T--NYU_Abu_Dhabi--key4.JPG"class="center"> | ||
+ | <br> | ||
+ | |||
+ | <h2><b><u>Microfluidic chip</u></b>: Developed cheap chips with longer shelf life with the ability to test for multiple pathogens (five) at once. <a href="https://2018.igem.org/Team:NYU_Abu_Dhabi/Engineering">Click here for more details.</a> | ||
+ | </h2> | ||
+ | |||
+ | <br> | ||
+ | <img src="https://static.igem.org/mediawiki/2018/a/a7/T--NYU_Abu_Dhabi--key5.JPG"class="center2"> | ||
+ | <br> | ||
+ | |||
+ | <h2><b><u>Visualisation</u></b>: Optimised Blue light to view fluorescence after running the reaction- drastically reducing cost for all diagnostic devices that utilise fluorescence, also ensuring availability of detection for people of all backgrounds. <a href="https://2018.igem.org/Team:NYU_Abu_Dhabi/Engineering">Click here for more details.</a> | ||
+ | </h2> | ||
+ | |||
+ | <br> | ||
+ | <img src="https://static.igem.org/mediawiki/2018/3/3a/T--NYU_Abu_Dhabi--key6.JPG"class="center"> | ||
+ | <br> | ||
+ | |||
+ | |||
+ | <br><br> | ||
</center> | </center> | ||
</article> | </article> | ||
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<article> | <article> | ||
<center> | <center> | ||
− | < | + | <h4><u><center>Abstract</center></u></h4> |
<br><br> | <br><br> | ||
<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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<br> | <br> | ||
− | < | + | <h4><u><center>Results</center></u></h4> |
<h4><ins>PCR</ins></h4> | <h4><ins>PCR</ins></h4> | ||
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<br><br> | <br><br> | ||
− | <h2>Results obtained clearly shows that PCR is sensitive up to 0.1 ng/µl, lowest concentration tested, for all three plasmids tested. Visually, all bands appear to be similarly thick, which shows that, despite the changes in concentration, PCR amplified each DNA in a similar manner. | + | <h2>Results obtained clearly shows that PCR is sensitive up to 0.1 ng/µl, lowest concentration tested, for all three plasmids tested. Visually, all bands appear to be similarly thick, which shows that, despite the changes in concentration, PCR amplified each DNA in a similar manner. |
</h2> | </h2> | ||
− | <h2>Published research has reported PCR to be sensitive up to 3 pg/µl (6). This shows that PCR is a sensitive technique that is able to amplify DNA even at low DNA concentrations. | + | <h2>Published research has reported PCR to be sensitive up to 3 pg/µl (6). This shows that PCR is a sensitive technique that is able to amplify DNA even at low DNA concentrations. |
</h2> | </h2> | ||
<br> | <br> | ||
<h5><i>Specificity (lmo0773, invA and gbpA)</i></h5> | <h5><i>Specificity (lmo0773, invA and gbpA)</i></h5> | ||
− | <h2>Two sets of experiments were carried out to test the specificity of each amplification technique used. In the first set of experiments, the genes used were kept constant, while the primers were varied, while in the second set, the primers were kept constant while the genes were varied. As can be seen in the figure below, PCR was not found to be specific, as the DNA for a specific gene was amplified by primers designed for another gene as well as with primers specific for that gene. | + | <h2>Two sets of experiments were carried out to test the specificity of each amplification technique used. In the first set of experiments, the genes used were kept constant, while the primers were varied, while in the second set, the primers were kept constant while the genes were varied. As can be seen in the figure below, PCR was not found to be specific, as the DNA for a specific gene was amplified by primers designed for another gene as well as with primers specific for that gene. |
</h2> | </h2> | ||
<br> | <br> | ||
<img src="https://static.igem.org/mediawiki/2018/4/48/T--NYU_Abu_Dhabi--Results--Biology_2.JPG"class="center"> | <img src="https://static.igem.org/mediawiki/2018/4/48/T--NYU_Abu_Dhabi--Results--Biology_2.JPG"class="center"> | ||
− | <h2><center><i>Figure 2. Agarose gels (1%) corresponding to PCR specificity reactions carried out on three different genes (a) lmo0733, (b) invA and (c) hipO. The first set of reactions for each gene is done by keeping the gene constant while varying the primers, while the second set of reactions are carried out by varying the gene used while keeping the primers constant. | + | <h2><center><i>Figure 2. Agarose gels (1%) corresponding to PCR specificity reactions carried out on three different genes (a) lmo0733, (b) invA and (c) hipO. The first set of reactions for each gene is done by keeping the gene constant while varying the primers, while the second set of reactions are carried out by varying the gene used while keeping the primers constant. |
</i></center></h2> | </i></center></h2> | ||
<br><br> | <br><br> | ||
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<h4><ins>LAMP</ins></h4> | <h4><ins>LAMP</ins></h4> | ||
− | <h2>Loop-mediated isothermal amplification was performed using primers designed with <a href="http://primerexplorer.jp/lampv5e/index.html">PrimerExplorer</a> for lmo0733, invA, hipO and gbpA. The reaction was run using miniprep DNA and transformed E. Coli colonies to assess if amplification can occur with whole cells. The Agarose gel (1%) shows amplification in all the lanes with miniprep DNA. | + | <h2>Loop-mediated isothermal amplification was performed using primers designed with <a href="http://primerexplorer.jp/lampv5e/index.html">PrimerExplorer</a> for lmo0733, invA, hipO and gbpA. The reaction was run using miniprep DNA and transformed E. Coli colonies to assess if amplification can occur with whole cells. The Agarose gel (1%) shows amplification in all the lanes with miniprep DNA. |
</h2> | </h2> | ||
<br> | <br> | ||
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<h2><center><i>Figure 3. Agarose gel (1%) showing LAMP amplification of invA, gbpA and <i>lmo0733</i> miniprep DNA with designed LAMP primers (PrimerExplorer). Amplification is seen for <i>lmo0733</i> and gbpA but not invA when gene transformed E. Coli colonies were used. (Lane 1) 500 bp ladder; (Lane 2) invA miniprep + invA LAMP primers; (Lane 3) Nuclease-free water + invA LAMP primers; (Lane 4) invA transformed E. Coli colony + invA LAMP primers; (Lane 5) gbpA miniprep + gbpA LAMP primers; (Lane 6) Nuclease-free water + gbpA LAMP primers; (Lane 7) gbpA transformed E. Coli colony + gbpA LAMP primers; (Lane 8) <i>lmo0733</i> miniprep + <i>lmo0733</i> LAMP primers; (Lane 9) Nuclease-free water + <i>lmo0733</i> LAMP primers; (Lane 10) <i>lmo0733</i> transformed E. Coli colony + <i>lmo0733</i> LAMP primers. | <h2><center><i>Figure 3. Agarose gel (1%) showing LAMP amplification of invA, gbpA and <i>lmo0733</i> miniprep DNA with designed LAMP primers (PrimerExplorer). Amplification is seen for <i>lmo0733</i> and gbpA but not invA when gene transformed E. Coli colonies were used. (Lane 1) 500 bp ladder; (Lane 2) invA miniprep + invA LAMP primers; (Lane 3) Nuclease-free water + invA LAMP primers; (Lane 4) invA transformed E. Coli colony + invA LAMP primers; (Lane 5) gbpA miniprep + gbpA LAMP primers; (Lane 6) Nuclease-free water + gbpA LAMP primers; (Lane 7) gbpA transformed E. Coli colony + gbpA LAMP primers; (Lane 8) <i>lmo0733</i> miniprep + <i>lmo0733</i> LAMP primers; (Lane 9) Nuclease-free water + <i>lmo0733</i> LAMP primers; (Lane 10) <i>lmo0733</i> transformed E. Coli colony + <i>lmo0733</i> LAMP primers. | ||
</i></center></h2> | </i></center></h2> | ||
− | <br>< | + | <br><br> |
<img src="https://static.igem.org/mediawiki/2018/b/b4/T--NYU_Abu_Dhabi--Results--Biology_4.JPG"class="center"> | <img src="https://static.igem.org/mediawiki/2018/b/b4/T--NYU_Abu_Dhabi--Results--Biology_4.JPG"class="center"> | ||
<h2><center><i>Figure 4. Agarose gel (1%) showing LAMP amplification of gbpA with non colorimetric reaction mastermix (MM) (Optigene) with either hydroxy naphthol blue (HNB) or SYBR green added and with colorimetric reaction mastermix (NEB). (Lane 1) 500 bp ladder; (Lane 2) gbpA + Optigene MM + gbpA LAMP primers + HNB; (Lane 3) nuclease free water + Optigene MM + gbpA primers + HNB; (Lane 4) gbpA + Optigene MM + gbpA LAMP primers + SYBR green; (Lane 5) Nuclease free water + Optigene MM + gbpA LAMP primers + SYBR green; (Lane 6) gbpA + NEB MM + gbpA LAMP primers; (Lane 7) Nuclease free water + NEB MM + gbpA LAMP primers. | <h2><center><i>Figure 4. Agarose gel (1%) showing LAMP amplification of gbpA with non colorimetric reaction mastermix (MM) (Optigene) with either hydroxy naphthol blue (HNB) or SYBR green added and with colorimetric reaction mastermix (NEB). (Lane 1) 500 bp ladder; (Lane 2) gbpA + Optigene MM + gbpA LAMP primers + HNB; (Lane 3) nuclease free water + Optigene MM + gbpA primers + HNB; (Lane 4) gbpA + Optigene MM + gbpA LAMP primers + SYBR green; (Lane 5) Nuclease free water + Optigene MM + gbpA LAMP primers + SYBR green; (Lane 6) gbpA + NEB MM + gbpA LAMP primers; (Lane 7) Nuclease free water + NEB MM + gbpA LAMP primers. | ||
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<img src="https://static.igem.org/mediawiki/2018/4/4d/T--NYU_Abu_Dhabi--Results--Biology_5.JPG"class="center"> | <img src="https://static.igem.org/mediawiki/2018/4/4d/T--NYU_Abu_Dhabi--Results--Biology_5.JPG"class="center"> | ||
<h2><center><i>Figure 5. Visualization of SYBR green at 302 nm and 365 nm for <i>lmo0733</i> LAMP reaction.</i></center></h2> | <h2><center><i>Figure 5. Visualization of SYBR green at 302 nm and 365 nm for <i>lmo0733</i> LAMP reaction.</i></center></h2> | ||
− | |||
<br><br> | <br><br> | ||
+ | <h2>No fluorescence was detected in the absence of SYBR green. Background fluorescence was observed in the negative controls. A clear distinction was observed between positive and negative controls. </h2> | ||
+ | <br> | ||
<img src="https://static.igem.org/mediawiki/2018/8/8c/T--NYU_Abu_Dhabi--Results--Biology_6.JPG"class="center"> | <img src="https://static.igem.org/mediawiki/2018/8/8c/T--NYU_Abu_Dhabi--Results--Biology_6.JPG"class="center"> | ||
− | <h2><center><i>Figure 6. Visualization of SYBR green at 302 nm and 365 nm for <i>invA</i> LAMP reaction | + | <h2><center><i>Figure 6. Visualization of SYBR green at 302 nm and 365 nm for <i>invA</i> LAMP reaction</i></center></h2> |
− | + | ||
<br><br> | <br><br> | ||
+ | <h2>Results obtained matched the experiment performed with <i>lmo0733</i>. 1000X SYBR Green was determined to be the optimal concentration and 365 nm seemed to produce the best images for visualization of LAMP amplification.</h2> | ||
+ | <br> | ||
<h5><i>SYBR Green Visualization</i></h5> | <h5><i>SYBR Green Visualization</i></h5> | ||
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<h5><i>Colorimetric Test: Real Sample Swab and Amplification</i></h5> | <h5><i>Colorimetric Test: Real Sample Swab and Amplification</i></h5> | ||
− | <h2>To test the working principles of the <i>Pathogene</i> pathogen project, it had to be established that the intra-lab amplification techniques would be effective on real world samples of contaminated food, water, surfaces etc. Two samples of beef were prepared for the purposes of determining the colorimetric visualization of results for LAMP, in particular the use of NEB WarmStart Colorimetric Mastermix. A sample of untreated store-bought beef was prepared alongside a sample of DH5-alpha cells transformed with the lmo0733 gene from <i>Listeria Monocytogenes</i>. Direct swabs were taken from each sample and used in the LAMP reactions. Reactions lacking the target gene appear a bright red colour whereas reaction mixes containing the amplified gene appear salmon to yellow in colour. | + | <h2>To test the working principles of the <i>Pathogene</i> pathogen project, it had to be established that the intra-lab amplification techniques would be effective on real world samples of contaminated food, water, surfaces etc. Two samples of beef were prepared for the purposes of determining the colorimetric visualization of results for LAMP, in particular the use of NEB WarmStart Colorimetric Mastermix. A sample of untreated store-bought beef was prepared alongside a sample of DH5-alpha cells transformed with the lmo0733 gene from <i>Listeria Monocytogenes</i>. Direct swabs were taken from each sample and used in the LAMP reactions. Reactions lacking the target gene appear a bright red colour whereas reaction mixes containing the amplified gene appear salmon to yellow in colour. |
</h2> | </h2> | ||
<br> | <br> | ||
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<br> | <br> | ||
<img src="https://static.igem.org/mediawiki/2018/1/14/T--NYU_Abu_Dhabi--Results--Biology_13.JPG"class="center"> | <img src="https://static.igem.org/mediawiki/2018/1/14/T--NYU_Abu_Dhabi--Results--Biology_13.JPG"class="center"> | ||
− | <h2><center><i>Figure 13. The SYBR Green fluorescence of the <i>hipO</i> serial dilutions represented under <b>(a)</b> UV light (365 nm) <b>(b)</b> Blue light <b>(c)</b> under Blue light with overexposure demonstrates. | + | <h2><center><i>Figure 13. The SYBR Green fluorescence of the <i>hipO</i> serial dilutions represented under <b>(a)</b> UV light (365 nm) <b>(b)</b> Blue light <b>(c)</b> under Blue light with overexposure demonstrates. |
</i></center></h2> | </i></center></h2> | ||
<br><br> | <br><br> | ||
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<h5><i>LAMP Specificity (lmo0773, invA and gbpA)</i></h5> | <h5><i>LAMP Specificity (lmo0773, invA and gbpA)</i></h5> | ||
− | <h2>The same two experiments done with PCR were done with LAMP. The results obtained indicate that LAMP is highly specific as every gene was only amplified by its primers and not by any other primers. LAMP was found to be the only completely specific technique out of PCR, LAMP and RPA. | + | <h2>The same two experiments done with PCR were done with LAMP. The results obtained indicate that LAMP is highly specific as every gene was only amplified by its primers and not by any other primers. LAMP was found to be the only completely specific technique out of PCR, LAMP and RPA. |
</h2> | </h2> | ||
<br> | <br> | ||
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<h2><center><i>Figure 15. Agarose gel (3%) showing RPA amplification of <i>lmo0733</i>, <i>invA</i> and <i>gbpA</i> miniprep DNA and transformed <i>E. coli</i> colonies in 50 ul volume reactions. The light bands seen in the negative control lanes are primer dimers and proteins from the RPA reaction. (Lane 1) 100 bp ladder; (Lane 2) <i>lmo0733</i> miniprep + <i>lmo0733</i> RPA primers; (Lane 3) <i>lmo0733</i> transformed <i>E. coli</i> colony + <i>lmo0733</i> RPA primers; (Lane 4) <i>lmo0733</i> negative control; (Lane 5) <i>invA</i> miniprep + <i>invA</i> RPA primers; (Lane 6) <i>invA</i> transformed <i>E. coli</i> colony + <i>invA</i> RPA primers; (Lane 7) <i>invA</i> negative control; (Lane 8) <i>gbpA</i> miniprep + <i>gbpA</i> RPA primers; (Lane 9) <i>gbpA</i> transformed <i>E. coli</i> colony + <i>gbpA</i> RPA primers; (Lane 10) <i>gbpA</i> negative control; (Lane 11) 500 bp ladder | <h2><center><i>Figure 15. Agarose gel (3%) showing RPA amplification of <i>lmo0733</i>, <i>invA</i> and <i>gbpA</i> miniprep DNA and transformed <i>E. coli</i> colonies in 50 ul volume reactions. The light bands seen in the negative control lanes are primer dimers and proteins from the RPA reaction. (Lane 1) 100 bp ladder; (Lane 2) <i>lmo0733</i> miniprep + <i>lmo0733</i> RPA primers; (Lane 3) <i>lmo0733</i> transformed <i>E. coli</i> colony + <i>lmo0733</i> RPA primers; (Lane 4) <i>lmo0733</i> negative control; (Lane 5) <i>invA</i> miniprep + <i>invA</i> RPA primers; (Lane 6) <i>invA</i> transformed <i>E. coli</i> colony + <i>invA</i> RPA primers; (Lane 7) <i>invA</i> negative control; (Lane 8) <i>gbpA</i> miniprep + <i>gbpA</i> RPA primers; (Lane 9) <i>gbpA</i> transformed <i>E. coli</i> colony + <i>gbpA</i> RPA primers; (Lane 10) <i>gbpA</i> negative control; (Lane 11) 500 bp ladder | ||
</i></center></h2> | </i></center></h2> | ||
+ | <br><br> | ||
<h2>RPA reactions worked successfully for 50 ul reactions. To save lab reagents in experiments and to make the microfluidic chips economical in terms of resources, further experiments were carried out to test RPA reactions at lower volumes, i.e. 25 ul and 10 ul. | <h2>RPA reactions worked successfully for 50 ul reactions. To save lab reagents in experiments and to make the microfluidic chips economical in terms of resources, further experiments were carried out to test RPA reactions at lower volumes, i.e. 25 ul and 10 ul. | ||
</h2> | </h2> | ||
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<h2><center><i>Figure 16. Agarose gel (3%) showing RPA amplification of <i>invA</i> and <i>gbpA</i> miniprep DNA and negative controls in 25 ul volume reactions. The light bands seen in the negative control lanes are primer dimers and proteins from the RPA reaction. (Lane 1) 100 bp ladder; (Lane 2) <i>invA</i> miniprep + <i>invA</i> RPA primers; (Lane 3) <i>invA</i> negative control; (Lane 4) <i>gbpA</i> miniprep + <i>gbpA</i> RPA primers; (Lane 5) <i>gbpA</i> negative control. | <h2><center><i>Figure 16. Agarose gel (3%) showing RPA amplification of <i>invA</i> and <i>gbpA</i> miniprep DNA and negative controls in 25 ul volume reactions. The light bands seen in the negative control lanes are primer dimers and proteins from the RPA reaction. (Lane 1) 100 bp ladder; (Lane 2) <i>invA</i> miniprep + <i>invA</i> RPA primers; (Lane 3) <i>invA</i> negative control; (Lane 4) <i>gbpA</i> miniprep + <i>gbpA</i> RPA primers; (Lane 5) <i>gbpA</i> negative control. | ||
</i></center></h2> | </i></center></h2> | ||
− | |||
− | |||
<br><br> | <br><br> | ||
+ | <h2>The reaction volume for RPA was successfully optimized to a total volume of 25 ul. This allowed for economical use of reagents in lab experiments and for use in microfluidic chips. | ||
+ | </h2> | ||
+ | <br> | ||
<h5><i>Reaction volume: 10 uL reaction</i></h5> | <h5><i>Reaction volume: 10 uL reaction</i></h5> | ||
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</i></center></h2> | </i></center></h2> | ||
<br><br> | <br><br> | ||
− | <h2>The reaction volume for RPA was successfully optimized to a total volume of 10 µl. The agarose gel (3%) shows brighter bands for <i>gbpA</i> and <i>lmo0733</i> compared to <i>invA</i>. This allowed for economical use of reagents in lab experiments and for use in microfluidic chips. | + | <h2>The reaction volume for RPA was successfully optimized to a total volume of 10 µl. The agarose gel (3%) shows brighter bands for <i>gbpA</i> and <i>lmo0733</i> compared to <i>invA</i>. This allowed for economical use of reagents in lab experiments and for use in microfluidic chips. |
</h2> | </h2> | ||
<br> | <br> | ||
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<img src="https://static.igem.org/mediawiki/2018/a/a4/T--NYU_Abu_Dhabi--Results--Biology_18.JPG"class="center"> | <img src="https://static.igem.org/mediawiki/2018/a/a4/T--NYU_Abu_Dhabi--Results--Biology_18.JPG"class="center"> | ||
<h2><center><i>Figure 18. Visualization of SYBR green at 302 nm and 365 nm for <i>invA</i> RPA reaction</h2> | <h2><center><i>Figure 18. Visualization of SYBR green at 302 nm and 365 nm for <i>invA</i> RPA reaction</h2> | ||
+ | <br><br> | ||
<h2>No fluorescence was detected in the absence of SYBR green. Minimal background fluorescence was observed in the negative controls. A clear distinction was observed between positive and negative controls. 1000X SYBR Green was determined to be the optimal concentration and 365 nm seemed to produce the best images for visualization of LAMP amplification. | <h2>No fluorescence was detected in the absence of SYBR green. Minimal background fluorescence was observed in the negative controls. A clear distinction was observed between positive and negative controls. 1000X SYBR Green was determined to be the optimal concentration and 365 nm seemed to produce the best images for visualization of LAMP amplification. | ||
</i></center></h2> | </i></center></h2> | ||
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<br><br> | <br><br> | ||
<h2>Background fluorescence was observed in the negative controls. However, a clear distinction was observed between positive and negative controls. | <h2>Background fluorescence was observed in the negative controls. However, a clear distinction was observed between positive and negative controls. | ||
− | </h2> | + | </h2> |
<br> | <br> | ||
<img src="https://static.igem.org/mediawiki/2018/a/a2/T--NYU_Abu_Dhabi--Results--Biology_20.JPG"class="center"> | <img src="https://static.igem.org/mediawiki/2018/a/a2/T--NYU_Abu_Dhabi--Results--Biology_20.JPG"class="center"> | ||
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<h5><i>Specificity</i></h5> | <h5><i>Specificity</i></h5> | ||
− | <h2>The two specificity experiments were done with RPA for the two genes, <i>lmo0733</i> and <i>invA</i>. The results shown in the Figure below, show that RPA is not as specific as LAMP as amplification of a gene with primers designed for another gene does occur. This could be due to the fact that RPA uses the longest primers out of all three techniques, resulting in a higher possibility of having regions of the primers complementary to different genes. | + | <h2>The two specificity experiments were done with RPA for the two genes, <i>lmo0733</i> and <i>invA</i>. The results shown in the Figure below, show that RPA is not as specific as LAMP as amplification of a gene with primers designed for another gene does occur. This could be due to the fact that RPA uses the longest primers out of all three techniques, resulting in a higher possibility of having regions of the primers complementary to different genes. |
</h2> | </h2> | ||
<br> | <br> | ||
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<center> | <center> | ||
− | < | + | <h4><u><center>Sample Collector</center></u></h4> |
<br><br> | <br><br> | ||
<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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<br> | <br> | ||
− | < | + | <h4><u><center>Heating Device</center></u></h4> |
<br><br> | <br><br> | ||
− | <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 |
green LED light lights up, signaling that the power is connected. The 6 blue LED lights that aids visualization will also be on. In the second mode (for RPA reaction), one red LED light turns on, and the heating board heats up to 40° C. In the third mode (for LAMP reaction), two red LED lights turn on and the heating board heats up to 65° C. A temperature sensor is closely attached to the heating board and helps ensure that the temperature is maintained as desired. A power bank that consists of a 9V rechargeable battery is used as the power supply for the device. The user can just connect the power bank to the device for the device to start operating. | green LED light lights up, signaling that the power is connected. The 6 blue LED lights that aids visualization will also be on. In the second mode (for RPA reaction), one red LED light turns on, and the heating board heats up to 40° C. In the third mode (for LAMP reaction), two red LED lights turn on and the heating board heats up to 65° C. A temperature sensor is closely attached to the heating board and helps ensure that the temperature is maintained as desired. A power bank that consists of a 9V rechargeable battery is used as the power supply for the device. The user can just connect the power bank to the device for the device to start operating. | ||
</h2> | </h2> | ||
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<br> | <br> | ||
− | < | + | <h4><u><center>The Microfluidics</center></u></h4> |
<br><br> | <br><br> | ||
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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> | ||
<br> | <br> | ||
− | < | + | <h4><u><center>Sample Collector</center></u></h4> |
<br><br> | <br><br> | ||
<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> | ||
<br> | <br> | ||
− | < | + | <h4><u><center>Chip Flow</center></u></h4> |
<br><br> | <br><br> | ||
<img src="https://static.igem.org/mediawiki/2018/7/77/T--NYU_Abu_Dhabi--proof5.JPG"class="center"> | <img src="https://static.igem.org/mediawiki/2018/7/77/T--NYU_Abu_Dhabi--proof5.JPG"class="center"> | ||
− | <h2><center><i>Figure 7. Testing flow of liquid in the first | + | <h2><center><i>Figure 7. Testing flow of liquid in the first 3M film chip |
</i></center></h2> | </i></center></h2> | ||
<br> | <br> | ||
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<br> | <br> | ||
<img src="https://static.igem.org/mediawiki/2018/b/b7/T--NYU_Abu_Dhabi--proof6.JPG"class="center"> | <img src="https://static.igem.org/mediawiki/2018/b/b7/T--NYU_Abu_Dhabi--proof6.JPG"class="center"> | ||
− | <h2><center><i>Figure 8. Testing flow of liquid in the 3M chip | + | <h2><center><i>Figure 8. Testing flow of liquid in the 3M film chip |
</i></center></h2> | </i></center></h2> | ||
<br> | <br> | ||
<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> | ||
<br> | <br> | ||
− | < | + | <h4><u><center>Amplification</center></u></h4> |
<br><br> | <br><br> | ||
<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> | ||
<br> | <br> | ||
− | <h2>Next, the four RPA reactions were carried out in a 3M chip. For one RPA reaction, 29.5µl of re-hydration buffer was added to one tube of dried reaction, along with 2.4µl forward primers, 2,4 µl backward primers, 8.2µl of water, 5µl of DNA, 1µl of 1000X SBYR Green and 2.5µl of Magnesium acetate. The primers were replaced with an equal volume of water for the two negative control reactions. | + | <h2>Next, the four RPA reactions were carried out in a 3M chip. For one RPA reaction, 29.5µl of re-hydration buffer was added to one tube of dried reaction, along with 2.4µl forward primers, 2,4 µl backward primers, 8.2µl of water, 5µl of DNA, 1µl of 1000X SBYR Green and 2.5µl of Magnesium acetate. The primers were replaced with an equal volume of water for the two negative control reactions. |
</h2> | </h2> | ||
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</i></center></h2> | </i></center></h2> | ||
<br> | <br> | ||
− | < | + | <h4><u><center>Heating Device</center></u></h4> |
<br><br> | <br><br> | ||
− | <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 |
− | green LED light lights up, signaling that the power is connected. The 6 blue LED lights that aids visualization will also be on. In the second mode (for RPA reaction), one red LED light turns on, and the heating board heats up to and maintains at approximately 40°C. In the third mode (for LAMP reaction), two red LED lights turn on and the heating board heats up to and maintains at approximately 65°C. A temperature sensor is closely attached to the heating board and helps ensure that the temperature is maintained as desired. | + | green LED light lights up, signaling that the power is connected. The 6 blue LED lights that aids visualization will also be on. In the second mode (for RPA reaction), one red LED light turns on, and the heating board heats up to and maintains at approximately 40°C. In the third mode (for LAMP reaction), two red LED lights turn on and the heating board heats up to and maintains at approximately 65°C. A temperature sensor is closely attached to the heating board and helps ensure that the temperature is maintained as desired. |
</h2> | </h2> | ||
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</i></center></h2> | </i></center></h2> | ||
<br> | <br> | ||
− | < | + | <h4><u><center>Visualization</center></u></h4> |
<br><br> | <br><br> | ||
− | <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. |
</h2> | </h2> | ||
<h2> | <h2> | ||
− | The objective of this was to ensure that fluorescence could be observed in the PDMS chip under blue light. Moreover, this was done to illustrate the difference in fluorescence between positive and negative controls. | + | The objective of this was to ensure that fluorescence could be observed in the PDMS chip under blue light. Moreover, this was done to illustrate the difference in fluorescence between positive and negative controls. |
</h2> | </h2> | ||
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</i></center></h2> | </i></center></h2> | ||
<br> | <br> | ||
− | <h2>The same process was repeated using 3M chips. 10 reactions, 5 positive and 5 negative were carried out in PCR tubes and pipetted into a 3M chip to check visualization. The results are shown in Figure shown below, as visualized under blue light. | + | <h2>The same process was repeated using 3M chips. 10 reactions, 5 positive and 5 negative were carried out in PCR tubes and pipetted into a 3M chip to check visualization. The results are shown in Figure shown below, as visualized under blue light. |
</h2> | </h2> | ||
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<center> | <center> | ||
− | < | + | <h4><u><center>For 3M Chip</center></u></h4> |
− | < | + | <br> |
<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"> | ||
<h2>Reagents required per chip (10 reactions): | <h2>Reagents required per chip (10 reactions): | ||
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</h2> | </h2> | ||
− | < | + | <h4><u><center>For Sample Collector</center></u></h4> |
− | < | + | <br> |
<br> | <br> | ||
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<br> | <br> | ||
− | < | + | <h4><u><center>For Heating Device</center></u></h4> |
− | < | + | <br> |
<br> | <br> | ||
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<div class="dropdown-menu" aria-labelledby="navbarDropdown"> | <div class="dropdown-menu" aria-labelledby="navbarDropdown"> | ||
<a class="dropdown-item" href="https://2018.igem.org/Team:NYU_Abu_Dhabi/Description">Description</a> | <a class="dropdown-item" href="https://2018.igem.org/Team:NYU_Abu_Dhabi/Description">Description</a> | ||
− | + | ||
<a class="dropdown-item" href="https://2018.igem.org/Team:NYU_Abu_Dhabi/Demonstrate">Demonstration</a> | <a class="dropdown-item" href="https://2018.igem.org/Team:NYU_Abu_Dhabi/Demonstrate">Demonstration</a> | ||
<a class="dropdown-item" href="https://2018.igem.org/Team:NYU_Abu_Dhabi/Results">Results</a> | <a class="dropdown-item" href="https://2018.igem.org/Team:NYU_Abu_Dhabi/Results">Results</a> |
Latest revision as of 22:40, 17 October 2018