Difference between revisions of "Team:MIT"

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<center><h2>We've successfully created new, hormone-inducible mammalian promoters, characterized a miRNA sensing platform in TERT-immortalized human endometrial stromal cells (tHESC) culture under varying estrogen conditions, and tested the functionality of a serine integrase (TP901) in a mammalian line as a biological latch.<br><br>We've spent a long time visualizing how these tools could be used in the long term to help patients with endometriosis.</h2></center><br><br>
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<center><h2>We've successfully created new, hormone-inducible mammalian promoters,<br> characterized a miRNA sensing platform in TERT-immortalized human endometrial stromal cells (tHESC) culture under varying estrogen conditions, <br>and tested the functionality of a serine integrase (TP901) in a mammalian line as a biological latch.<br><br>We've spent a long time visualizing how these tools could be used in the long term to help patients with endometriosis.</h2></center><br><br>
 
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       <img src="https://static.igem.org/mediawiki/2016/6/64/T--MIT--FutureButton.svg" alt="Future work, designs, and collaborations" >
 
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       <span class="text-content"><span><br>We worked with experts in endometriosis to lay out a basic clinical plan, designed a possible full circuit using our synthetic biological parts, and collaborated with the BU Hardware team to test and confirm that mammalian cells can grow in a microfluidics device.<br><br><br><br><br>Read more about the future applications of our work</span></span>
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       <span class="text-content"><span><br>We worked with experts in endometriosis to lay out a basic clinical plan,<br> designed a possible full circuit using our synthetic biological parts,<br> and collaborated with the BU Hardware team to test and confirm that mammalian cells can grow in a microfluidics device.<br><br><br><br><br>Read more about the future applications of our work</span></span>
 
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Revision as of 20:07, 16 October 2016


This diagnostic process can be expedited by using the following synthetic biological tools to sense molecular markers in endometrial biopsy samples.


We've successfully created new, hormone-inducible mammalian promoters,
characterized a miRNA sensing platform in TERT-immortalized human endometrial stromal cells (tHESC) culture under varying estrogen conditions,
and tested the functionality of a serine integrase (TP901) in a mammalian line as a biological latch.

We've spent a long time visualizing how these tools could be used in the long term to help patients with endometriosis.