Difference between revisions of "Team:Freiburg/Diagnostics"

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<h1 class="sectionedit1">Diagnostics today</h1>
 
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The detection of antibodies in a blood sample is a versatile and widely applied method of today's diagnostics <sup><a class="fn_top" href="#fn__1" id="fnt__1" name="fnt__1">1)</a></sup> <sup><a class="fn_top" href="#fn__2" id="fnt__2" name="fnt__2">2)</a></sup>. Common methods include ELISA-assays which either rely on the capture of disease antigens by immobilized antibodies (Sandwich and competitive ELISA) or on the direct immobilization of these antigens beforehand<sup><a class="fn_top" href="#fn__3" id="fnt__3" name="fnt__3">3)</a></sup>. Both methods require stable conditions for handling and storage of the plates as test reliability is crucially dependent on native-state proteins. Maintaining these conditions is already quite expensive under European standards, but becomes elaborate when working in tropical or arid regions.
 
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Especially in those regions, where hospitals are mostly hard to reach and local medical treatment seldom relies on physicians, it is necessary to reliably distinguish between different illnesses as fast as possible. The treatment of potential epidemic pathogens requires an enormous logistic effort and differential diagnosis of a less potent pathogen may save thousands of dollars and prevent fear among people. Thus, it would be beneficial to have a large library of known antigens that is easy and cost-effective to store and to ship, but nonetheless functions as a reliable selective tool in diagnostics.
 
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Our idea of how to deal with this problem is to use the unique properties of DNA as reliable information storage and combine it with cell-free expression inside the detection device. The antigens produced directly before diagnosis are not only less prone to denaturation, but are also enriched on the array in the device by a specific surface. Antibodies potentially present in the patient's blood are then observed by a new kind of detection method called iRIf.
 
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<a class="wikilink1" href="https://2015.igem.org/Team:Freiburg/Project/Overview" title="project_overview">Find out more about our project</a>
 
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<a class="wikilink1" href="/igem2015/doku.php?id=tag:info&amp;do=showtag&amp;tag=info" rel="tag" title="tag:info">info</a>
 
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<div class="fn"><sup><a class="fn_bot" href="#fnt__1" id="fn__1" name="fn__1">1)</a></sup>
 
<a class="urlextern" href="http://www.who.int/diagnostics_laboratory/faq/elisa/en/" rel="nofollow" target="_Blank" title="http://www.who.int/diagnostics_laboratory/faq/elisa/en/">WHO info page on ELISA</a></div>
 
<div class="fn"><sup><a class="fn_bot" href="#fnt__2" id="fn__2" name="fn__2">2)</a></sup>
 
Kaushik, A. et al., 2015. Towards detection and diagnosis of Ebola virus disease at point-of-care. Biosensors &amp; bioelectronics, 75, pp.254–272.</div>
 
<div class="fn"><sup><a class="fn_bot" href="#fnt__3" id="fn__3" name="fn__3">3)</a></sup>
 
Schuurs, A.H. &amp; van Weemen, B.K., 1980. Enzyme-immunoassay: a powerful analytical tool. Journal of immunoassay, 1(2), pp.229–49. </div>
 
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Latest revision as of 00:28, 12 September 2015