Team:USTC CHINA/Project/Overview

From 2013.igem.org

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         <div id="overview-bar" class="basic-bar">
         <div id="overview-bar" class="basic-bar">
         <h1>Overview</h1>
         <h1>Overview</h1>
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         <p>In our world, billions of people suffer from contagion. However, only parts of them can be prevented by proper vaccines. Many disadvantages limit the usage of traditional vaccines especially in developing countries. </p>
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         <p>In our world, billions of people are suffering from contagion. However, only a fraction of contagion can be prevented by the existing vaccines. The disadvantages of traditional vaccines limit their usage especially in developing countries. </p>
<div align="center"><img src="https://static.igem.org/mediawiki/igem.org/e/ec/2013ustc-china_traditional_vaccine_transport.jpg" width="400" height="300" />
<div align="center"><img src="https://static.igem.org/mediawiki/igem.org/e/ec/2013ustc-china_traditional_vaccine_transport.jpg" width="400" height="300" />
<div class="atfigure" align="center" style="width:400px;font-size:14px;">Fig1. hard shipping in some area </div></div>
<div class="atfigure" align="center" style="width:400px;font-size:14px;">Fig1. hard shipping in some area </div></div>
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<p>This year, our project focused on a revolutionary vaccine delivery. We chose Bacillus subtilis as chassis to establish a transdermal vaccine fresh secreting band-aid which consists of four engineering B.subtilis, each of which carried a gene circuit independently.</p>
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<p>This year, our project focused on a revolutionary vaccine delivery. We chose Bacillus subtilis as chassis to establish a band-aid secreting fresh transdermal vaccine consisting of four engineering B.subtilis, each of which carried a gene circuit independently.</p>
<div align="center"><img src="https://static.igem.org/mediawiki/2013/archive/e/ed/20130923171924!2013igemustc_Standardization.png" width="400" height="350" />
<div align="center"><img src="https://static.igem.org/mediawiki/2013/archive/e/ed/20130923171924!2013igemustc_Standardization.png" width="400" height="350" />
<div class="atfigure" align="center" style="width:400px;font-size:14px;">Fig2. block-based design </div></div>
<div class="atfigure" align="center" style="width:400px;font-size:14px;">Fig2. block-based design </div></div>
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<p>By using an excellent transdermal peptide TD1, three of them could express a series of fusion proteins(antigen, 2 kinds of adjuvants) which could penetrate the skin and work as traditional vaccine molecule.The fourth type is our “reporter” which could notify users whether the band-aid works well and when they could stick or tear off the patch. Moreover, we designed a reliable suicide system in Bacillus subtilis for the very first time in iGEM. So it would be OK if our users tear patches off and throw them away. Cheap and convenient, we just created a world without needle. </p>   
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<p>With an excellent transdermal peptide TD1, three of the engineering B.subtilis could express a series of fusion proteins (the antigen and 2 kinds of adjuvants) which could penetrate the skin and work as traditional vaccine molecules. The fourth bacteria are our “reporter” which would notify users when the band-aid is working well and the patch can be pasted or tore off. Moreover, we designed a reliable suicide system in Bacillus subtilis for the very first time in iGEM. So it would be OK when the patches are thrown away into the environment. Cheap and convenient, we created a world without needle. </p>   
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Revision as of 13:49, 27 September 2013

Overview

In our world, billions of people are suffering from contagion. However, only a fraction of contagion can be prevented by the existing vaccines. The disadvantages of traditional vaccines limit their usage especially in developing countries.

Fig1. hard shipping in some area

This year, our project focused on a revolutionary vaccine delivery. We chose Bacillus subtilis as chassis to establish a band-aid secreting fresh transdermal vaccine consisting of four engineering B.subtilis, each of which carried a gene circuit independently.

Fig2. block-based design

With an excellent transdermal peptide TD1, three of the engineering B.subtilis could express a series of fusion proteins (the antigen and 2 kinds of adjuvants) which could penetrate the skin and work as traditional vaccine molecules. The fourth bacteria are our “reporter” which would notify users when the band-aid is working well and the patch can be pasted or tore off. Moreover, we designed a reliable suicide system in Bacillus subtilis for the very first time in iGEM. So it would be OK when the patches are thrown away into the environment. Cheap and convenient, we created a world without needle.