Team:UT Dallas/Project

From 2011.igem.org

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Latest revision as of 23:59, 5 September 2011

biz solution

Overview

The human bowel hosts a rich diversity of symbiotic microflora that provides a powerful engineering platform for intelligent probiotics. These “immunobots” will ideally work in-sync and enhance natural self-repair mechanisms for a range of intestinal diseases associated with tissue damage. Towards this end, we engineered a bacterial chemotaxis pathway that utilizes a chimeric receptor to successfully interface with the immune system. In addition, we introduced an inducible secondary bacterial population that can trigger system-wide self-destruction, conferring an additional level of user control. Each module of our system was characterized using fluorescent reporters and the integrated parts were evaluated by controlled experiments involving wound signal gradients. We envision a probiotic solution that can facilitate localized tissue repair for damage resulting from inflammatory bowel diseases, including ulcerative colitis and Crohn’s disease.

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UT Dallas

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Notebook

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          <li><a href="https://2011.igem.org/Team:UT_Dallas/Notebook"><font size="3" face="verdana">Notebook</a></font></li>
          <li><a href="https://2011.igem.org/Team:UT_Dallas/HumanPractices"><font size="3" face="verdana">Human Practices</a></font></li>
-         <li><a href="https://2011.igem.org/Team:UT_Dallas/Gallery"><font size="3" face="verdana">Gallery</a></font></li>
+         <li><a href="https://2011.igem.org/Team:UT_Dallas/Safety"><font size="3" face="verdana">Safety</a></font></li>
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-           <h2><span>Project Description</span></h2>
+           <h2><span>Overview</span></h2>
-           <p> <font size="3" face="verdana">Tissue damage characterizes a range of medical conditions that can be particularly difficult to manage without restrictively risky or expensive intervention. The human body hosts a rich diversity of symbiotic microflora that provides a powerful engineering platform for synthetic bacterial systems. We aim to construct a probiotic solution that successfully interfaces with the immune system to facilitate localized tissue repair.</font></p><br></br>
+           <p> <font size="3" face="verdana">The human bowel hosts a rich diversity of symbiotic microflora that provides a powerful engineering platform for intelligent probiotics. These “immunobots” will ideally work in-sync and enhance natural self-repair mechanisms for a range of intestinal diseases associated with tissue damage. Towards this end, we engineered a bacterial chemotaxis pathway that utilizes a chimeric receptor to successfully interface with the immune system. In addition, we introduced an inducible secondary bacterial population that can trigger system-wide self-destruction, conferring an additional level of user control. Each module of our system was characterized using fluorescent reporters and the integrated parts were evaluated by controlled experiments involving wound signal gradients. We envision a probiotic solution that can facilitate localized tissue repair for damage resulting from inflammatory bowel diseases, including ulcerative colitis and Crohn’s disease.
-<p>add diagram</p>
+</font></p><br></br>
-<p></p><p><font size = "3" face = "verdana">Click on the links to in the sidebar to learn more about our project.</font><p>
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