Team:MIT phage

From 2010.igem.org

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<table width=70%><tr><td><div id="bodybaby">hairy cells: polymerizing phage</div></td>
<table width=70%><tr><td><div id="bodybaby">hairy cells: polymerizing phage</div></td>
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<tr><td><br><b>Introduction</b>
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<br><b>Overview</b>
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<br><b>Introduction</b>
<br><b>In the context of past iGEM projects</b> and past publications, our project is unique in that..
<br><b>In the context of past iGEM projects</b> and past publications, our project is unique in that..
<br><b>Construction plan, circuit diagram</b>
<br><b>Construction plan, circuit diagram</b>

Revision as of 18:33, 10 October 2010

MIT iGEM 2010

The 2010 MIT iGEM team. We are biological engineers, physicists, electrical engineers, chemical engineers, mathematicians, and computer scientists.
Programmable, Self-constructing Biomaterials

The 2010 MIT iGEM team focused on the control and production of self-constructing and self-repairing living biomaterials through both bacterial and mammalian engineering. We ventured to set up the framework for material formation in both types of cells, for future applications in living, self-repairing materials and in vitro organogenesis respectively.


We have accomplished far beyond what we expected of ourselves! In addition to our project, we have created a new Mammalian Biobrick standard, contributed original parts for mammalian cells and bacteriophage, and we have biobricked two working toggles for the registry.


Introduction
Context
Plan
Results

hairy cells: polymerizing phage

Overview
Introduction
In the context of past iGEM projects and past publications, our project is unique in that..
Construction plan, circuit diagram
Results