Team:Groningen

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Discover our novel approach to environmental biosensing, where synthetic biology intersects with microbial electrochemical systems.
Discover our novel approach to environmental biosensing, where synthetic biology intersects with microbial electrochemical systems.
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<a href="https://2012.igem.org/Team:Cornell/project" class="small button radius">More Info</a>

Revision as of 08:45, 19 July 2013


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<a href="https://2012.igem.org/Team:Cornell/project"><img src="Cornell_Dan_SQ.jpg"></a>

Discover our novel approach to environmental biosensing, where synthetic biology intersects with microbial electrochemical systems.

<a href="https://2012.igem.org/Team:Cornell/project" class="small button radius">More Info</a>


Abstract

The unique properties of silk have provided it with a utility that goes far beyond that of any other natural fibers known to man. Its amazing mechanical properties, 'silky smooth' softness, and bio-compatibility, has led to applications ranging from from simple clothing to high tech biomedical devices.

The industry from which silk is obtained, however, is less than ideal. Scientists have therefore begun to design silk-producing micro-organisms. The 2012 iGEM team from Utah have indeed successfully designed BioBricks for this very purpose. However, these micro-organisms remain inadequate in the secretion of silk, which is a major limiting factor on the range of potential biosynthetic designs and applications.

Our goal is to solve the secretion issue and to use it for the formation of a silk biofilm. The beauty of such a biofilm can be attributed to the properties of silk, and to the fact that any imaginable shape of seamless silk could be created since the biofilm grows in such a way as to fit its mold. We will be exploiting these properties to coat biomedical prosthetic devices, with the goal to prevent infections, and hence to prevent the required operations in dealing with such infections.