Team:Cornell

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<div style="text-align: center;"><big><big><big><a href="https://2011.igem.org/Team:Cornell/Recruiting">Click
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<font face="Comic Sans MS"><div style="text-align: center;"><strong><big><big><big>Abstract</big></big></big></strong>
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Cornell’s 2011 iGEM team has designed a new, scalable, and cell-free method to produce complex biomolecules. Current methods for purification from cellular lysate are expensive and time consuming. BioFactory utilizes modified enzymes, capable of being attached to surfaces, in the creation of a modular microfluidic chip for each enzyme. The surface bonding is performed by the well-characterized biotin-avidin mechanism. When combined in series, these chips operate as a linear biochemical pathway for continuous flow reactions. Additionally, we plan to engineer E. coli with the mechanism for light-induced apoptosis to easily lyse cultures producing the necessary enzymes. The resulting lysate is flowed through the microfluidic channels, coating them with the desired enzyme. We believe this chemical synthesis method will reduce unwanted side reactions and lower the costs of producing bio-pharmaceuticals in the future.</p></font>
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=='''Project description'''==
 
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Our current proposed project for the summer is the fabrication of a microfluidic device for the cell-free production of bio-pharmaceuticals by binding the necessary enzymes of the pathway to the surface of the channel. The enzymes would be harvested from cellular lysate created by engineering light-induced cell death in bacterial populations which produce the needed enzymes. Our goal is to automate and simplify the device construction to allow for a scalable mircofluidic factory.
 

Latest revision as of 01:23, 29 October 2011



Home Table
Click for Recruiting!


Abstract

Cornell’s 2011 iGEM team has designed a new, scalable, and cell-free method to produce complex biomolecules. Current methods for purification from cellular lysate are expensive and time consuming. BioFactory utilizes modified enzymes, capable of being attached to surfaces, in the creation of a modular microfluidic chip for each enzyme. The surface bonding is performed by the well-characterized biotin-avidin mechanism. When combined in series, these chips operate as a linear biochemical pathway for continuous flow reactions. Additionally, we plan to engineer E. coli with the mechanism for light-induced apoptosis to easily lyse cultures producing the necessary enzymes. The resulting lysate is flowed through the microfluidic channels, coating them with the desired enzyme. We believe this chemical synthesis method will reduce unwanted side reactions and lower the costs of producing bio-pharmaceuticals in the future.


Project Data
Team Multimedia