Team:MIT overview

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<tr><td><br>Materials technology is a rapidly advancing field with research focusing on new methods of nanomaterial design. The biggest problem with nanomaterials is that the creators (us) are on a completely different length scale when compared to the materials we venture to create. Our project strives to take small steps in the direction of nanomaterials by utilizing cells--both bacterial and mammalian--and bacteriophage as units in developing a living, self-assembling, dynamic biomaterial.
<tr><td><br>Materials technology is a rapidly advancing field with research focusing on new methods of nanomaterial design. The biggest problem with nanomaterials is that the creators (us) are on a completely different length scale when compared to the materials we venture to create. Our project strives to take small steps in the direction of nanomaterials by utilizing cells--both bacterial and mammalian--and bacteriophage as units in developing a living, self-assembling, dynamic biomaterial.
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Our goal is to create a system within cells that can convert a 2D design visible to the human eye into a 3D biostructure of phage or bone with the cross section of that same design. Our cells will be able to sense elements of the macro, human world, and output a living, self-assembled structure. Our mammalian team was motivated by the idea of the cellular “touch pad,” and is utilizing mechano-sensing promoters to allow mammalian cells to sense pressure and produce a controlled mineralization in response. The bacterial team is using the S.O.S. response from UV radiation and quorum sensing as stimuli to have bacteria secrete bacteriophage. Coated with zipper proteins, these bacteriophage can polymerize, cross-link and eventually form a living structure.  Both teams are integrating a toggle switch into the system, allowing us to consistently control the cell’s response to the stimuli.
Our goal is to create a system within cells that can convert a 2D design visible to the human eye into a 3D biostructure of phage or bone with the cross section of that same design. Our cells will be able to sense elements of the macro, human world, and output a living, self-assembled structure. Our mammalian team was motivated by the idea of the cellular “touch pad,” and is utilizing mechano-sensing promoters to allow mammalian cells to sense pressure and produce a controlled mineralization in response. The bacterial team is using the S.O.S. response from UV radiation and quorum sensing as stimuli to have bacteria secrete bacteriophage. Coated with zipper proteins, these bacteriophage can polymerize, cross-link and eventually form a living structure.  Both teams are integrating a toggle switch into the system, allowing us to consistently control the cell’s response to the stimuli.
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Revision as of 15:53, 27 October 2010

MIT iGEM 2010 Abstract

abstract

Materials technology is a rapidly advancing field with research focusing on new methods of nanomaterial design. The biggest problem with nanomaterials is that the creators (us) are on a completely different length scale when compared to the materials we venture to create. Our project strives to take small steps in the direction of nanomaterials by utilizing cells--both bacterial and mammalian--and bacteriophage as units in developing a living, self-assembling, dynamic biomaterial.

Our goal is to create a system within cells that can convert a 2D design visible to the human eye into a 3D biostructure of phage or bone with the cross section of that same design. Our cells will be able to sense elements of the macro, human world, and output a living, self-assembled structure. Our mammalian team was motivated by the idea of the cellular “touch pad,” and is utilizing mechano-sensing promoters to allow mammalian cells to sense pressure and produce a controlled mineralization in response. The bacterial team is using the S.O.S. response from UV radiation and quorum sensing as stimuli to have bacteria secrete bacteriophage. Coated with zipper proteins, these bacteriophage can polymerize, cross-link and eventually form a living structure. Both teams are integrating a toggle switch into the system, allowing us to consistently control the cell’s response to the stimuli.

By the end of the summer, we want our project to be able to showcase the capability of indirectly controlling the production of an organized biostructure. With the integration of multiple visible markers, user-directed design will be able to stimulate the production of a multichromatic output on a bacterial lawn, along with a tangible biostructure, and mechanical stimulation of our mammalian cell line will induce controlled differentiation of our cells into bone. We hope to have developed two systems with the ability to form living three-dimensional biomaterials that retain their ability to reform into a different structure if given the correct input.