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Team:UT Dallas/test haccordian
From 2012.igem.org
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| - | <div id='st_1'><h2 class='title'>Distributed Cellular Processing Units: a synergistic approach to biological computing</h2> | + | <div id='st_1' style="float:left"><h2 class='title'>Distributed Cellular Processing Units: a synergistic approach to biological computing</h2> |
The goal of the 2012 University of Texas at Dallas IGEM team is to redefine biological information processing using quorum signaling-based biological circuitry in bacteria. Quorum signaling allows bacteria to communicate with each other through the use of chemical signals. Bacteria use this form of signaling in nature to coordinate their behavior. Using three quorum signaling molecules we create unique connections between different populations of engineered bacteria and perform coordinated computing functions. We design and characterize standard and novel modules such as toggle switches, oscillators, signal propagators, and logic gates. As compared to engineering molecular circuitry in single populations, we aim to show that the synergistic approach to information processing leads to improved, scalable, and tunable operation. | The goal of the 2012 University of Texas at Dallas IGEM team is to redefine biological information processing using quorum signaling-based biological circuitry in bacteria. Quorum signaling allows bacteria to communicate with each other through the use of chemical signals. Bacteria use this form of signaling in nature to coordinate their behavior. Using three quorum signaling molecules we create unique connections between different populations of engineered bacteria and perform coordinated computing functions. We design and characterize standard and novel modules such as toggle switches, oscillators, signal propagators, and logic gates. As compared to engineering molecular circuitry in single populations, we aim to show that the synergistic approach to information processing leads to improved, scalable, and tunable operation. | ||
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Revision as of 01:01, 27 September 2012
Distributed Cellular Processing Units: a synergistic approach to biological computing
The goal of the 2012 University of Texas at Dallas IGEM team is to redefine biological information processing using quorum signaling-based biological circuitry in bacteria. Quorum signaling allows bacteria to communicate with each other through the use of chemical signals. Bacteria use this form of signaling in nature to coordinate their behavior. Using three quorum signaling molecules we create unique connections between different populations of engineered bacteria and perform coordinated computing functions. We design and characterize standard and novel modules such as toggle switches, oscillators, signal propagators, and logic gates. As compared to engineering molecular circuitry in single populations, we aim to show that the synergistic approach to information processing leads to improved, scalable, and tunable operation.-
This accordion content has a custom full width of 250px. Note where the two inline CSS are added within the markup.
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This accordion content has a custom full width of 180px. Note where the two inline CSS are added within the markup.
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This accordion content has a custom full width of 350px. Note where the two inline CSS are added within the markup.
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This accordion content has a custom full width of 550px. Note where the two inline CSS are added within the markup.
