Team:ETH Zurich/project/applications

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Future development of synthetic biological systems will require the implementation of reliable synthetic circuits. These genetic circuits will be designed to program new biological behaviour, dynamics, and logic control<sup>[[Team:ETH_Zurich/project/references#refWeiss|[1]]]</sup>. A well established multichannel orthogonal communication system is crucial for efficient biological computation which is subsequently required for the performance of the cells tasks. In order to achieve the goals of our project we need to thoroughly characterise available components, improve their performance, and develop novel constructs for robust multichannel orthogonal communication and subsequent logic processing. With our findings we will try to make a contribution to the field of biological computation by enabling further development of complex systems that depend on the interaction between its sub components.
Future development of synthetic biological systems will require the implementation of reliable synthetic circuits. These genetic circuits will be designed to program new biological behaviour, dynamics, and logic control<sup>[[Team:ETH_Zurich/project/references#refWeiss|[1]]]</sup>. A well established multichannel orthogonal communication system is crucial for efficient biological computation which is subsequently required for the performance of the cells tasks. In order to achieve the goals of our project we need to thoroughly characterise available components, improve their performance, and develop novel constructs for robust multichannel orthogonal communication and subsequent logic processing. With our findings we will try to make a contribution to the field of biological computation by enabling further development of complex systems that depend on the interaction between its sub components.
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[File:ETH_Zurich_2014_Application_implant.png]
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[[File:ETH_Zurich_2014_Application_implant.png]]
These biological computers in turn need to find a way to be implemented in patients, if they are developed for therapeutic use. A promising application of such synthetic biological systems is cell based therapy by alginate-microencapsulated implants<sup>[[Team:ETH_Zurich/project/references#refAuslander|[2]]][[Team:ETH_Zurich/project/references#refBugaj|[3]]]</sup>. In our project we try to generate complex patterns using a grid of alginate beads by exploiting their communication and input integration systems. These beads are incapable of functioning in isolation but generate complex patterns when used together on the grid. We believe that this can be a significant step for the development of artificial organs composed of multiple alginate-microencapsulated implants. Analogous to our system, these encapsulated implants work together to perform the overall task which otherwise, could not have been achieved by a single implant working in isolation.
These biological computers in turn need to find a way to be implemented in patients, if they are developed for therapeutic use. A promising application of such synthetic biological systems is cell based therapy by alginate-microencapsulated implants<sup>[[Team:ETH_Zurich/project/references#refAuslander|[2]]][[Team:ETH_Zurich/project/references#refBugaj|[3]]]</sup>. In our project we try to generate complex patterns using a grid of alginate beads by exploiting their communication and input integration systems. These beads are incapable of functioning in isolation but generate complex patterns when used together on the grid. We believe that this can be a significant step for the development of artificial organs composed of multiple alginate-microencapsulated implants. Analogous to our system, these encapsulated implants work together to perform the overall task which otherwise, could not have been achieved by a single implant working in isolation.

Revision as of 14:57, 14 October 2014

iGEM ETH Zurich 2014