Difference between revisions of "Team:Potsdam/Description"

Revision as of 13:41, 1 November 2017

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Background facts and information The field of synthetic biology combines different disciplines, like molecular biology, engineering, mathematics and physics to improve the knowledge of existing biological systems or to design and manipulate genes, pathways and entire genomes of organisms, for them to fulfill a certain purpose. Synthetic Biology is applied in various fields and disciplines. For biomedical applications it can be used to design ... Find out more	Abstract Bringing enzymes closer together for increased reaction efficiency by using DNA scaffolds. In fields like biotechnology, synthetic biology and in medical applications it becomes increasingly important to produce more and more complex substrates efficiently. For this reason, a high product yield is always sought after. A relatively straight forward method ... Find out more	Project Design Biotechnological applications have skyrocketed and evolved to be one of the most ubiquitous aspects in our daily life in the past years. From uses in food industry to dietary supplements and science, so-called white biotechnology is everywhere. That’s why we try to recreate a widespread phenomenon called metabolic channelling synthetically and increase the yield in biochemical... Find out more

Research work & Protocols Finding a suitable topic was very challenging and time consuming. Initially, we looked through projects of prior teams and assembled a list of possible topics. A big influence was a new method for assembling genes in a manufacturing manner which was being developed by a research group on our university. Based on the quick and easy synthesis of proteins a first idea was the creation of enzymes that could convert blood groups.... Find out more	Modelling Team Eindhoven’s project and our LLPs project have a lot of similarities (see our collaboration for more information). Apart from experimenting with their idea they also used a newly designed and a rule-based model system to simulate their experiments outcome more accurately. Through our collaboration they agreed to helping us modelling our system for a better insight into the protein-protein interactions during LLPs... Find out more	Labbook Biotechnological applications have skyrocketed and evolved to be one of the most ubiquitous aspects in our daily life in the past years. From uses in food industry to dietary supplements and science, so-called white biotechnology is everywhere. That’s why we try to recreate a widespread phenomenon called metabolic channelling synthetically and increase the yield in biochemical... Find out more

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          <td ><b>Research work & Protocols</b> <br> Finding a suitable topic was very challenging and time consuming. Initially, we looked through projects of prior teams and assembled a list of possible topics.
-A big influence was a new method for assembling genes in a manufacturing manner which was being developed by a research group on our university. Based on the quick and easy synthesis of proteins a first idea was the creation of enzymes that could convert blood groups....<br><a href="https://2017.igem.org/wiki/index.php?title=Team%3APotsdam%2FBackground">Find out more</td>
+A big influence was a new method for assembling genes in a manufacturing manner which was being developed by a research group on our university. Based on the quick and easy synthesis of proteins a first idea was the creation of enzymes that could convert blood groups....<br><a href="https://2017.igem.org/wiki/index.php?title=Team%3APotsdam%2FProtocols">Find out more</td>
-         <td align="justify"><p style="margin-left:30px;"><b>Modelling</b><br>Team Eindhoven’s project and our LLPs project have a lot of similarities (see our collaboration for more information). Apart from experimenting with their idea they also used a newly designed and a rule-based model system to simulate their experiments outcome more accurately. Through our collaboration they agreed to helping us modelling our system for a better insight into the protein-protein interactions during LLPs...<br><a href="https://2017.igem.org/Http://2017.igem.org/2017.igem.org/Team:Potsdam/Abstract">Find out more</a></p></td>
+         <td align="justify"><p style="margin-left:30px;"><b>Modelling</b><br>Team Eindhoven’s project and our LLPs project have a lot of similarities (see our collaboration for more information). Apart from experimenting with their idea they also used a newly designed and a rule-based model system to simulate their experiments outcome more accurately. Through our collaboration they agreed to helping us modelling our system for a better insight into the protein-protein interactions during LLPs...<br><a href="https://2017.igem.org/Team:Potsdam/Model">Find out more</a></p></td>
          <td align="justify"><p style="margin-left:30px;"><b>Labbook</b><br>Biotechnological applications have skyrocketed and evolved to be one of the most ubiquitous aspects in our daily life in the past years. From uses in food industry to dietary supplements and science, so-called white biotechnology is everywhere.
-That’s why we try to recreate a widespread phenomenon called metabolic channelling synthetically and increase the yield in biochemical... <br> <a href="https://2017.igem.org/wiki/index.php?title=Team%3APotsdam%2FDesign">Find out more </p></td>
+That’s why we try to recreate a widespread phenomenon called metabolic channelling synthetically and increase the yield in biochemical... <br> <a href="https://2017.igem.org/Team:Potsdam/Notebook">Find out more </p></td>
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Difference between revisions of "Team:Potsdam/Description"

Revision as of 13:41, 1 November 2017

IGEM Potsdam