Difference between revisions of "Team:LMU-TUM Munich"

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[[Image:Muc16_Team_Slider8.jpeg|link=|alt=Another Team Photo|class=bottom]]
 
 
==<span style="color:#000000">Abstract:</span> <span style="color:#009440">bio(t)</span><span style="color:#3070b3">INK</span> <span style="color:#8d8d8d">- rethINK tissue printing</span>==
 
==<span style="color:#000000">Abstract:</span> <span style="color:#009440">bio(t)</span><span style="color:#3070b3">INK</span> <span style="color:#8d8d8d">- rethINK tissue printing</span>==
 
We are living in an aging society that is facing a decreasing supply of donor organs for medical transplantation. To confront this pressing issue, we developed a game-changing approach to bioprint tissues for biomedical applications. Our interdisciplinary work aims to create a unique ink, named bio(t)INK, to revolutionize bioprinting. The printing process uses a [https://2016.igem.org/Team:LMU-TUM_Munich/Hardware hijacked 3D printer] and two components of biotINK to induce an instantaneous [https://2016.igem.org/Team:LMU-TUM_Munich/Proof polymerization reaction], creating three-dimensional multi-cellular structures in a user-definable manner. The principle of this two-component glue relies on the rapid and specific interaction of biotin and its tetrameric [https://2016.igem.org/Team:LMU-TUM_Munich/Proteins binding protein] avidin. To make use of this high biotin-avidin affinity for cell-cell cross-linking, we [https://2016.igem.org/Team:LMU-TUM_Munich/Receptors engineered cells presenting biotin moieties or biotin-binding proteins on their surfaces] as well as [https://2016.igem.org/Team:LMU-TUM_Munich/Proteins recombinant matrix proteins], which [https://2016.igem.org/Team:LMU-TUM_Munich/Proof co-polymerize upon printing]. Furthermore, we explored genetic circuits which allow us to functionalize the bio-synthetic tissue and install biosafety mechanisms. Altogether, we are confident that our system provides the necessary means to advance the SynBio community to the next level – the tissue level.<br>
 
We are living in an aging society that is facing a decreasing supply of donor organs for medical transplantation. To confront this pressing issue, we developed a game-changing approach to bioprint tissues for biomedical applications. Our interdisciplinary work aims to create a unique ink, named bio(t)INK, to revolutionize bioprinting. The printing process uses a [https://2016.igem.org/Team:LMU-TUM_Munich/Hardware hijacked 3D printer] and two components of biotINK to induce an instantaneous [https://2016.igem.org/Team:LMU-TUM_Munich/Proof polymerization reaction], creating three-dimensional multi-cellular structures in a user-definable manner. The principle of this two-component glue relies on the rapid and specific interaction of biotin and its tetrameric [https://2016.igem.org/Team:LMU-TUM_Munich/Proteins binding protein] avidin. To make use of this high biotin-avidin affinity for cell-cell cross-linking, we [https://2016.igem.org/Team:LMU-TUM_Munich/Receptors engineered cells presenting biotin moieties or biotin-binding proteins on their surfaces] as well as [https://2016.igem.org/Team:LMU-TUM_Munich/Proteins recombinant matrix proteins], which [https://2016.igem.org/Team:LMU-TUM_Munich/Proof co-polymerize upon printing]. Furthermore, we explored genetic circuits which allow us to functionalize the bio-synthetic tissue and install biosafety mechanisms. Altogether, we are confident that our system provides the necessary means to advance the SynBio community to the next level – the tissue level.<br>

Revision as of 21:34, 4 December 2016

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Abstract: bio(t)INK - rethINK tissue printing

We are living in an aging society that is facing a decreasing supply of donor organs for medical transplantation. To confront this pressing issue, we developed a game-changing approach to bioprint tissues for biomedical applications. Our interdisciplinary work aims to create a unique ink, named bio(t)INK, to revolutionize bioprinting. The printing process uses a hijacked 3D printer and two components of biotINK to induce an instantaneous polymerization reaction, creating three-dimensional multi-cellular structures in a user-definable manner. The principle of this two-component glue relies on the rapid and specific interaction of biotin and its tetrameric binding protein avidin. To make use of this high biotin-avidin affinity for cell-cell cross-linking, we engineered cells presenting biotin moieties or biotin-binding proteins on their surfaces as well as recombinant matrix proteins, which co-polymerize upon printing. Furthermore, we explored genetic circuits which allow us to functionalize the bio-synthetic tissue and install biosafety mechanisms. Altogether, we are confident that our system provides the necessary means to advance the SynBio community to the next level – the tissue level.

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LMU & TUM Munich

Technische Universität MünchenLudwig-Maximilians-Universität München

United team from Munich's universities

Contact us:

Address

iGEM Team TU-Munich
Emil-Erlenmeyer-Forum 5
85354 Freising, Germany