Difference between revisions of "Team:ETH Zurich/HP/Silver"

(Add details about big data revolution.)
(Attempt floating to the left.)
Line 8: Line 8:
 
<main role="main">
 
<main role="main">
 
<h1 class="headline">Promoting Synthetic Biology</h1>
 
<h1 class="headline">Promoting Synthetic Biology</h1>
<br>
+
 
 
<section class="first">
 
<section class="first">
 
     <h1>Pitch at the ETH Student Project House</h1>
 
     <h1>Pitch at the ETH Student Project House</h1>
    <figure class="fig-float SPH">
 
        <a href="https://sph.ethz.ch/"><img src="https://2017.igem.org/wiki/images/2/23/T--ETH_Zurich--SPH_logo.png"
 
        alt="Student Project House"
 
        /></a>
 
    </figure>
 
 
     <p>The student project house at ETH Zurich allows students from various backgrounds to follow own ideas and projects. They organize pitching events where students can present their ideas and connect with other students with similar interests. Due to the generally high demand of time and resources, life science projects have not yet been in the focus there.</p>
 
     <p>The student project house at ETH Zurich allows students from various backgrounds to follow own ideas and projects. They organize pitching events where students can present their ideas and connect with other students with similar interests. Due to the generally high demand of time and resources, life science projects have not yet been in the focus there.</p>
 +
    <figure class="fig-float-right SPH">
 +
        <a href="https://sph.ethz.ch/">
 +
            <img alt="Student Project House"
 +
            src="https://2017.igem.org/wiki/images/2/23/T--ETH_Zurich--SPH_logo.png"/>
 +
        </a>
 +
    </figure>
 
     <p> We wanted to change that. To do so, we went there to present one of our earlier ideas. This way, we introduced a bunch of mechanical engineers, computer scientists and other students from ETH Zurich to the world of synthetic biology. Afterwards, we passed on our own experiences with a student-led life scientific project to the SPH-manager.</p>
 
     <p> We wanted to change that. To do so, we went there to present one of our earlier ideas. This way, we introduced a bunch of mechanical engineers, computer scientists and other students from ETH Zurich to the world of synthetic biology. Afterwards, we passed on our own experiences with a student-led life scientific project to the SPH-manager.</p>
 
</section>
 
</section>
Line 22: Line 23:
 
<section>
 
<section>
 
     <h1>Talk at NTU Athens</h1>
 
     <h1>Talk at NTU Athens</h1>
     <figure class="fig-float NTUA">  
+
    <p>Building reliable networks out of simple, well-characterised components is an engineer's daily work. Synthetic Biology is no different in this aspect; it appears that nature favours reuse of elementary biological mechanisms in all kinds of systems. Systematic research has revealed a number of reasons why some biological cirtuits are more abundant than others, namely efficiency and robustness to parameter variation. <a href="#bib1" class="forward-ref">[1]</a> Such principles are universal in the world of technology and should be accessible to engineering students who had little or no prior exposure to biology.
 +
     <figure class="fig-float-left NTUA">  
 
         <img src="https://2017.igem.org/wiki/images/1/1f/T--ETH_Zurich--NTUA_talk.jpg"
 
         <img src="https://2017.igem.org/wiki/images/1/1f/T--ETH_Zurich--NTUA_talk.jpg"
 
         alt="Nikolaos giving a talk at NTUA"
 
         alt="Nikolaos giving a talk at NTUA"
Line 28: Line 30:
 
         <figcaption>Nikolaos giving a talk to graduate students at the National Technical University of Athens.</figcaption>
 
         <figcaption>Nikolaos giving a talk to graduate students at the National Technical University of Athens.</figcaption>
 
     </figure>
 
     </figure>
     <p>Building reliable networks out of simple, well-characterised components is an engineer's daily work. Synthetic Biology is no different in this aspect; it appears that nature favours reuse of elementary biological mechanisms in all kinds of systems. Systematic research has revealed a number of reasons why some biological cirtuits are more abundant than others, namely efficiency and robustness to parameter variation. <a href="#bib1" class="forward-ref">[1]</a> Such principles are universal in the world of technology and should be accessible to engineering students who had little or no prior exposure to biology. We thus travelled to the <a href="https://www.ece.ntua.gr/en">School of Electric and Computer Engineering</a> at the National Technical University of Athens (where Nicolaos graduated from) and attempted to introduce about 20 master students of Computer Science to elementary principles of regulatory gene networks.</p>
+
     <p>We thus travelled to the <a href="https://www.ece.ntua.gr/en">School of Electric and Computer Engineering</a> at the National Technical University of Athens (where Nicolaos graduated from) and attempted to introduce about 20 master students of Computer Science to elementary principles of regulatory gene networks.</p>
<p> We introduced ourselves, and gave a brief talk presenting the current state of bacterial cancer therapy, using CATE as a concrete example, albeit still experimental. While presenting our project, we explained how Synthetic Biology can employed to create biological AND gates that "sense" and conditionally respond to their environment. In particular, we outlined the crucial role such high-level bio-bricks play in our project, and described our efforts to engineer them to suit our needs (e.g. using a Lactate/AHL AND-gate to increase specificity, and use a heat-deactivated repressor to remote-controll cell lysis).
+
    <p> We introduced ourselves, and gave a brief talk presenting the current state of bacterial cancer therapy, using CATE as a concrete example, albeit still experimental. While presenting our project, we explained how Synthetic Biology can employed to create biological AND gates that "sense" and conditionally respond to their environment. In particular, we outlined the crucial role such high-level bio-bricks play in our project, and described our efforts to engineer them to suit our needs (e.g. using a Lactate/AHL AND-gate to increase specificity, and use a heat-deactivated repressor to remote-controll cell lysis).
<p>Finally, we mentioned the repercussions of big-data revolution. Indeed, one can find more data in Biology than in any other discipline known to man. <a href="#bib2" class="forward-ref">[2]</a> Computer-assisted statistical analysis is gaining importance in modern biology and thus academic and entrepreneurial opportunities in SynBio are increasing for engineering graduates. .</li>
+
 
</p>
+
    <p>Finally, we mentioned the repercussions of big-data revolution. Indeed, one can find more data in Biology than in any other discipline known to man. <a href="#bib2" class="forward-ref">[2]</a> Computer-assisted statistical analysis is gaining importance in modern biology and thus academic and entrepreneurial opportunities in SynBio are increasing for engineering graduates.</p></li>
 +
    </p>
 
</section>
 
</section>
  
 
<section>
 
<section>
 
     <h1>Talk by T3 Pharma CEO Simon Ittig and Us</h1>
 
     <h1>Talk by T3 Pharma CEO Simon Ittig and Us</h1>
     <figure class="fig-float T3">  
+
    <p>While doing an <a href="/Team:ETH_Zurich/HP/Gold_Integrated">interview with Dr. Simon Ittig</a> we came to realize that bacterial cancer therapy, combined with synthetic biology, is not only a possible new treatment approach but also commercially interesting. We therefore asked him to come to our department to explain the technology as well as talk about how to build your own startup. He agreed and gave an insightful and interesting talk to a range of scientists from our department and also other universities.</p>
 +
     <figure class="fig-float-left T3">  
 
         <img src="https://2017.igem.org/wiki/images/9/9a/T--ETH_Zurich--T3event.png"
 
         <img src="https://2017.igem.org/wiki/images/9/9a/T--ETH_Zurich--T3event.png"
 
         alt="Impressions"
 
         alt="Impressions"
Line 42: Line 46:
 
         <figcaption>Impression of the event that was attended by around 80 people.</figcaption>
 
         <figcaption>Impression of the event that was attended by around 80 people.</figcaption>
 
     </figure>
 
     </figure>
    <p>While doing an <a href="/Team:ETH_Zurich/HP/Gold_Integrated">interview with Dr. Simon Ittig</a> we came to realize that bacterial cancer therapy, combined with synthetic biology, is not only a possible new treatment approach but also commercially interesting. We therefore asked him to come to our department to explain the technology as well as talk about how to build your own startup. He agreed and gave an insightful and interesting talk to a range of scientists from our department and also other universities. The talk was followed by an apero at which new connections between industry and academia have been formed. For this event, we worked together with <a href="https://bsse-industry.ethz.ch/"> D-BSSE meets industry</a> who have a lot of experience with such events.</p>
+
<p>The talk was followed by an apero at which new connections between industry and academia have been formed. For this event, we worked together with <a href="https://bsse-industry.ethz.ch/"> D-BSSE meets industry</a> who have a lot of experience with such events. We made further use of the occasion and introduced ourselves and our idea to the audience. This way we made sure that the scientists at our department know of iGEM and what this years team is doing.</p>
    <p>We made further use of the occasion and introduced ourselves and our idea to the audience. This way we made sure that the scientists at our department know of iGEM and what this years team is doing.</p>
+
 
</section>
 
</section>
  

Revision as of 23:56, 28 October 2017

Promoting Synthetic Biology

Pitch at the ETH Student Project House

The student project house at ETH Zurich allows students from various backgrounds to follow own ideas and projects. They organize pitching events where students can present their ideas and connect with other students with similar interests. Due to the generally high demand of time and resources, life science projects have not yet been in the focus there.

Student Project House

We wanted to change that. To do so, we went there to present one of our earlier ideas. This way, we introduced a bunch of mechanical engineers, computer scientists and other students from ETH Zurich to the world of synthetic biology. Afterwards, we passed on our own experiences with a student-led life scientific project to the SPH-manager.

Talk at NTU Athens

Building reliable networks out of simple, well-characterised components is an engineer's daily work. Synthetic Biology is no different in this aspect; it appears that nature favours reuse of elementary biological mechanisms in all kinds of systems. Systematic research has revealed a number of reasons why some biological cirtuits are more abundant than others, namely efficiency and robustness to parameter variation. [1] Such principles are universal in the world of technology and should be accessible to engineering students who had little or no prior exposure to biology.

Nikolaos giving a talk at NTUA
Nikolaos giving a talk to graduate students at the National Technical University of Athens.

We thus travelled to the School of Electric and Computer Engineering at the National Technical University of Athens (where Nicolaos graduated from) and attempted to introduce about 20 master students of Computer Science to elementary principles of regulatory gene networks.

We introduced ourselves, and gave a brief talk presenting the current state of bacterial cancer therapy, using CATE as a concrete example, albeit still experimental. While presenting our project, we explained how Synthetic Biology can employed to create biological AND gates that "sense" and conditionally respond to their environment. In particular, we outlined the crucial role such high-level bio-bricks play in our project, and described our efforts to engineer them to suit our needs (e.g. using a Lactate/AHL AND-gate to increase specificity, and use a heat-deactivated repressor to remote-controll cell lysis).

Finally, we mentioned the repercussions of big-data revolution. Indeed, one can find more data in Biology than in any other discipline known to man. [2] Computer-assisted statistical analysis is gaining importance in modern biology and thus academic and entrepreneurial opportunities in SynBio are increasing for engineering graduates.

Talk by T3 Pharma CEO Simon Ittig and Us

While doing an interview with Dr. Simon Ittig we came to realize that bacterial cancer therapy, combined with synthetic biology, is not only a possible new treatment approach but also commercially interesting. We therefore asked him to come to our department to explain the technology as well as talk about how to build your own startup. He agreed and gave an insightful and interesting talk to a range of scientists from our department and also other universities.

Impressions
Impression of the event that was attended by around 80 people.

The talk was followed by an apero at which new connections between industry and academia have been formed. For this event, we worked together with D-BSSE meets industry who have a lot of experience with such events. We made further use of the occasion and introduced ourselves and our idea to the audience. This way we made sure that the scientists at our department know of iGEM and what this years team is doing.

References

  1. Alon, Uri. An Introduction to Systems Biology: Design Principles of Biological Circuits. CRC Press: 2006
  2. http://journals.plos.org/plosbiology/article?id=10.1371/journal.pbio.1002195