Difference between revisions of "Team:Valencia UPV/Public Engagement"

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Index

Education and Public Engagement
Printeria: SynBio has never been easier
Bio Art
Future generations
European Research Night
UPV Welcome Fest

Social outreach: exploring the relation between art and science

Education: enhancing hand-on STEAM curricula for the future generations

European Research Night: fighting against common SynBio misconceptions

Design Factory Exhibition: promoting SynBio to the university community

Education and Public Engagement

Synthetic Biology challenges have only real sense taking into account the effect it has on the improvement of nowadays issues. However, it is also one of the most controversial scientific fields for the public opinion.

Currently, access to Synthetic Biology field is hampered by several barriers, such as the necessity of deep technical knowledge and high-cost technologies. In the same way, the presence of common misconceptions in regard to bacteria handling and genetic engineering makes it even more difficult to reach to the general public.

Thus, our aim is to break down all these barriers in order to increase SynBio accessibility into society.

To do so, we have created Printeria: a bio-engieering device capable of automating the process of printing genetic circuits in bacteria.

Printeria: SynBio has never been easier

Under the core values of affordability and reproducibility, Printeria is a compact device with which SynBio can be approached to the public in an innovative, friendly and reduced-cost way.

Thus, Printeria has been conceived as both and educational and bioartistic tool. With a user-friendly software, it can introduce SynBio into the high school classrooms without the necessity of lab equipments. In the same way, it offers a wide range of opportunities for the bioartist disposal.

To prove its social usefulness, we have explored Printeria impact possibilities into society.

Bio Art

“To develop a complete mind: Study the science of art; Study the art of science. Learn how to see. Realize that everything connects to everything else.” - Leonardo da Vinci

Art exists since the origins of humanity. Likewise, science has always been prompted by a desire of knowing more and more about the world, the nature and life.

While developing Printeria, we had the chance to get into the vast applications of the BioArt world: a contemporary art form that adapts scientific methods and biotechnology to explore living systems as artistic subjects (1).

As a consequence, we decided it was necessary to explore the existant synergy between art and science by getting into BioArt ways of expression.

Printone: express yourself

While creating our Printeria Part Collection, we decided to provide bioartists with a complete DNA toolkit for their artwork production. To do so, we assembled several transcriptional units with our differents reporters (GFPmut3, sfGFP, YGP, mRFP, amilCP ) and a variety of promoteres and RBS of diverse relative strenghts.

By this way, we finally obtained Printone: a palette of pigmented bacteria, composed of different colours and intensity tones, for the entire disposal of the bioartist.

FOTO COLORES

We used this variety of colours to introduce, both ourselves and the general public, to the Microbial Art field: creation of agar plates artworks with living cells such as bacteria. We were introducen into this kind of art thanks to the information gathered as part of our Integrated Human work Integrated Human with the artist niche. The spanish bioartist María Peñil, who works hand-by-hand with the researcher Mehmet Berkmen, helped us to in-depth understand the Microbial Art branch and its possibilities. Indeed, we finally sent them some of our Printone samples, as they were interested in testing the use of our genetic engineered bacteria to paint with.

FOto con logo printeria

Bioartist for one day

How to attract people to SynBio? It is possible to achieve this challenge in a subjective and eye-appealing way?

While developing Printeria, we realized we had there the perfect way to approach SynBio in a nerby and cultural way to the non-researcher world. Thus, we organized the workshop ‘Bioartist for one day’.

The activity took place in the Mustang Art Gallery (Elche), a cultural space dedicated to the diffusion of contemporary art. This workshop involved last year high school students of arts, science and social sciences, so we could interact with a wide range of different profiles. However, this activity not only involved students, but also their teachers and some local artists who were interested in getting into the world of the bacterial art.

In this activity, they created their own ‘living masterpice’. Previously, we did detailed explanation on how to properly use the lab material and cells during simple microbiology protocols. Thus, they learned both from the art and microbiology worlds.

Then, using solid agar plates as a canvas, inoculating loops as brushes and the palette of pigmented bacteria we self-made in the lab as tempera, they blew their minds to do imaginative Microbial Art. As soon as they finished, petri dishes were collected, kept and sealed for a later incubation in our lab. Finally, a gallery of all their beutiful works was published in @printeriaupv Instagram profile, so everyone could share them and so create interest into Bacterial Art among society.

As a conclusion, this workshop was a total success, and both the public and ourselves were delighted to realize the beauty of the microbial world and its simple but yet appealing applications.

Yturralde: fusion between art and science

José María Yturralde is an spanish artist widely known for his relationship with science. He collaborated with artists and scientists to redefine his understanding of shapes, and explored ways that the mainframe computer could be used as a tool for his art (2). In this context, we thought it could be a great idea to introduce him to the vast possibilities of the BioArt, and so learn about his life experiences all at once.

As part of this outreach collaboration we decided to recreate one of his masterpieces, from the well-known collection 'Impossible Figures', with our own genetic engineered bacteria.

To do so, we printed a 3D mold of the figure to delimitate the barriers of the drawing, so we could then inoculate each coloured bacteria in a compartiment of the solid agar medium. Finally, using bigger than usual agar dishes, we were able to recreate his artwork. After several trials with different colour tones and molds, the final result was perfect:

Impossible figure artwork. Yturraldes's masterpiece and the equivalent Microbial Art version

Future generations

High school students are eager to know more about the world they live in. However, students rarely learn about Synthetic Biology inside classrooms. As there is a lack of hand-on STEM curricula, basic concepts such as gene, DNA and bacteria are only explained theoretically.

In order to stimulate young people to be curious about science, we decided to do our part in changing this educational approach.

Communicating

First and most simple, we gave some talks to high school students, in which we talked about:

Bacteria: enemies or friends?

We wanted to beat the stigma against bacteria, explaining their importance and benefits, not only naturally, but also in biotechnology (i.e.: bacteria as biofactories for medicine, industry, etc.)
Printeria: how it really works?

As SynBio is not only about biology, we thought it was also highly important to demonstrate the role of engineering and electronics. Thus, we decided to explain them, from an educational approch, the basis of Printeria: how the digital microfluidic system allows us to control each biotech process with high accuracy.

During the talk, they were able to life in first person the droplets controlled movement around our PCB surface. Moreoever, we showed them several videos and gifs to ensure students could understand such kind of a priori complex concepts. As a result, many of them finished the talk being completely interested in learning more about the microfluidic technology and its applications.

Printeria: educational approach

Printeria aim is to used as an educational device. Taking into account that, generally, people doesn't even know what SynBio is from the beginning, we realized it was necessary to ensure students could discover synbio in a friendly but technically correct way.

To do so, ...

European Research Night

The European Research Night is a wide-public event, promoted under the EU Programme Horizon 2020, whose objective is to to encourage the scientific vocations and lay public interest into science.

Activity

As part of this event the City of Arts and Science, one of the biggest scientific and cultural leisure complexes in Europe, organized a complete program of free access activities. We were invited to be part of this program, so we decided to present there Printeria future applications to a public from different ages, who dialogued with us about common synbio misconceptios.

Design Factory Exhibition

UPV_iGEM is part of the Design Factory Global Network, a network of universities innovation hubs whose mission is to create change in the world of learning through passion-based culture.

Activity

As part of the Design Factory Exhibition, we we had the chance to show Printeria to all the university community and to introduce the basic concepts of SynBio to those who didn't know about them.

References

(1) Bioart: An introduction https://www.sciencedaily.com/releases/2015/11/151123203619.htm

(2) Bravo, E. G. & García, J. A. (2015). Yturralde: Impossible Figure Generator. Leonardo 48(4), 366-374. The MIT Press. Retrieved October 8, 2018, from Project MUSE database.

@@ Line 261: / Line 261: @@
-Then, using solid <b>agar plates</b> as a <b>canvas</b>, <b>inoculating loops</b> as <b>brushes</b> and the palette of <b>pigmented bacteria</b> we self-made in the lab as <b>tempera</b>, they blew their minds to do imaginative <b>Microbial Art</b>. As soon as they finished, petri dishes were collected, kept and sealed for a later incubation in our lab. Finally, a gallery of all their beutiful works was published in <a href="https://www.instagram.com/printeriaupv/?hl=es">@printeriaupv Instagram profile</a>, so everyone could share them and so create interest into Bacterial Art among society. </p>
+<p>Then, using solid <b>agar plates</b> as a <b>canvas</b>, <b>inoculating loops</b> as <b>brushes</b> and the palette of <b>pigmented bacteria</b> we self-made in the lab as <b>tempera</b>, they blew their minds to do imaginative <b>Microbial Art</b>. As soon as they finished, petri dishes were collected, kept and sealed for a later incubation in our lab. Finally, a gallery of all their beutiful works was published in <a href="https://www.instagram.com/printeriaupv/?hl=es">@printeriaupv Instagram profile</a>, so everyone could share them and so create interest into Bacterial Art among society. </p>
 <p>As a conclusion, this workshop was a total success, and both the public and ourselves were delighted to realize the beauty of the microbial world and its simple but yet appealing applications.
   <p><img src="https://static.igem.org/mediawiki/2018/d/de/T--Valencia_UPV--placasMAGUPV2018.jpg" alt=""></p>
@@ Line 268: / Line 268: @@
                    <p> José María Yturralde is an spanish artist widely known for his relationship with science.  He collaborated with artists and scientists to redefine his understanding of shapes, and explored ways that the mainframe computer could be used as a tool for his art (2). In this context, we thought it could be a great idea to <b>introduce</b> him to the vast possibilities of the <b>BioArt</b>, and so learn about his life experiences all at once.
-                   </p><p>As part of this outreach collaboration, we decided to recreate one of his masterpieces, from the well-known collection <b>'Impossible Figures'</b>, with our own genetic engineered bacteria.
+                   </p><p>As part of this outreach collaboration we decided to recreate one of his masterpieces, from the well-known collection <b>'Impossible Figures'</b>, with our own genetic engineered bacteria.
                    <p>To do so, we printed a 3D mold of the figure to delimitate the barriers of the drawing, so we could then inoculate each coloured bacteria in a compartiment of the solid agar medium. Finally, using bigger than usual agar dishes, we were able to recreate his artwork. After several trials with different colour tones and molds, the final result was perfect:  </p>
                    <div class="fotoConPie">
@@ Line 306: / Line 306: @@
                    <h3>Future generations</h3>
-                   <p>High school students are eager to know more about the world they live in. However, students rarely learn about Synthetic Biology inside classrooms. As there is a lack of hand-on STEM curricula, basic concepts such as gene, DNA and bacteria are only explained theoretically.
+                   <p>High school students are eager to know more about the world they live in. However, students rarely learn about Synthetic Biology inside classrooms. As there is a lack of hand-on STEM curricula, basic concepts such as gene, DNA and bacteria are only explained theoretically. </p>
-In order to stimulate young people to be curious about science, we decided to do our part in changing this educational approach.
+<p>In order to stimulate young people to be curious about science, we decided to do our part in changing this educational approach.
 </p>
-                   <h4>Communicating: divulgue SynBio</h4>
+                   <h4>Communicating</h4>
                    <p>First and most simple,  we gave some talks to high school students, in which we talked about:
 </p><ul>
@@ Line 318: / Line 318: @@
    <li>
      <p>Printeria: how it really works? </p> <p> As SynBio is not only about biology, we thought it was also highly important to demonstrate the role of engineering and electronics. Thus, we decided to explain them, from an educational approch, the basis of Printeria: how the digital microfluidic system allows us to control each biotech process with high accuracy. </p>
-       <p>During the talk, they were able to life in first person the droplets controlled movement around our PCB surface. Moreoever, we showed them several videos and gifs to ensure students could understand such kind of a priori complex concepts. As a result, many of them finished the talk being completely interested in learning more about the microfluidic technology and its applications. </p>
+       <p>During the talk, they were able to life in first person the droplets controlled movement around our PCB surface. Moreoever, we showed them several videos and gifs to ensure students could understand such kind of a priori complex concepts. As a result, many of them finished the talk being completely interested in learning more about the microfluidic technology and its applications.
        <img src="https://static.igem.org/mediawiki/2018/2/2c/T--Valencia_UPV--MAGUPV2018.jpg" alt="">
 </p></li></ul>