Team:Imperial College London/Workshop

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|At the same time as being a very informative and useful exercise, we each found that running the workshops was actually really good fun. It was refreshing to see so many new ideas and applications for synthetic biology.  The students seemed to really enjoyed applying what they had learnt in their school lessons to solve real-life problems. We tried to tie in what they had already learnt, or what they would be learning that year, into the workshop so that they wouldn't be learning lots of new material all in one go.
|At the same time as being a very informative and useful exercise, we each found that running the workshops was actually really good fun. It was refreshing to see so many new ideas and applications for synthetic biology.  The students seemed to really enjoyed applying what they had learnt in their school lessons to solve real-life problems. We tried to tie in what they had already learnt, or what they would be learning that year, into the workshop so that they wouldn't be learning lots of new material all in one go.
Nevertheless, explaining some of the methods used in synthetic biology was tricky because we didn't want to lose their attention, but we felt that some of the information was essential for them to get a grasp of the principles of BioBrick assemblies.
Nevertheless, explaining some of the methods used in synthetic biology was tricky because we didn't want to lose their attention, but we felt that some of the information was essential for them to get a grasp of the principles of BioBrick assemblies.
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There are few opportunities in most curriculums to be creative in terms of science.

Revision as of 17:31, 11 October 2010

Introduction
Public engagement is an essential part of determining priorities in research funding, but there is more to it than simply setting policies. Bridging the gap between academics and the wider public can achieve far more than , it can break down barriers for people to

When discussing the public engagement aspect of synthetic biology, we realised that school students would be an interesting demographic to present the subject to. We also liked the idea of inspiring young people to learn more about synthetic biology

As a team, we'd like to experience explaining and discussing the subject of synthetic biology and our project in particular, with non-specialists. We'd also like to demonstrate the importance of engaging the public when embarking on a project like ours. Engaging a younger audience might be an effective way of introducing synthetic biology to the wider public, as they are likely to be more familiar with web-based tools and are therefore more likely to embrace the potential of synthetic biology.

We'd like the students to think about synthetic biology in a way that makes them believe that they can shape the course it takes in the future. It would be great if they could see science as a way of being creative. Also, we hope to show the students how the media can affect the way people perceive synthetic biology and genetic engineering.

We knew that the workshops would help our project in terms of providing feedback that might change our own perspectives of synthetic biology, including any societal implications it might have.

Hopefully, in the future other iGEM teams will follow in our footsteps so we can inspire young scientists to learn more about synthetic biology!

The schools we chose to run the workshops at were state-funded schools, because we wanted to demonstrate that anyone can learn about synthetic biology, regardless of their background.

Plan
Each workshop ran for 1 hour and 40 minutes, including a 10 minute break in the middle.

We wanted the workshop to be as visual and exciting as possible, so we used various images and videos throughout. For more information, see the slideshow.

Introduction (15 minutes) The aim of the introductory session was to explain the concept of synthetic biology clearly to the students, allowing them to come up with their own opinions of what they think it could mean. We then wanted to discuss a few applications, the iGEM competition, and give an overview of our project.

Activity 1 (15 minutes) In small groups, the students had to come up with different ideas for applying synthetic biology. Each group was given a different key word, such as bioremediation or sanitation. During this activity, each group made a poster detailing their ideas, which they used when explaining their ideas to the other groups. Presentation: Regulation of Synthetic Biology (10 minutes) We decided that it was necessary to introduce the students to this side of research, of which their experience was likely to be limited.

Break (10 minutes)

Activity 2 (20 minutes) This was more of a debate/discussion style activity. The idea was to discuss the various concerns and issues associated with synthetic biology, allowing the students to voice their own opinions. We also discussed our project in particular, such as the social impacts of putting GMOs into water and so on.

Presentation: Synthetic Biology and the Media (10 minutes) This was an opportunity for us to show the students how the media can change the public’s opinion of a particular subject, simply by using provocative language or images. We used various news headlines and news programmes as examples.

Activity 3 (20 minutes) The aim of this activity was to allow the students to experience the process of marketing a synthetic biology product. In groups, they were each given a synthetic biology product for which they had to act out a TV advert. They had to address the concerns of the public, and reassure people that the organism in question was ‘safe’.

Reflections
At the same time as being a very informative and useful exercise, we each found that running the workshops was actually really good fun. It was refreshing to see so many new ideas and applications for synthetic biology. The students seemed to really enjoyed applying what they had learnt in their school lessons to solve real-life problems. We tried to tie in what they had already learnt, or what they would be learning that year, into the workshop so that they wouldn't be learning lots of new material all in one go.

Nevertheless, explaining some of the methods used in synthetic biology was tricky because we didn't want to lose their attention, but we felt that some of the information was essential for them to get a grasp of the principles of BioBrick assemblies.

There are few opportunities in most curriculums to be creative in terms of science.


It's really easy to tell when people understand the concept of synthetic biology because ideas start popping up every few seconds!


Recommendations
  1. Try to find out where the students are in their studies and what they'll be learning in the near future. That way, they'll be able to apply their existing knowledge and learn things that could help them in their future work!