Difference between revisions of "Team:Kyoto/Integrated Human Practices"

Latest revision as of 23:33, 29 November 2018

Team:Kyoto/Project - 2018.igem.org

　　As introduced in Human Practice, we iGEM Kyoto 2018 have jumped out of the laboratory, made exchanges with a wide variety of people, learned a lot of things and added depth to the contents of the project. In this page, we will introduce an overview of how these Human Practice activities educated us and led to the improvement of the project. We will introduce it by dividing into three parts.

　The first is an interview with salt damage experts and what we learned from it. We were able to learn about the specific circumstances that we could apply our device and got insight into the needs and concerns of salt damage, and these lead to the design of a new device.

　The second relates to the first part, it is a biosafety problem. From Public Engagement activities and exchanges with experts, we recognized the needs of further safety measures for our devices, and we decided to move on to the development of new parts to guide yeast cell aggregation. This is the point that iGEM Kyoto's project this year received the greatest influence from Human Practice.

　Thirdly, in order to create a more efficient salt absorbing device, we interacted with many experts. Starting from the device creation method, we learned the performance evaluation method, the creation of the final device form, and application method. From their advice, the outline of this project was determined.

　We summarized the activities of our integrated human practice in a chart shown below. Three parts of work influenced each other and this helps you visualize how we were able to improve the project by human practice work.

CLICK HERE

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-　As a project in 2018, iGEM Kyoto worked on the creation of salt-absorbing yeast. In most cases, the function of biomolecules is greatly affected by the salt concentration in solution. In order to avoid situations where synthetic biological devices created to work in various environments are inhibited at high salt concentration, our device aims to adjust the salt concentration of the culture solution.<br><br>
+　As introduced in Human Practice, we iGEM Kyoto 2018 have jumped out of the laboratory, made exchanges with a wide variety of people, learned a lot of things and added depth to the contents of the project. In this page, we will introduce an overview of how these Human Practice activities educated us and led to the improvement of the project. We will introduce it by dividing into three parts.<br><br>
-　In order to consider where our device can practically be used, we studied various examples of synthetic biological devices and asked the experts about many social problems caused by salt concentration. The salt damage problem shown below is particularly serious among salt related social problems. How our device can contribute to Salt Damage and what kind of function is expected in our device? To search these answers, we not only asked experts in Salt Damage but also set up opportunities to listen to the public who are unfamiliar with synthetic biology.<br><br>
+　The first is an interview with salt damage experts and what we learned from it. We were able to learn about the specific circumstances that we could apply our device and got insight into the needs and concerns of salt damage, and these lead to the design of a new device.<br><br>
-　Among these opportunities, we noticed that cognition about synthetic biology is much lower than we imagined in Japanese society. Furthermore, most people did not know about the activities of iGEM. Many synthetic biological devices, including ours, are created every day to solve all possible social problems. We believe that in order for these devices to be used in the actual field, not only special experts but also general public need to have an understanding of synthetic biology. Therefore, in the following events, we advertised on synthetic biology and iGEM and worked on improving cognition about these activities in Japanese society.<br><br>
+　The second relates to the first part, it is a biosafety problem. From Public Engagement activities and exchanges with experts, we recognized the needs of further safety measures for our devices, and we decided to move on to the development of new parts to guide yeast cell aggregation. This is the point that iGEM Kyoto's project this year received the greatest influence from Human Practice.<br><br>
+　Thirdly, in order to create a more efficient salt absorbing device, we interacted with many experts. Starting from the device creation method, we learned the performance evaluation method, the creation of the final device form, and application method. From their advice, the outline of this project was determined.<br><br>
+　We summarized the activities of our integrated human practice in a chart shown below. Three parts of work influenced each other and this helps you visualize how we were able to improve the project by human practice work.<br><br>
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+<center><img src="https://static.igem.org/mediawiki/2018/b/b3/T--Kyoto--chartchart.png" width="70%"></center>
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-<center><img src="https://static.igem.org/mediawiki/2018/9/95/T--Kyoto--environment.png" width="30%"></center>
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-　As we showed in this result, salt concentration has a great influence on protein-protein interaction. Besides, the behavior of various biomolecules is greatly influenced by salt concentration. Rather than solving this device in the test tube alone, is there any possibility of expanding the application to solve something more social? While exploring this question, we encountered a serious problem caused by high salt concentration, it is salt damage.<br><br>
-　Salt damage is a phenomenon that the growth of crops is inhibited by salt accumulation in the soil. Since plants do not require salt for growth, excess salts in the soil become growth inhibiting substances. For example, high concentrations of sodium ions in the soil cause osmotic pressure to increase and inhibit the ability to suck up water, soils lose their water holding capacity, and enzyme reactions in plant bodies are inhibited.<br><br>
-　Salt damage is occurring in one-fifth of the world's agricultural land. Is it possible that our device will contribute even a bit to this problem? We searched for an expert on salt damage and explored the possibility to find an answer to this question.
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-<center><a href="https://2018.igem.org/Team:Kyoto/Environment" class="btn"><font color="#000000"><b>CLICK HERE</b></center></font></a><br><br><br>
-<center><img src="https://static.igem.org/mediawiki/2018/f/f1/T--Kyoto--education.png" width="40%"></center>
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-　If we study synthetic biology, we often spend much time inside the lab. So, we tend to consider just biological aspects of GMOs or ease in handling them in the laboratory. However, in order to make use of synthetic biology, it is necessary to embrace ideas of  public people and people of various fields.<br><br>
-　Fortunately, we were able to get many opportunities to interact with a wide range of people from junior high school students to university professors, Such opportunities made us notice new issues and applications of our project. I'm sure that our project would be more disgusting unless we met them.
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-<center><a href="https://2018.igem.org/Team:Kyoto/Public_Engagement" class="btn"><font color="#000000"><b>CLICK HERE</b></center></font></a><br><br><br>
+<center><a href="https://2018.igem.org/Team:Kyoto/Applied_Design" class="btn"><font color="#000000"><b>CLICK HERE</b></center></font></a><br><br><br>