Team:SJTU-BioX-Shanghai/Education

Achievement

1. Left-Behind Children: We help children who are short of education badly, with planting seeds of science in their minds

2. Undergraduates: Using an Original pattern, we break down barriers of discipline and attract people from different disciplines into synthetic biology.

3. Poor teenages: We help them and offer free lectures, even teaching equipment.

4. The middle-aged: We encourage them to gain cutting-edge knowledge and keep learning through their life.

Left-Behind Children

Left-behind children are commonly existing but easy to ignore in China. Parents go out for a long time due to work and cannot be with their children which leads to their negligence in the management and education of the children. This will not only affect the children's learning grades, but also damage the children's mental health¹.The rapid development of Shanghai, China has attracted a large number of migrant workers. This has led to the emergence of a large number of left-behind children whose basic knowledge is in shortage. They were the first forgotten people we have seen. So in order to help the left-behind children, we contacted Shanghai Jiuqian Volunteering Service Agency and successfully introduced biology explanations into their extracurricular classrooms.

Jiuqian Volunteering Service is a public welfare organization established in 2008 with the purpose of providing high-quality free public education for children, especially those whose parents work in Shanghai. Courses include various subjects and musical instruments, summer camps during winter and summer vacations. More than 10,000 children have been served.

We first advertised to the children about food safety in daily life, mainly about pesticide residues in fruits and vegetables in the farmer’s market. We added contents like how to clean the fruits, how to judge the symptoms of food poisoning, how to call for help, and so on.

Next, we explained to the children the basic biological knowledge, including the discovery history of DNA and RNA, and their role in life. During the presentation, they actively participated and showed great interest in the field we introduced.

In the discussion after class, we also mentioned our RNA-based testing project. Unexpectedly, the children were very eager for novel knowledge and expressed their opinions and questions initially. Under our guidance, they showed their self-understanding ability of biology.

Poor Teenager

Poverty leads to dropout is a worldwide problem. Some children have lost the opportunities to receive education due to economic conditions, and have to help with housework and labor at school age.In this way, children lose access to biology and even have a high possibility of engaging in criminal activities².

In Southwest China, the backwardness of education is more serious. Especially in rural areas, where the terrain is complex, most people live on farming, the economy is backward, and educational resources are lacking.There are many students here who are unable to receive education due to difficult conditions.

In order to change this situation, we cooperated with the software team of Shanghai Jiao Tong University and went to the Middle School of Yuantou Town in Pingle County, Guilin, Guangxi Province.We rely on the abundant resources of SJTU, not only to provide course materials, but also to provide expensive hardware facilities, such as microscopes,electronic projections and other equipments, in order to improve the situation of poor students.

We had face-to-face discussions and exchanges with some local teachers representatives. The teacher introduced the local education and the difficulties they are facing, such as the shortage of educational resources, insufficient number of teachers, and the quality of teaching which still need to be improved.

First of all, we donated several microscopes to poor schools. These microscopes will become important tools for children to observe small creatures and will also add content to future biology courses.At the same time, we also taught the children how to use the microscope correctly, including pre-preparation, operation, and finishing after use.

What’s more,in view of the lively characteristics of children, we also brought interesting biological experiments-leaf vein bookmarks.Let children use the medicine to remove the leaf flesh, leaving the delicate veins, and drying them to make bookmarks.Improved children's hands-on ability and cultivated their interest in biology from experiments.Finally, we compiled and displayed the children's works, and encouraged everyone to learn about the world through their own hands.

Our educational activities have been affirmed by local teachers, students and parents. This not only improved the hardware facilities of local education, but also provided children with opportunities to learn new knowledge and broaden their horizons.

Undergraduate

It is well known that after high school graduates enter college, they will choose their majors, take specific courses, and interact with people in specific areas such as physics, computer science, and mathematics. This means that most students will no longer formally study biology, including synthetic biology. Consequently, these students lack knowledge of biology, and due to it, most students naturally don't participate in IGEMs. This will lead to the loss of talent and the unicity of talent in the field of synthetic biology, which is a great pity. Besides, as a comprehensive discipline, synthetic biology is very much in need of the most creative students and dynamic groups in college, and it also needs the involvement of students from other majors.

So, in order to break through this dilemma, our team SJTU-BioX-Shanghai developed a model, with synthetic biology as the theme, with different disciplines, added featured discussion content, and carried out six disciplines of publicity and education, including: biology, medicine, physics, chemistry, computer science, mathematics; And our team led more than 110 undergraduates from different disciplines to visit the biology lab. At the same time, we designed questionnaires to understand whether preaching is conducive to students of other majors to understand and participate in synthetic biology.

We hope that this model helps college students of other majors to understand synthetic biology and become a member of it. By promoting this model in other universities such as Tongji University, we see the possibility that more non-biological students at universities will learn about synthetic biology and offer constructive advice from different perspectives.

Biology

We preached to the students in the biology major. Because biology students have a good knowledge base, we detailed the principles of our project and the development process, successfully demonstrated how to use the knowledge of synthetic biology to solve a practical problem. What's more, in the featured discussion sessions we designed, considering that biology students often have difficulty defining synthetic biology, we mainly focused on distinguishing synthetic biology and genetic engineering, as well as how to define biological modules and designs, and so on. By encouraging students to know about synthetic biology, we hope that more biology students can directly participate in the competition of iGEM.

Our speech has had a good effect. The questionnaire showed that 81.1% of students were able to answer basic knowledge of synthetic biology, such as the principles of designing biological brick, common system indicators, etc. Fifty-five percent of the students learned about the interdisciplinary mode of operation. At the same time, more than 60% of students focused on major breakthroughs in synthetic biology.

Physics

This is a great challenge for us because the biological fundamentals of the interdisciplinary audience are weak. For physics students, we firstly introduced the event of iGIM , and then the general content of our project this year. At the same time, in order to give them a better understanding of drastic change in biology, we discuss the formation of Cooper pairs and derive the theoretical differences between quantum and macro levels in the special discussion session, starting from superconductor theory. Later, we talk about a typical example of biophysics: phase change in gene expression. With the help of preaching, we have given physics students a new knowledge of gene expression, encouraged them to analyze biological problems from their own perspectives, and used advanced equipment in the field of physics to promote the development of synthetic biology.

Our educational activities have achieved their propaganda purposes. Back to the questionnaire, it showed that 82.3 percent of students learned about iGEM, 77.6 percent said the activity was conducive to increasing their acceptance of biological knowledge, 81.2% of students were able to interpret proper nouns, and more than 66.6% of students noticed the cases which physics was involved in synthetic biology.

Medicine

Medical students have a certain biological basis, and they are also direct users of biological products. We have a brief overview of the iGEM events and our projects. However, we try to introduce our project from the perspective of medical students. Because doctors in the actual work process, very much need the support of new technology. They are also well aware of the problems with the current industry. Medical students were encouraged to seek practical solutions from learning and life, and to try to solve the problems through synthetic biology. Using the example of Exosome-dependent Alzheimer's screening in translational medicine, we analyzed how our 2021 program applies to early screening and diagnosis of disease in order to help medical students establish a logical system of problem solving and demand-oriented thinking.

Our speech inspired them. The questionnaire showed that 70.1% of students were able to answer basic knowledge of synthetic biology, such as the principles of designing biological brick, common system indicators, etc. Sixty percent of the students learned about the interdisciplinary mode of operation. At the same time, more than 78% of students focused on major breakthroughs in synthetic biology.

Chemistry

Chemistry students have a good knowledge base, such as hydrogen bonds, Van der Waal’ Force. At the same time, our project has a part about the formation of chemical bonds, we discussed with the students in the course of the project principal part. Not only that, but we also want to have a special discussion from the perspective of biological chemistry: biochemical topics. We explained to them the specific effects and workings of the amidohydrolase. Taking the stomach protease in daily life as an example, it illustrates the process of interrupting the peptide bond, lets the students in the chemical direction understand the specific content of biochemical research, and stimulates their interest in entering the field of synthetic biology with a chemical background.

Our educational activities have achieved their propaganda purposes. Back to the questionnaire, it showed that 85.3 percent of students learned about iGEM, 95.6 percent said the activity was conducive to increasing their acceptance of biological knowledge, 64.7% of students were able to interpret proper nouns, and more than 79.6% of students noticed the cases which physics was involved in synthetic biology.

Mathematics

In the presentation to students in Mathematics, we gave a brief overview of our project. What's more, given the math major, we shared with them the work of our project on mathematical modeling. Because many parts of our project involve mathematical modeling, good mathematical modeling can guide and optimize our experiments: model predictions for synthesis and degradation during RNA transcription, for example. We take the IGEM project as an example to encourage students in the mathematical direction to play their own advantages, using mathematical modeling tools, to participate in the construction of future synthetic biology.

Our educational activities were a success. The questionnaire showed that 80.1% of students were able to answer basic knowledge of synthetic biology, such as the principles of designing biological brick, common system indicators, etc. Forty percent of the students learned about the interdisciplinary mode of operation. At the same time, more than 50% of students focused on major breakthroughs in synthetic biology.

Computer science

We give a presentation to students in Computer Science. For participants are from ACM(Association of Computing. Machinery) of Shanghai Jiao Tong university who are a wonderful teammates of international computer competition. We started with a topic of international competitions and talked about the development history and schedule of iGEM, so that they have a preliminary understanding of iGEM. At the same time, we prepared a lecture on bioinformatics, a theme is "protein folding alphafold". Through the explanation of algorithmic thinking and construction, students understand how to view and solve biological problems from a computer perspective. And we encouraged them to join the field of synthetic biology.

Back to the questionnaire, it showed that 76.3 percent of students learned about iGEM, 80.6 percent said the activity was conducive to increasing their acceptance of biological knowledge, 90.2% of students were able to interpret proper nouns, and more than 56.6% of students noticed the cases which physics was involved in synthetic biology.

Summary

Tours to Our Laboratory

Not only did we conduct popular science education and feature discussions for students in 6 disciplines, but we also led more than 120 undergraduates from different disciplines to visit our iGEM laboratory in batches. During the visit, we not only explained the safety regulations in the laboratory, the operating instructions of various instruments, but also personally demonstrated how to use the instruments for students who had never entered the biological laboratory, including Clean Bench, pipettes, PCR instruments, etc. This not only lets students in other subjects understand the status of the iGEM experiment, but also sees the specific operation of normal synthetic biology, which is impossible to learn from books. What's more, such visits have increased the understanding of synthetic biology among students in other disciplines and greatly stimulated their interest in participating in experiments.

Model Promotion—Tongji University

In order to prove the feasibility of education for non-biological college students, we not only completed the school's 6 different majors of interdisciplinary education, we also want to extend it to more universities, and jointly practice such an educational model.

Tongji University is our partner. After exchanging our ideas, we found that both parts had the ideas for the education of college students. So we provided them with our model, iGEM competition as a cross-discipline comprehensive competition, the object of education should not be limited to life science-related professional students, but should be further extended to mathematics, physics and other related majors. Based on this, Tongji University team listened to our views, we both agreed to target more students involved in other disciplines as educational objects in the subsequent education activities, and to extend this model to more universities in China.

The Middle-aged

The production pillar of the whole society is the group of middle-aged people³. But they find it difficult to get away from the daily busy and complicated work. In this way, they will be neglected to learn new knowledge and improve their scientific literacy.

Aiming at the characteristics of the middle-aged group. We relied on large-scale science popularization stations in the farmer’s market, where they can preach. We published brochures .

At the same time, we have also prepared convenient online courses so that they can watch and learn anytime, anywhere. Receive popular science education and improve their own quality. We hope that through our efforts, we can spread popular science education to this busy middle-aged population, improve social science thinking, and even increase productivity.

First of all, we went to the Shanghai Food and Drug Safety Science Station for professional study. Here, we have seen the integration of multiple education models. First of all, education can be conducted in the form of quick tests. We can master the correct daily safety knowledge by answering points. Also, we learn to record popular science videos to explain the hazards of various potential threats and fast-detected target substances to our health.

Secondly, in order to be able to fully reach our target population, we choose to go to the farmer's market, where many middle-aged people will purchase food. We explain the basic knowledge of rapid detection on the spot, containing simple principles, detection limits, sensitivity and specificity. In order to give local people a basic content of our detection. We also explained the criticality of a series of pesticide target substances, and through the popularization of past safety incidents. We can see that the public started paying attention to related safety incidents and spontaneously conduct quick inspections.

After the on-the-spot lecture, we found that our strength was limited, and we could only give a small portion of middle-aged people who come to buy food popular science education. Therefore, we need a much more popular science tool that is not limited by time and space, facilitates learning, and has a wide range of influence.

Therefore, we have produced a series of educational videos on biological themes so that viewers can play on-demand at the time they want. We cooperated with Tianjin University to put our educational videos on public platforms to let more people Able to watch.

The difficulty of the content is differentiated, from medium to high difficulty (for people with existing foundations, and introduction of our specific quick test items from the perspective of new nucleic acid applications) and low-difficulty targeted explanations.

We hope that the content we present shows a certain degree of cohesion. Therefore, we introduced the basic knowledge in the low-difficulty area, specifically explaining the functions of DNA, RNA, and protein, which laid the groundwork for our testing projects. So that the audience can understand and master after receiving the science popularization in the low-difficulty area. Interested in learning the knowledge of difficult areas.