Frontiers in Medical Biology I

Course manual 2019/2020

Course content

This course will focus on three of today’s biggest societal health challenges: “Cancer”, “Aging” and “Food for Health”. Students will

• obtain knowledge of the fundamental, biological principles underlying these challenges.
• obtain various skill sets to address these challenges from different perspectives (public engagement and experimental research in Frontiers I, entrepreneurship in Frontiers II).

Taking normal developmental biology as a starting point, students will learn

• how cells organize themselves into tissues.
• how to view disease as a disruption of normal development and tissue homeostasis.
• how to integrate different knowledge areas by taking a multidisciplinary, systems biology approach to study complex cell behavior.
• which (bio)technological challenges are associated with studying complex tissues.
• which (bio)technological challenges are associated with predicting, preventing and curing disease.

Frontiers in Medical Biology I starts by giving students a solid foundation in developmental biology, focusing on complex multicellular animals. Taking the three germ layers (ectoderm, endoderm and mesoderm) as a starting point, students will learn the fundamental principles of cell communication and cell movement, tissue patterning and gene regulation. Healthy cell behavior will continuously be compared to diseased situations, with a more in depth focus on aging (including stem cells and their promise for regenerative medicine), cancer formation (taking breast cancer, melanoma and neuroblastoma as an example) and nutritional challenges (e.g. metabolic disorders and food allergies). At the end of week 8, the students’ knowledge of these topics will be tested in a written exam.

In the time leading up to the exam, students will get ample opportunity to process and actively engage with the material. Special emphasis will be placed on the integration of different knowledge areas, by combining insights from wet-lab experiments and synthetic biology approaches with computational modeling. To achieve this, the material will be presented in the form of lectures (hoorcollege) and directly applied in tutorials (werkcollege) and practicals (either wet-lab experiments or computer excercises). To further develop their insight into the material presented in Frontiers in Medical Biology I, students will also work on a science communication assignment, for which they will make a webvideo to explain a basic biological concept covered during the course to a broad audience.

Frontiers in Medical Biology I provides the basis for (and has been designed together with) Frontiers in Medical Biology II, which follows immediately after. In this course students will actively and creatively apply the knowledge and skills acquired in Frontiers in Medical Biology I, enabling them to not only explore potential fields of interest (e.g. cancer research, regenerative medicine), but also to discover which area/approach suits him/her best (e.g. science communication, business, fundamental research). The track is completed by Advanced Genomics, which also builds on Frontiers I.

Study materials

Literature

• We have switched to the 11th edition of Gilbert: Developmental Biology (by Gilbert, 11th edition - hardback cover: ISBN: 978-1-60535-470-5; looseleaf: ISBN: 978-1-60535-604-4).

• The Cell (by Alberts)
• Advanced Nutrition and Human Metabolism (by Cooper and Smith, 6th edition - ISBN-:78-1133104056)

Syllabus

• will be made available on Canvas

Practical training material

• Make sure to bring a lab coat, lab journal, pen and pencils to the wet lab practicals! You will receive a manual during the practical.

Software

• you will be asked to install R on your personal laptop

Other

• Additional hand-outs and papers, posted on Canvas.

Objectives

• Explain the importance of fundamental research for solving societal health challenges
• apply the knowledge from basic developmental processes and principles in a novel situaton to address a biological problem
• Translate fundamental biological knowledge into information for a broad audience
• analyse the wiring and behavior of gene circuits (e.g. control elements, bi-stable and oscillatory behavior)
• explain cancer and aging from a developmental biologist’s perspective
• define or describe specific developmental processes and biological events, including (but not limited to) gastrulation, EMT and epigenetic patterning.
• integrate knowledge of the molecular and cellular level to understand complex biological systems
• explain basic principles of tissue morphogenesis and maintenance at the molecular and cellular level
• use systems biology to better understand biological processes

Teaching methods

• Hoorcollege
• Werkcollege
• Laptopcollege
• (Computer)practicum
• Presentatie/symposium
• Zelfstudie
• Communicatie opdracht
• Lecture
• Laptop seminar
• Seminar
• Presentation/symposium
• Self-study
• Computer lab session/practical training

The learning material will be presented in the form of lectures (hoorcollege). This will be alternated with tutorials (werkcollege) and practicals (either wet-lab experiments or computer excercises), allowing students to process and actively engage with the material. In the communication assignment (web video) you will get the opportunity to handle the material from a different perspective.

Students are expected to actively engage with and process the material during the time allocated for self-study ('zelfstudie') and science communication assignments (‘verwerkingsopdracht’). Please note that in the Datanose schedule, the time that should be allocated to self-study is not explicitly indicated! It is your responsibility to use the open time slots for this purpose.

Learning activities

Academic skills

You will develop your critical thinking and analytical skills as we move away from the text book into 'real world' examples and papers in the tutorials ('werkcolleges') and practicals. This requires active participation on your part: we will cover a lot of different topics, but rather than just absorbing the material, we encourage you to ask questions and to dig deeper. How do biomedical scientists go about finding the answers to their questions? How do you design and interpret an experiment? How do you formulate a logical scientific argument? Which experimental approaches and techniques do you pick to address a specific biological question?

You will develop your communication skills (which are becoming more and more important as scientists are frequently asked to interact with the general public) in the communication assignment.

Attendance

Programme's requirements concerning attendance (OER-B):

• Participation in all practical sessions, computer sessions, and seminars in the curriculum is obligatory.
  

Additional requirements for this course:

- Attendance at the lectures is highly recommended, since these are interactive and provide additional examples that may not be in the textbook. 
- Attendance during tutorials and practical components (wet-lab experiments and computer/modeling exercises) is mandatory. Students that still end up missing one of the tutorials/practicals will have to make up for this in a personal assignment to be decided upon by the responsible teacher.
- Students that are repeating the course ('recidivisten') because they did not pass the final exam last year can get a 'vrijstelling' for the wet lab practical and the communication assignment, provided that they successfully passed these components in the year before. They are however expected to attend the computer practicals again. Please note that this 'vrijstelling' only holds for one year. After this, all course components must be taken again.

Assessment

To pass this course, students must obtain a final grade ≥ 5.5.

This final grade (scale from 1 to 10) is calculated as follows:

(0.7 * [written exam])
+
(0.15 * [communication assignment])
+
(0.1 * [computer assignment])
+
(0.05 * [wetlab practical])

Please note the following:

• As detailed in the OER, students must obtain ≥ 5.0 for each of the individual components.

Inspection of assessed work

Contact the course coordinator to make an appointment for inspection.

Up to twenty working days after the announcement of the results of the written examination, students can request to inspect their work and the standards applied for marking. Contact the course coordinator via e-mail to make an appointment.

Assignments

Practical wet-lab assignments

• Students will work in teams of 2. At the end of the practical, each individual student must hand in the completed questions (found in the practical hand-out), demonstrating that they properly understood and interpreted the experiments. They will receive a grade based on these answers, as well as their professional attitude during the practical (counting towards 5% of the final grade of the course). Students that fail the practical must complete an alternative assignment to be decided upon by the responsible teacher. Details will be provided during the wet-lab practical.

Computer assignments (weeks 1-7)

• At the end of each computer practical, students must hand in their answers to a set of questions. Together, these answers will count towards 10% of the final grade of the course. Details on these assignments will be provided during the computer practicals.

Science communication assignment (webvideo)

• Students will complete a communication assignment inspired by one of the topics covered in weeks 1 through 6. The deadline for handing in these assignments is towards the end of week 7.

  Assignment: Make a web video (3-4 minutes max.) to explain a fundamental biological principle to a broad audience. This assignment is performed in teams of 2-4 students.

  This communication assignment will count towards 15% of the final grade of the course. Details on these assignments can be found in the course syllabus.
  Examples of previous communication assignments can be found on You Tube at https://www.youtube.com/channel/UCHQAB7Xbqm_1CYJdKWlkeUA

Fraud and plagiarism

The 'Regulations governing fraud and plagiarism for UvA students' applies to this course. This will be monitored carefully. Upon suspicion of fraud or plagiarism the Examinations Board of the programme will be informed. For the 'Regulations governing fraud and plagiarism for UvA students' see: www.student.uva.nl

Course structure

Timetable

The schedule for this course is published on DataNose.

Additional information

Frontiers in Medical Biology I (12 EC) should be taken together with Frontiers in Medical Biology II (12 EC). This track will be offered in English.

A minimum of 16 and a maximum of 40 students. When the course if oversubscribed, preference will be given to students from the Biomedische Wetenschappen program (including beta/gamma students that have declared a biomedical sciences major). Additional selection, if needed, will be based on study progress.

Processed course evaluations

This course is well evaluated (receiving an average of 7.6 in 2016-2017, a 7.8 in the 2017-2018 and a 7.9 in the 2018-2019 student evaluation). Students find the course academically challenging and interesting. Overall, students are highly motivated to commit themselves to the material and they always indicate to have learned a lot about a variety of different topics.

We stress that this is a 3rd year course and that, as a result, students are expected to take control of their learning experience (e.g. students are expected to be able to discriminate between "hoofd- en bijzaken", to ask for more explanation when things are unclear, to be able to adapt to the different teaching styles of individual lecturers) and to actively work on developing a critical academic attitude (e.g. to be self-critical, to reflect on their work, to process feedback, to practice in formulating scientific problems/questions and solutions). The smaller group size is well suited for scientific discussions and interaction with the teachers, so use this opportunity!

Changes implemented based on student feedback (course evaluation end self-evaluation):

• In 2018-2019 we further improved our communication and instructions about the structure and set-up of the course (e.g. to indicate how different topics are linked and will be examined). In particular, weeks 3 and 4 (theme: food for health) were re-structured to obtain more focus on the microbiome and metabolism.
• In 2018-2019 we further improved integration of the webvideo/communication assignment: Students are only allowed to pick a topic that is directly related to material/concepts taught in Frontiers I. They also have to explain their choice in the reflective statement. By focussing more explicitly on the relevant underlying concepts they want to convey, students indeed perceived this as not only a 'fun' but also an 'educational' assignment.
• In the 2018-2019 student evaluation, students expressed the wish to receive more feedback, particularly for the wetlab practical. In 2019-2020 the following changes were implemented: The wetlab practical will now be assessed with a grade and time will be scheduled for students to inspect the assessed work. Students are also encouraged to identify more implicit moments of feedback as such, or to ask for more explicit during the practical when needed.
• In the 2018-2019 student evaluation, students indicated that the exam questions did not always connect to the lectures. In 2019-2020 the following changes were implemented: We have re-aligned the 'leerdoelen' and 'toetsmatrijs'. Also, an additional tutorial on experiment design and interpretation has been scheduled in week 6 to further connect the lectures, practical and the written exam. 

Changes not implemented so far:

• Students repeatedly indicate that the written exam is challenging (all the material is tested once, after 8 weeks instead of in two separate exams after 4 weeks each). The choice to only evaluate the material at the end is a conscious decision, since the ultimate goal is for the students to identify connections between the different areas and to identify common themes and principles. Students also indicate that they appreciate this. Given the results obtained over the past few years and the limited amount of students that need to re-take the exam, the learning goals appear to be met and at present we see no reason to change the original design. This will be continuously reflected upon and assessed by all teachers involved.

Other changes implemented:

• 2017-2019: We have continuously developed our computer practicals focusing on stem cells, thanks in part to a Grassroots proposal that was awarded to Gooitzen Zwanenburg and Renee van Amerongen. The goal of this practical is to get the students to actively engage with and think about essential, but complex concepts in stem cell biology and tissue homeostasis. The 2018-2019 results indicated that this approach is successful.

• 2018-2019: Advanced Genomics I and II were re-designed and Advanced Genomics I was fully integrated into the Frontiers in Medical Biology track. This ensures that the material and concepts taught in Frontiers I are now a "rode draad" in the entire track.

Contact information

Coordinator

• dr. R. van Amerongen

Staff

• prof. dr. S. Brul
• Yorick van de Grift MSc
• Hilde Herrema
• Huub Hoefsloot
• E.C. de Jong
• dr. M.J. Jonker
• prof. dr. P.J. Lucassen
• dr. W.J. van Nes
• prof. dr. J.H. Ravesloot
• dr. P.J. Verschure
• A.L. Zeeman BA
• Gooitzen Zwanenburg