Computational imaging, modelling and AI in biomedicine

Postgraduate course

ECTS credits: 10
Teaching semesters: Spring
Course code: BMED365
Number of semesters: 1
Teaching language: English
Resources: Schedule

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Objectives and Content

The objective and content of the course address:The computational mindset, imaging, modeling, machine learning, and AI in future biomedicine - ethical and regulatory aspects of AI. The course is a guided "journey" with a hands-on component through selected computational modeling techniques within biomedical and medical applications. Examples, demonstrations, and tasks will be related to in vivo imaging (MRI) and segmentation, imaging mass cytometry (IMC), biomarkers and prediction, network analysis ("patient similarity networks"), multimodal data, as well as large language models ("foundation models") within medicine and biology. Throughout the course, students will use principles and modern tools for data analysis, machine learning, and generative AI (e.g. ChatGPT) within biomedical applications. This will give the students an introduction to Python and Jupyter notebooks, use of the "cloud" for access to open data, calculations, and knowledge, as well as insight into and rationale for "open science" and "reproducible research". All course material will be openly available on a GitHub repository.

Learning Outcomes

Upon completion of the course, the student must have the following learning outcomes defined in terms of knowledge, skills, and general competence:

Knowledge

The student ...Has broad knowledge of the terms "multiscale" and "multiparametric biomedical imaging",

"computational modeling", "big data", "network analysis", "machine learning", "deep learning", and "generative AI" (incl. large language models) and was able to relate these terms to examples from biomedicine and personalized and precision medicine.

Skills

The student ...Can find and use a selection of modern software tools for data analysis, visualization, reporting, and generative AI, e.g. explorative data analysis, figure and graphics production with Jupyter notebooks, and efficient prompting of large language models such as ChatGPT. Can communicate about selected methods, software packages, and libraries where these methods have been implemented and explain their relevance in biomedical research and medicine.

General competence

The student ...Recognizes the importance of mathematical models and computational approaches, as well as large language models, for the analysis and understanding of complex systems and disease processes. Appreciate the need for interdisciplinary collaboration in biomedicine of the future. Ethical and regulatory aspects of biomedical AI. Can analyze how scientific collaboration in the form of "open science", sharing of data, and "reproducible research" can move science forward.

ECTS Credits

Level of Study

Master

Semester of Instruction

Spring

Required Previous Knowledge

Bachelor's degree in biology, chemistry, physics, informatics, mathematics, statistics, biomedical engineering, software engineering, medicine from 3rd year, or similar e.g. exchange student (to be approved).

Recommended Previous Knowledge

For the students from biomedicine / biology, recommended previous knowledge includes general physiology, anatomy, and cell biology / molecular biology from their Bachelor's degree (or at the level of passing the second year into the medical curriculum). They should also have a curiosity/interest in biomedical technology, mathematics/statistics, and computational science. Some familiarity with programming (Python and friends) is highly recommended. For students in engineering (medical technology, software engineering) or students in mathematics, informatics, chemistry, or physics, the recommended previous knowledge includes calculus / linear algebra / statistics and computer programming (Python) from their bachelor program or engineering school. They should also have a curiosity/interest in biology, physiology, disease processes, and modeling applications. Medical students on the research track, and PhD students are welcome to take the course.

Credit Reduction due to Course Overlap

6 sp if completed ELMED219

Access to the Course

Students admitted to a Master's program at the Faculty of Medicine or the Faculty of Science and Technology at UiB (or another university) and students admitted to the engineering studies at HVL (or another university, e.g. Erasmus student). Qualified students from outside UiB will receive guest student status upon admission to the course.

There is room for max 20 students, with 10 places reserved for master's students in biomedicine.

Teaching and learning methods

The teaching style is oriented towards "blended learning" and "flipped classroom":

The course is divided into two blocks. In the first block there will be two days of introductory and motivational lectures, including demonstrations.There wil be e-learning/lab modules on a GitHub repository (before, during, and available after the course) addressing the learning outcomes for the course. A submission related to a specific topic within biomedicine, chosen from among a small selection of pre-defined projects, is mandatory. This will be organized as projects in small teams, where collaboration between students majoring in different topics in their Bachelor e.g. biology and informatics, respectively ("tandem"), is sought. This interdisciplinary team project must be presented orally at one of the last meetings in the first block. The second block will focus on computational biomedical imaging (MRI, IMC, ...) and modelling. Between the first and second block, the students will work on their own personal project, defined by the student henself within the scope of the course. This project must be submitted before the end of block two and will be presented to the rest of the students as a "speed posters". There will be a total of six "labs"/"meet-ups" with teachers and teaching assistents. Final digital exam. The course will assume the students have their own laptop (or borrow one).

Compulsory Assignments and Attendance

One compulsory team project participation, submission, and group presentation, followed by an individual project with a "speed-poster" presentation, partly with a peer assessment component. Compulsory activities are registered by the course supervisor and must be passed before the final exam.

Forms of Assessment

Team project and group presentation in block one, and submission of a personal project and presentation of corresponding "speed poster" in block two must be approved.

Final digital home exam (2 hours) with quiz and MCQ with a pass / no-pass.

Grading Scale

Pass/fail

Assessment Semester

Spring

Reading List

The literature list and study material (on GitHub) will be ready by 01.07 for the autumn semester and 01.12 for the spring semester.

Course Evaluation

Written evaluation using electronic/digital evaluation tool.

Programme Committee

Department of Biomedicine

Course Coordinator

Arvid Lundervold

Course Administrator

Department of Biomedicine

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Department of Biomedicine med-ibm-studiesaker@uib.no

Course coordinator: Arvid Lundervold, arvid.lundervold@uib.no

Type of assessment: Take-home examination
Assignment handed out: 03.03.2025, 09:00
Submission deadline: 03.03.2025, 12:00
Withdrawal deadline: 01.02.2025
Examination system: Inspera; Digital exam

Important information about exams

The Department of Biomedicine