FYS-8029 Optical nanoscopy - 10 stp

The course is available as a singular course.

The course will only be taught if there is a sufficient number of students. If you are interested in following the course, please contact the student advisor as soon as possible

The objective of this course is to provide education and training on state-of-the-art optical super-resolution imaging techniques. The emerging field of super-resolution optical microscopy is commonly referred to as optical nanoscopy. The focus will be on structured illumination microscopy (SIM) and direct stochastic optical reconstruction microscopy (dSTORM) techniques. The course will provide theoretical and practical training on the state-of-the art optical nanoscopy techniques. The teaching will be given as lectures, demonstrations, and practical sessions. Students will be provided opportunities to image their own sample (within limitations) using state-of-the-art SIM and dSTORM microscopes to be installed at UiT. Optical nanoscopy has had an impact in several disciplines. Similarly, this course is planned to be cross-disciplinary and it is suitable for candidates with different backgrounds, such as physics, biology, medicine, fisheries, pharmacy, who are interested to learn or use the emerging field of optical nanoscopy. The course is open to both internal and external students. The contents of the course are:

• Introduction to fluorescence based optical imaging techniques
• Diffraction limit and its implication in bio-imaging application
• Overview of existing optical nanoscopy techniques
• Opportunities and limitations of different optical nanoscopy techniques, (SIM, STED, dSTORM).
• Theory and background of direct stochastical optical reconstruction microscopy (dSTORM)
• Theory and background of Structured illumination microscopy
• Demonstration and optimization of sample preparation for dSTORM
• Practical hands-on training on using dSTORM to acquire super-resolved optical images, small groups (each consisting of 3-5 students)
• Demonstration and optimization on sample preparation for SIM
• Practical hands-on training on using SIM to acquire super-resolved optical images of live and fixed cells, small groups (each consisting of 3-5 students)
• Training on data analysis and post-acquisition image processing for 3D image rendering for SIM and d-STORM using Image J/Fiji or Volocity

The course will provide brief overview on image formation and microscopy before venturing into the arena of super-resolution optical microscopy. The course will be given at both Master and PhD level. For Master level, cell staining, image acquisition, 3-D data rendering will not be mandatory and practical hands-on training will be less extensive. Practical training on SIM and dSTORM will be more extensive at PhD levels.

To take PhD courses you need to have at least a master's degree or equivalent.

PhD students at UiT The Arctic University of Norway register for the course through StudentWeb .

External applicants apply for admission through SøknadsWeb.

All external applicants have to attach a confirmation of their status as a PhD student from their home institution. Students who hold a Master of Science degree, but are not yet enrolled as a PhD-student have to attach a copy of their master's degree diploma. These students are also required to pay the semester fee.

More information regarding PhD courses at the Faculty of Science and Technology is found here.

Knowledge - The student can:

• understand the implication of diffraction limits of conventional fluorescence microscopy
• evaluate the advantages and limitation of various optical nanoscopy techniques
• make decision on which optical nanoscopy technique is useful for their respective applications
• understand the underlying principles of SIM and dSTORM

Skills - The student can:

• gain practical skills to use and operate commercial SIM and d-STORM system to acquire super-resolved optical images
• gain practical skills on image rendering using Fiji/ImageJ/Volocity
• gain basics on cell staining for SIM and d-STORM

General expertise - The student can:

• familiarize with optical microscope and fluorescence imaging techniques
• appreciate the multi-disciplinary research opportunities available at the cross-roads of biology and physics

Lectures: 20 hours Exercises: 30 hours

The course will be given in two extensive modules, each consisting of one week.