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[ 600MTARHMTV25 ] VL Harnessing Mechanobiology for Tissue Engineering
Versionsauswahl
(*) Unfortunately this information is not available in english.
Workload Education level Study areas Responsible person Hours per week Coordinating university
3 ECTS R - Doctoral programme (*)Biophysik Kerstin Blank 2 hpw Johannes Kepler University Linz
Detailed information
Pre-requisites (*)Zulassung zum Doktoratsstudium Medical Sciences, Naturwissenschaften bzw. Technischen Wissenschaften
Original study plan Doctoral programme Natural Sciences 2025W
Learning Outcomes
Competences
Upon successful completion of the course, students are able to describe the structures and physical properties of biological systems across different hierarchical levels (from molecules to cells and tissues). They have a deep understanding of the experimental physical methods used to study these systems at various scales. Additionally, they will gain initial insights into current research questions and trends. They are able to assess the relevance of new developments for the advancement of the field.
Skills Knowledge
Upon completing the course, students will possess the following skills.
They are able to

  • describe the structural and mechanical properties of biological systems at different scales and assess the relevance of these properties for biological functions (k2, k3);
  • explain the relationship between the structures of biological systems and their mechanical properties (k2);
  • apply fundamental physical concepts to biological structures and processes and describe these structures and processes (k3);
  • evaluate the suitability and limitations of experimental physical methods for studying biological systems (k3);
  • apply learned physical principles to new or related biological questions (k4).
During the course, students will acquire knowledge in the following areas and concepts of mechanobiology and tissue engineering:

  • biopolymers;
  • thermodynamics and kinetics of molecular interactions;
  • effect of forces on molecular interactions;
  • protein mechanics;
  • viscoelasticity;
  • cytoskeleton;
  • molecular motors;
  • cell mechanics;
  • cell adhesion and migration;
  • force generation and mechanosensing in biological systems;
  • mechanical properties of tissues;
  • mechanical regulation processes in mammalian, plant and bacterial cells.
Criteria for evaluation will be announced at the beginning of the course
Methods Lecture
Language English
Changing subject? No
On-site course
Maximum number of participants 20
Assignment procedure Direct assignment