Simone Schürle-Finke: Katalogdaten im Frühjahrssemester 2023 |
Name | Frau Prof. Dr. Simone Schürle-Finke |
Lehrgebiet | Medizinische Mikrosysteme |
Adresse | Medizinische Mikrosysteme ETH Zürich, GLC H 17.1 Gloriastrasse 37/ 39 8092 Zürich SWITZERLAND |
Telefon | +41 44 633 62 62 |
simone.schuerle@hest.ethz.ch | |
Departement | Gesundheitswissenschaften und Technologie |
Beziehung | Ausserordentliche Professorin |
Nummer | Titel | ECTS | Umfang | Dozierende | |
---|---|---|---|---|---|
376-0304-00L | Colloquium in Translational Science (Spring Semester) | 1 KP | 1K | N. Cesarovic, A. Alimonti, C. Ewald, V. Falk, J. Goldhahn, K. Maniura, R. M. Rossi, S. Schürle-Finke, G. Shivashankar, E. Vayena, V. Vogel, F. von Meyenn, weitere Dozierende | |
Kurzbeschreibung | Current topics in translational medicine presented by speakers from academia and industry. | ||||
Lernziel | Getting insight into actual areas and problems of translational medicine. | ||||
Inhalt | Timely and concise presentations of postgraduate students, post-docs, senior scientists, professors, as well as external guests from both academics and industry will present topics of their interest related to translational medicine. | ||||
Voraussetzungen / Besonderes | No compulsory prerequisites, but student should have basic knowledge about biomedical research. | ||||
376-1354-00L | Nanomaterials for Health | 4 KP | 2G | P. Wick, S. Schürle-Finke | |
Kurzbeschreibung | This course provides fundamentals concerning how nanomaterials can be beneficial for health, focusing on food, water, air, as well as diagnosis and therapy of diseases. | ||||
Lernziel | Students are able to - identify and remember the aspects of nanomaterials that have a (potential) impact on health; - systematically evaluate the contributions and potential impact of nanomaterials to a defined problem or application; - get inspired and be able to develop ideas regarding nanomaterials for well-defined health challenges. | ||||
Inhalt | Nanoscience and associated technologies drive development of useful new materials and enable a plethora of exciting discoveries and applications for our daily lives. 70 % of the inventions made during the last decades were directly or indirectly material related. A significant part thereof was made in the areas of health- or medical technologies anticipating the unmet needs of our society. The successful implementation of innovative nanomaterials designs for health relies on inter- & transdisciplinary efforts between different research fields. The lecture will focus on nanomaterials, their use in different areas of health, starting with food, food additive and food packaging, water and air disinfection, and applications in diagnosis and therapy. Further, it will provide foundational knowledge to create novel material designs for unmet clinical needs. 1. Introduction: definition and special properties of nanomaterials and nanomaterials safety (available as an online tutorial with a Q&A session in the lecture) 2. Nanomaterials synthesis (top down and bottom up) 3. Nanomaterials characterization (physical, chemical, and biological characterization) 4. Nanomaterials in food, food additives and packaging 5. Nanomaterials in water purification 6. Nanomaterials in surface and air purification 7. Nanomaterials in diagnostics and (bio)monitoring 8. Nanomaterials in therapeutics 9. Paper discussion of innovative proof of concept examples form the literature (guided Journal club) and further discussion of own ideas along the determined unmet health needs 10. End of semester performance assessment done as a presentation of a recent paper exploring the use of nanomaterial for health (lecturer provide a preselection of appropriate papers) | ||||
Voraussetzungen / Besonderes | Recommendation: 376-1353-00 Nanostructured Material Safety (NMS) In order to make the course accessible to all students, critical prerequisite information from NMS will be provided as an online self-guided learning module. | ||||
376-1624-00L | Practical Methods in Biofabrication | 5 KP | 4P | S. J. Ferguson, P. Chansoria, A. Puiggali-Jou, S. Schürle-Finke, weitere Dozierende | |
Kurzbeschreibung | Biofabrication involves the assembly of materials, cells, and biological building blocks into grafts for tissue engineering and in vitro models. The student learns techniques involving the fabrication and characterization of tissue engineered scaffolds and the design of 3D models based on medical imaging data. They apply this knowledge to design, manufacture and evaluate a biofabricated graft. | ||||
Lernziel | The objective of this course is to give students hands-on experience with the tools required to fabricate tissue engineered grafts. During the first part of this course, students will gain practical knowledge in hydrogel synthesis and characterization, fuse deposition modelling and stereolithography, bioprinting and bioink design, electrospinning, and cell culture and viability testing. They will also learn the properties of common biocompatible materials used in fabrication and how to select materials based on the application requirements. The students learn principles for design of 3D models. Finally the students will apply their knowledge to a problem-based Project in the second half of the Semester. The Project requires significant time outside of class Hours, strong commitment and ability to work independently. | ||||
Voraussetzungen / Besonderes | Not recommended if passed 376-1622-00 Practical Methods in Tissue Engineering |