Suchergebnis: Katalogdaten im Herbstsemester 2017
MAS in Medizinphysik | ||||||
Fachrichtung: Allg. Medizinphysik und Biomedizinisches Ingenieurwesen | ||||||
Vertiefung Bioengineering | ||||||
Wahlfächer Von den beiden Lerneinheiten 376-1622-00L Practical Methods in Tissue Engineering (angeboten im Herbstsemester) und 376-1624-00L Practical Methods in Biofabrication (angeboten im Frühjahrssemester) dürfen nicht beide angerechnet werden. | ||||||
Nummer | Titel | Typ | ECTS | Umfang | Dozierende | |
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151-0604-00L | Microrobotics | W | 4 KP | 3G | B. Nelson | |
Kurzbeschreibung | Microrobotics is an interdisciplinary field that combines aspects of robotics, micro and nanotechnology, biomedical engineering, and materials science. The aim of this course is to expose students to the fundamentals of this emerging field. Throughout the course students are expected to submit assignments. The course concludes with an end-of-semester examination. | |||||
Lernziel | The objective of this course is to expose students to the fundamental aspects of the emerging field of microrobotics. This includes a focus on physical laws that predominate at the microscale, technologies for fabricating small devices, bio-inspired design, and applications of the field. | |||||
Inhalt | Main topics of the course include: - Scaling laws at micro/nano scales - Electrostatics - Electromagnetism - Low Reynolds number flows - Observation tools - Materials and fabrication methods - Applications of biomedical microrobots | |||||
Skript | The powerpoint slides presented in the lectures will be mad available as pdf files. Several readings will also be made available electronically. | |||||
Voraussetzungen / Besonderes | The lecture will be taught in English. | |||||
227-0386-00L | Biomedical Engineering | W | 4 KP | 3G | J. Vörös, S. J. Ferguson, S. Kozerke, U. Moser, M. Rudin, M. P. Wolf, M. Zenobi-Wong | |
Kurzbeschreibung | Introduction into selected topics of biomedical engineering as well as their relationship with physics and physiology. The focus is on learning the concepts that govern common medical instruments and the most important organs from an engineering point of view. In addition, the most recent achievements and trends of the field of biomedical engineering are also outlined. | |||||
Lernziel | Introduction into selected topics of biomedical engineering as well as their relationship with physics and physiology. The course provides an overview of the various topics of the different tracks of the biomedical engineering master course and helps orienting the students in selecting their specialized classes and project locations. | |||||
Inhalt | Introduction into neuro- and electrophysiology. Functional analysis of peripheral nerves, muscles, sensory organs and the central nervous system. Electrograms, evoked potentials. Audiometry, optometry. Functional electrostimulation: Cardiac pacemakers. Function of the heart and the circulatory system, transport and exchange of substances in the human body, pharmacokinetics. Endoscopy, medical television technology. Lithotripsy. Electrical Safety. Orthopaedic biomechanics. Lung function. Bioinformatics and Bioelectronics. Biomaterials. Biosensors. Microcirculation.Metabolism. Practical and theoretical exercises in small groups in the laboratory. | |||||
Skript | Introduction to Biomedical Engineering by Enderle, Banchard, and Bronzino AND Link | |||||
327-1101-00L | Biomineralization | W | 2 KP | 2V | K.‑H. Ernst | |
Kurzbeschreibung | The course addresses undergraduate and graduate students interested in getting introduced into the basic concepts of biomineralization. | |||||
Lernziel | The course aims to introduce the basic concepts of biomineralization and the underlying principles, such as supersaturation, nucleation and growth of minerals, the interaction of biomolecules with mineral surfaces, and cell biology of inorganic materials creation. An important part of this class is the independent study and the presentation of original literature from the field. | |||||
Inhalt | Biomineralization is a multidisciplinary field. Topics dealing with biology, molecular and cell biology, solid state physics, mineralogy, crystallography, organic and physical chemistry, biochemistry, dentistry, oceanography, geology, etc. are addressed. The course covers definition and general concepts of biomineralization (BM)/ types of biominerals and their function / crystal nucleation and growth / biological induction of BM / control of crystal morphology, habit, shape and orientation by organisms / strategies of compartmentalization / the interface between biomolecules (peptides, polysaccharides) and the mineral phase / modern experimental methods for studying BM phenomena / inter-, intra, extra- and epicellular BM / organic templates and matrices for BM / structure of bone, teeth (vertebrates and invertebrates) and mollusk shells / calcification / silification in diatoms, radiolaria and plants / calcium and iron storage / impact of BM on lithosphere and atmosphere/ evolution / taxonomy of organisms. 1. Introduction and overview 2. Biominerals and their functions 3. Chemical control of biomineralization 4. Control of morphology: Organic templates and additives 5. Modern methods of investigation of BM 6. BM in matrices: bone and nacre 7. Vertebrate teeth 8. Invertebrate teeth 9. BM within vesicles: calcite of coccoliths 10. Silica 11. Iron storage and mineralization | |||||
Skript | Script with more than 600 pages with many illustrations will be distributed free of charge. | |||||
Literatur | 1) S. Mann, Biomineralization, Oxford University Press, 2001, Oxford, New York 2) H. Lowenstam, S. Weiner, On Biomineralization, Oxford University Press, 1989, Oxford 3) P. M. Dove, J. J. DeYoreo, S. Weiner (Eds.) Biomineralization, Reviews in Mineralogoy & Geochemistry Vol. 54, 2003 | |||||
Voraussetzungen / Besonderes | No special requirements are needed for attending. Basic knowledge in chemistry and cell biology is expected. | |||||
376-1622-00L | Practical Methods in Tissue Engineering Number of participants limited to 16 | W | 5 KP | 4P | K. Würtz-Kozak, O. Krupkova, M. Zenobi-Wong | |
Kurzbeschreibung | The goal of this course is to teach MSc students the necessary skills for doing research in the fields of tissue engineering and regenerative medicine. | |||||
Lernziel | Practical exercises and demonstrations on topics including sterile cell culture, light microscopy and histology, protein and gene expression analysis, and viability assays are covered. The advantages of 3D cell cultures will be discussed and practical work on manufacturing and evaluating hydrogels and scaffolds for tissue engineering will be performed in small groups. In addition to practical lab work, the course will teach skills in data acquisition/analysis. | |||||
402-0674-00L | Physics in Medical Research: From Atoms to Cells | W | 6 KP | 2V + 1U | B. K. R. Müller | |
Kurzbeschreibung | Scanning probe and diffraction techniques allow studying activated atomic processes during early stages of epitaxial growth. For quantitative description, rate equation analysis, mean-field nucleation and scaling theories are applied on systems ranging from simple metallic to complex organic materials. The knowledge is expanded to optical and electronic properties as well as to proteins and cells. | |||||
Lernziel | The lecture series is motivated by an overview covering the skin of the crystals, roughness analysis, contact angle measurements, protein absorption/activity and monocyte behaviour. As the first step, real structures on clean surfaces including surface reconstructions and surface relaxations, defects in crystals are presented, before the preparation of clean metallic, semiconducting, oxidic and organic surfaces are introduced. The atomic processes on surfaces are activated by the increase of the substrate temperature. They can be studied using scanning tunneling microscopy (STM) and atomic force microscopy (AFM). The combination with molecular beam epitaxy (MBE) allows determining the sizes of the critical nuclei and the other activated processes in a hierarchical fashion. The evolution of the surface morphology is characterized by the density and size distribution of the nanostructures that could be quantified by means of the rate equation analysis, the mean-field nucleation theory, as well as the scaling theory. The surface morphology is further characterized by defects and nanostructure's shapes, which are based on the strain relieving mechanisms and kinetic growth processes. High-resolution electron diffraction is complementary to scanning probe techniques and provides exact mean values. Some phenomena are quantitatively described by the kinematic theory and perfectly understood by means of the Ewald construction. Other phenomena need to be described by the more complex dynamical theory. Electron diffraction is not only associated with elastic scattering but also inelastic excitation mechanisms that reflect the electronic structure of the surfaces studied. Low-energy electrons lead to phonon and high-energy electrons to plasmon excitations. Both effects are perfectly described by dipole and impact scattering. Thin-films of rather complex organic materials are often quantitatively characterized by photons with a broad range of wavelengths from ultra-violet to infra-red light. Asymmetries and preferential orientations of the (anisotropic) molecules are verified using the optical dichroism and second harmonic generation measurements. These characterization techniques are vital for optimizing the preparation of medical implants and the determination of tissue's anisotropies within the human body. Cell-surface interactions are related to the cell adhesion and the contractile cellular forces. Physical means have been developed to quantify these interactions. Other physical techniques are introduced in cell biology, namely to count and sort cells, to study cell proliferation and metabolism and to determine the relation between cell morphology and function. 3D scaffolds are important for tissue augmentation and engineering. Design, preparation methods, and characterization of these highly porous 3D microstructures are also presented. Visiting clinical research in a leading university hospital will show the usefulness of the lecture series. | |||||
535-0423-00L | Drug Delivery and Drug Targeting | W | 2 KP | 1.5V | J.‑C. Leroux, A. Spyrogianni Roveri | |
Kurzbeschreibung | Die Studierenden erwerben einen Überblick über derzeit aktuelle Prinzipien, Methoden und Systeme zur kontrollierten Abgabe und zum Targeting von Arzneistoffen. Damit sind die Studierenden in der Lage, das Gebiet gemäss wissenschaftlichen Kriterien zu verstehen und zu beurteilen. | |||||
Lernziel | Die Studierenden verfügen über einen Überblick über derzeit aktuelle Prinzipien und Systeme zur kontrollierten Abgabe und zum Targeting von Arzneistoffen. Im Vordergrund der Lehrveranstaltung steht die Entwicklung von Fähigkeiten zum Verständnis der betreffenden Technologien und Methoden, ebenso wie der Möglichkeiten und Grenzen ihres therapeutischen Einsatzes. Im Zentrum stehen therapeutische Peptide, Proteine, Nukleinsäuren und Impfstoffe. | |||||
Inhalt | Der Kurs behandelt folgende Themen: Arzneistoff-targeting und Freigabeprinzipien, makromolekulare Arzneistofftransporter, Liposomen, Mizellen, Mikro/Nanopartikel, Gele und Implantate, Anwendung von Impfstoffen, Abgabe im Gastrointestinaltrakt, synthetische Transporter für Arzneistoffe auf Nukleinsäurebasis, ophthalmische Vehikel und neue Trends in transdermaler und nasaler Arzneistofffreigabe. | |||||
Skript | Ausgewählte Skripten, Vorlesungsunterlagen und unterstützendes Material werden entweder direkt an der Vorlesung ausgegeben oder sind über das Web zugänglich: Link Diese Website enthält auch zusätzliche Unterlagen zu peroralen Abgabesystemen, zur gastrointestinalen Passage von Arzneiformen, transdermalen Systemen und über Abgabesysteme für alternative Absorptionswege. Diese Stoffgebiete werden speziell in der Vorlesung Galenische Pharmazie II behandelt. | |||||
Literatur | A.M. Hillery, K. Park. Drug Delivery: Fundamentals & Applications, second edition, CRC Press, Boca Raton, FL, 2017. B. Wang B, L. Hu, T.J. Siahaan. Drug Delivery - Principles and Applications, second edition, John Wiley & Sons, Hoboken NJ, 2016. Y. Perrie, T. Rhades. Pharmaceutics - Drug Delivery and Targeting, second edition, Pharmaceutical Press, London and Chicago, 2012. Weitere Literatur in der Vorlesung. |
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