Search result: Catalogue data in Spring Semester 2019

Biology Master Information
Elective Major Subject Areas
Elective Major: Molecular Health Sciences
Elective Compulsory Master Courses
NumberTitleTypeECTSHoursLecturers
376-1306-00LClinical Neuroscience Information W3 credits3GG. Schratt, University lecturers
AbstractThe lecture series "Clinical Neuroscience" presents a comprehensive, condensed overview of the most important neurological diseases, their clinical presentation, diagnosis, therapy options and possible causes. Patient demonstrations (Übungen) follow every lecture that is dedicated to a particular disease.
ObjectiveBy the end of this module students should be able to:
- demonstrate their understanding and deep knowledge concerning the main neurological diseases
- identify and explain the different clinical presentation of these diseases, the methodology of diagnosis and the current therapies available
- summarize and critically review scientific literature efficiently and effectively
376-1392-00LMechanobiology: Implications for Development, Regeneration and Tissue EngineeringW3 credits2GA. Ferrari, K. Würtz-Kozak, M. Zenobi-Wong
AbstractThis course will emphasize the importance of mechanobiology to cell determination and behavior. Its importance to regenerative medicine and tissue engineering will also be addressed. Finally, this course will discuss how age and disease adversely alter major mechanosensitive developmental programs.
ObjectiveThis course is designed to illuminate the importance of mechanobiological processes to life as well as to teach good experimental strategies to investigate mechanobiological phenomena.
ContentTypically, cell differentiation is studied under static conditions (cells grown on rigid plastic tissue culture dishes in two-dimensions), an experimental approach that, while simplifying the requirements considerably, is short-sighted in scope. It is becoming increasingly apparent that many tissues modulate their developmental programs to specifically match the mechanical stresses that they will encounter in later life. Examples of known mechanosensitive developmental programs include osteogenesis (bones), chondrogenesis (cartilage), and tendogenesis (tendons). Furthermore, general forms of cell behavior such as migration, extracellular matrix deposition, and complex tissue differentiation are also regulated by mechanical stimuli. Mechanically-regulated cellular processes are thus ubiquitous, ongoing and of great clinical importance.

The overall importance of mechanobiology to humankind is illustrated by the fact that nearly 80% of our entire body mass arises from tissues originating from mechanosensitive developmental programs, principally bones and muscles. Unfortunately, our ability to regenerate mechanosensitive tissue diminishes in later life. As it is estimated that the fraction of the western world population over 65 years of age will double in the next 25 years, an urgency in the global biomedical arena exists to better understand how to optimize complex tissue development under physiologically-relevant mechanical environments for purposes of regenerative medicine and tissue engineering.
Lecture notesn/a
LiteratureTopical Scientific Manuscripts
551-0364-00LFunctional Genomics
Information for UZH students:
Enrolment to this course unit only possible at ETH. No enrolment to module BIO 254 at UZH.

Please mind the ETH enrolment deadlines for UZH students: Link
W3 credits2VC. von Mering, C. Beyer, B. Bodenmiller, M. Gstaiger, H. Rehrauer, R. Schlapbach, K. Shimizu, N. Zamboni, further lecturers
AbstractFunctional genomics is key to understanding the dynamic aspects of genome function and regulation. Functional genomics approaches use the wealth of data produced by large-scale DNA sequencing, gene expression profiling, proteomics and metabolomics. Today functional genomics is becoming increasingly important for the generation and interpretation of quantitative biological data.
ObjectiveFunctional genomics is key to understanding the dynamic aspects of genome function and regulation. Functional genomics approaches use the wealth of data produced by large-scale DNA sequencing, gene expression profiling, proteomics and metabolomics. Today functional genomics is becoming increasingly important for the generation and interpretation of quantitative biological data. Such data provide the basis for systems biology efforts to elucidate the structure, dynamics and regulation of cellular networks.
ContentThe curriculum of the Functional Genomics course emphasizes an in depth understanding of new technology platforms for modern genomics and advanced genetics, including the application of functional genomics approaches such as advanced microarrays, proteomics, metabolomics, clustering and classification. Students will learn quality controls and standards (benchmarking) that apply to the generation of quantitative data and will be able to analyze and interpret these data. The training obtained in the Functional Genomics course will be immediately applicable to experimental research and design of systems biology projects.
Prerequisites / NoticeThe Functional Genomics course will be taught in English.
551-0338-00LCurrent Approaches in Single Cell Analysis (University of Zurich)
No enrolment to this course at ETH Zurich. Book the corresponding module directly at UZH.
UZH Module Code: BIO256

Mind the enrolment deadlines at UZH:
Link
W2 credits1VUniversity lecturers
AbstractIn this lecture, we will discuss the most important single cell
approaches, the questions they can address and current developments. We will cover single cell: genomics, transcriptomics, proteomics (CyTOF mass cytometry), metabolomics and highly multiplexed imaging. Finally, we will also discuss the latest approaches for the analysis of such generated highly multiplexed single cell data.
ObjectiveOn completion of this module the students should be able to:
- explain the basic principles of single cell analysis techniques
- identify and justify the limitations of the current single cell
technologies and suggest reasonable improvements
- know the basic challenges in data analysis imposed by the complex
multi parameter data.
Key skills:
On completion of this module the students should be able to:
- summarize and discuss the impact these technologies have on biology
and medicine
- design biological and biomedical experiments for which single cell
analysis is essential
ContentCurrently single cell analysis approaches revolutionize the way we study and understand biological systems. In all biological and biomedical settings, cell populations and tissues are highly heterogeneous; this heterogeneity plays a critical role in basic biological processes such as cell cycle, development and organismic function, but is also a major player in disease, e.g. for cancer development, diagnosis and treatment.
Currently, single cell analysis techniques are rapidly developing and
find broad application, as the single cell measurements not only enable
to study cell specific functions, but often reveal unexpected biological
mechanisms in so far (assumed) well understood biological processes.
In this lecture, we will discuss the most important single cell approaches, the questions they can address and current developments. We will cover single cell genomics, single cell transcriptomics, single cell proteomics (CyTOF mass cytometry), single cell metabolomics and highly multiplexed single cell imaging. Finally, we will also discuss the latest approaches for the analysis of such generated highly multiplexed single cell data.
551-1404-00LRNA and Proteins: Post-Transcriptional Regulation of Gene Expression (University of Zurich)
No enrolment to this course at ETH Zurich. Book the corresponding module directly at UZH.
UZH Module Code: BCH252

Mind the enrolment deadlines at UZH:
Link
W3 credits2VUniversity lecturers
AbstractThe course introduces the cellular processes and molecular mechanisms involved in regulating genome expression at the post-transcriptional level.
Topics will include :
-RNA processing, and transport;
-protein synthesis and translational control, trafficking and degradation;
-RNA-guided regulation (RNA interference, microRNAs);
-molecular surveillance and quality control mechanisms
Objective-Outline the cellular processes
used by eukaryotic and prokaryotic cells
to control gene expression at the post-
transcriptional level.
-Describe the molecular mechanisms
underlying post-transcriptional gene
regulation
-Identify experimental approaches
used to study post-transcriptional gene
regulation and describe their strengths
and weaknesses.
636-0111-00LSynthetic Biology I
Attention: This course was offered in previous semesters with the number: 636-0002-00L "Synthetic Biology I". Students that already passed course 636-0002-00L cannot receive credits for course 636-0111-00L.
W4 credits3GS. Panke, J. Stelling
AbstractTheoretical & practical introduction into the design of dynamic biological systems at different levels of abstraction, ranging from biological fundamentals of systems design (introduction to bacterial gene regulation, elements of transcriptional & translational control, advanced genetic engineering) to engineering design principles (standards, abstractions) mathematical modelling & systems desig
ObjectiveAfter the course, students will be able to theoretically master the biological and engineering fundamentals required for biological design to be able to participate in the international iGEM competition (see Link).
ContentThe overall goal of the course is to familiarize the students with the potential, the requirements and the problems of designing dynamic biological elements that are of central importance for manipulating biological systems, primarily (but not exclusively) prokaryotic systems. Next, the students will be taken through a number of successful examples of biological design, such as toggle switches, pulse generators, and oscillating systems, and apply the biological and engineering fundamentals to these examples, so that they get hands-on experience on how to integrate the various disciplines on their way to designing biological systems.
Lecture notesHandouts during classes.
LiteratureMark Ptashne, A Genetic Switch (3rd ed), Cold Spring Haror Laboratory Press
Uri Alon, An Introduction to Systems Biology, Chapman & Hall
Prerequisites / Notice1) Though we do not place a formal requirement for previous participation in particular courses, we expect all participants to be familiar with a certain level of biology and of mathematics. Specifically, there will be material for self study available on Link as of mid January, and everybody is expected to be fully familiar with this material BEFORE THE CLASS BEGINS to be able to follow the different lectures. Please contact Link for access to material
2) The course is also thought as a preparation for the participation in the international iGEM synthetic biology summer competition (Link, Link). This competition is also the contents of the course Synthetic Biology II. Link
551-1700-00LIntroduction to Flow Cytometry Restricted registration - show details
Number of participants limited to 24.
W2 credits1VJ. Kisielow, L. Tortola, further lecturers
AbstractThe lecture provides an introduction to flow cytometry. We will cover the technology basics, experimental design, data acquisition and analysis of flow and mass cytometry. In addition, various research applications will be discussed. The format is a lecture course enriched by a visit to the ETH Flow Cytometry Core Facility and practical demonstration of the use of analysis and sorting instruments.
ObjectiveThe goal of this course is to provide the basic knowledge of flow and mass cytometry required for planning and execution of cytometric experiments.
ContentThe lecture course aims at teaching principles of flow cytometry. The emphasis is on theoretical principles (signal detection, fluorochromes, signal spill-over and compensation) as well as practical aspects of experimental design and performance (sample preparation, controls, data acquisition and analysis).
List of topics:
- Principles of Flow Cytometry
- Signal processing
- Compensation and Controls
- Data analysis, gating and presentation
- Panel design
- Sorting
- Mass cytometry
- High-dimensional data analysis
- Practical demonstration (hardware and software)
Modern flow cytometric techniques for immunophenotyping, analysis of proliferation, cell cycle, apoptosis and cell signalling will be introduced.
Lecture notesUpdated handouts will be provided during the class.
LiteratureCurrent literature references on immunophenotyping, analysis of proliferation, cell cycle, apoptosis and cell signalling will be discussed during the lectures.
701-1708-00LInfectious Disease DynamicsW4 credits2VS. Bonhoeffer, R. D. Kouyos, R. R. Regös, T. Stadler
AbstractThis course introduces into current research on the population biology of infectious diseases. The course discusses the most important mathematical tools and their application to relevant diseases of human, natural or managed populations.
ObjectiveAttendees will learn about:
* the impact of important infectious pathogens and their evolution on human, natural and managed populations
* the population biological impact of interventions such as treatment or vaccination
* the impact of population structure on disease transmission

Attendees will learn how:
* the emergence spread of infectious diseases is described mathematically
* the impact of interventions can be predicted and optimized with mathematical models
* population biological models are parameterized from empirical data
* genetic information can be used to infer the population biology of the infectious disease

The course will focus on how the formal methods ("how") can be used to derive biological insights about the host-pathogen system ("about").
ContentAfter an introduction into the history of infectious diseases and epidemiology the course will discuss basic epidemiological models and the mathematical methods of their analysis. We will then discuss the population dynamical effects of intervention strategies such as vaccination and treatment. In the second part of the course we will introduce into more advanced topics such as the effect of spatial population structure, explicit contact structure, host heterogeneity, and stochasticity. In the final part of the course we will introduce basic concepts of phylogenetic analysis in the context of infectious diseases.
Lecture notesSlides and script of the lecture will be available online.
LiteratureThe course is not based on any of the textbooks below, but they are excellent choices as accompanying material:
* Keeling & Rohani, Modeling Infectious Diseases in Humans and Animals, Princeton Univ Press 2008
* Anderson & May, Infectious Diseases in Humans, Oxford Univ Press 1990
* Murray, Mathematical Biology, Springer 2002/3
* Nowak & May, Virus Dynamics, Oxford Univ Press 2000
* Holmes, The Evolution and Emergence of RNA Viruses, Oxford Univ Press 2009
Prerequisites / NoticeBasic knowledge of population dynamics and population genetics as well as linear algebra and analysis will be an advantage.
Elective Major: Biochemistry
Compulsory Concept Courses
NumberTitleTypeECTSHoursLecturers
551-0320-00LCellular Biochemistry (Part II)O3 credits2VY. Barral, R. Kroschewski, A. E. Smith
AbstractThis course will focus on molecular mechanisms and concepts underlying cellular biochemistry, providing advanced insights into the structural and functional details of individual cell components, and the complex regulation of their interactions. Particular emphasis will be on the spatial and temporal integration of different molecules and signaling pathways into global cellular processes.
ObjectiveThe full-year course (551-0319-00 & 551-0320-00) focuses on the molecular mechanisms and concepts underlying the biochemistry of cellular physiology, investigating how these processes are integrated to carry out highly coordinated cellular functions. The molecular characterization of complex cellular functions requires a combination of approaches such as biochemistry, but also cell biology and genetics. This course is therefore the occasion to discuss these techniques and their integration in modern cellular biochemistry.
The students will be able to describe the structural and functional details of individual cell components, and the spatial and temporal regulation of their interactions. In particular, they will learn to explain how different molecules and signaling pathways can be integrated during complex and highly dynamic cellular processes such as intracellular transport, cytoskeletal rearrangements, cell motility, and cell division. In addition, they will be able to illustrate the relevance of particular signaling pathways for cellular pathologies such as cancer or during cellular infection.
ContentSpatial and temporal integration of different molecules and signaling pathways into global cellular processes, such as cell division, cell infection and cell motility. Emphasis is also put on the understanding of pathologies associated with defective cell physiology, such as cancer or during cellular infection.
LiteratureRecommended supplementary literature (review articles and selected primary literature) will be provided during the course.
Prerequisites / NoticeTo attend this course the students must have a solid basic knowledge in chemistry, biochemistry, cell biology and general biology. Biology students have in general already attended the first part of the "Cellular Biochemistry" concept course (551-0319-00). The course will be taught in English.
In addition, the course will be based on a blended-learning scenario, where frontal lectures will be complemented with carefully chosen web-based teaching elements that students access through the ETH Moodle platform.
Compulsory Master Course
NumberTitleTypeECTSHoursLecturers
551-1310-00LA Problem-Based Approach to Cellular Biochemistry Restricted registration - show details
Number of participants limited to 15.
O6 credits2GM. Peter, E. Dultz, M. Gstaiger, V. Korkhov, V. Panse, A. E. Smith
AbstractIndependent, guided acquisition of an overview over a defined area of research, identification of important open questions, development of an experimental strategy to address a defined question, and formulation of this strategy within the framework of a research grant.
ObjectiveThe students will learn to acquire independently an overview over a defined area of research, and to identify important open questions. In addition, they will learn to develop an experimental strategy to address a defined question, and to formulate this strategy within the framework of a research grant.
ContentThe students will work in groups of two to three, in close contact with a tutor (ETH Prof or senior scientist). A research overview with open questions and a research grant will be developed independently by the students, with guidance from the tutor through regular mandatory meetings. The students will write both the research overview with open questions and the grant in short reports, and present them to their colleagues.
LiteratureThe identification of appropriate literature is a component of the course.
Prerequisites / NoticeThis course will be taught in english, and requires extensive independent work.
Elective Compulsory Concept Courses
See D-BIOL Master Studies Guide
NumberTitleTypeECTSHoursLecturers
551-0326-00LCell Biology Information W6 credits4VS. Werner, M. Bordoli, R. Henneberger, W. Kovacs, M. Schäfer, U. Suter, A. Wutz
AbstractThis Course introduces principle concepts, techniques, and experimental strategies used in modern Cell Biology. Major topics include: neuron-glia interactions in health and disease; mitochondrial dynamics; stem cell biology; growth factor action in development, tissue repair and disease; cell metabolism, in particular sensing and signaling mechanisms, cell organelles, and lipid metabolism.
Objective-To prepare the students for successful and efficient lab work by learning how to ask the right questions and to use the appropriate techniques in a research project.
-To convey knowledge about neuron-glia interactions in health and disease.
- To provide information on different types of stem cells and their function in health and disease
-To provide information on growth factor signaling in development, repair and disease and on the use of growth factors or their receptors as drug targets for major human diseases
-To convey knowledge on the mechanisms underlying repair of injured tissues
-To provide the students with an overview of mitochondrial dynamics.
-Providing an understanding of RNA processing reactions and their regulations.
-To provide a comprehensive understanding of metabolic sensing mechanisms occurring in different cell types and organelles in response to glucose, hormones, oxygen, nutrients as well as lipids, and to discuss downstream signaling pathways and cellular responses.
-To provide models explaining how disturbances in complex metabolic control networks and bioenergetics can lead to disease and to highlight latest experimental approaches to uncover the intricacies of metabolic control at the cellular and organismal level.
-Providing the background and context that foster cross-disciplinary scientific thinking.
551-0307-01LMolecular and Structural Biology II: From Gene to Protein
D-BIOL students are obliged to take part I and part II as a two-semester course.
W3 credits2VN. Ban, F. Allain, S. Jonas, M. Pilhofer
AbstractThis course will cover advanced topics in molecular biology and biochemistry with emphasis on the structure and function of cellular assemblies involved in expression and maintenance of genetic information. We will cover the architecture and the function of molecules involved in DNA replication, transcription, translation, nucleic acid packaging in viruses, RNA processing, and CRISPER/CAS system.
ObjectiveStudents will gain a deep understanding of large cellular assemblies and the structure-function relationships governing their function in fundamental cellular processes ranging from DNA replication, transcription and translation. The lectures throughout the course will be complemented by exercises and discussions of original research examples to provide students with a deeper understanding of the subjects and to encourage active student participation.
ContentAdvanced class covering the state of the research in structural molecular biology of basic cellular processes with emphasis on the function of large cellular assemblies.
Lecture notesUpdated handouts will be provided during the class.
LiteratureThe lecture will be based on the latest literature. Additional suggested
literature:
Branden, C., and J. Tooze, Introduction to Protein Structure, 2nd ed.
(1995). Garland, New York.
Elective Compulsory Master Courses
NumberTitleTypeECTSHoursLecturers
551-0140-00LEpigeneticsW4 credits2VA. Wutz, U. Grossniklaus, R. Paro, R. Santoro
AbstractEpigenetics studies the inheritance of traits that cannot be attributed to changes in the DNA sequence. The lecture will present an overview of different epigenetic phenomena and provide detailed insight into the underlying molecular mechanisms. The role of epigenetic processes in the development of cancer and other disorders will be discussed.
ObjectiveThe aim of the course is to gain an understanding of epigenetic mechanisms and their impact on the development of organisms, regenerative processes or manifestation of disease.
ContentTopics
- historical overview, concepts and comparison Genetics vs. Epigenetics
- Biology of chromatin: structure and function, organization in the nucleus and the role of histone modifications in processes like transcription and replication
- DNA methylation as an epigenetic modification
- Inheritance of epigenetic modifications during cell division: cellular memory
- Stability and reversibility of epigenetic modifications: cellular plasticity and stem cells
- Genomic imprinting in plants and mammals
- X chromosome inactivation and dosis compensation
- position effects, paramutations and transvection
- RNA-induced gene silencing
- The role of epigenetic processes in cancer development or cell aging
551-1100-00LInfectious Agents: From Molecular Biology to Disease
Number of participants limited to 22.
Requires application until 2 weeks before the start of the semester; selected applicants will be notified one week before the first week of lectures.
(if you missed the deadline, please come to the first date to see, if there are any slots left)
W4 credits2SW.‑D. Hardt, L. Eberl, U. F. Greber, A. B. Hehl, M. Kopf, S. R. Leibundgut, C. Münz, A. Oxenius, P. Sander
AbstractLiterature seminar for students at the masters level and PhD students. Introduction to the current research topics in infectious diseases; Introduction to key pathogens which are studied as model organisms in this field; Overview over key research groups in the field of infectious diseases in Zürich.
ObjectiveWorking with the current research literature. Getting to know the key pathogens serving as model organisms and the research technologies currently used in infection biology.
Contentfor each model pathogen (or key technology):
1. introduction to the pathogen
2. Discussion of one current research paper.
The paper will be provided by the respective supervisor. He/she will give advice (if required) and guide the respective literature discussion.
Lecture notesTeachers will provide the research papers to be discussed.
Students will prepare handouts for the rest of the group for their assigned seminar.
LiteratureTeachers will provide the research papers to be discussed.
Prerequisites / NoticeRestricted to max 22 students. Please sign up until two weeks before the beginning of the semester via e-mail to Link and include the following information: 551-1100-00L; your name, your e-mail address, university/eth, students (specialization, semester), PhD students (research group, member of a PhD program? which program?). The 22 students admitted to this seminar will be selected and informed by e-mail in the week befor the beginning of the semester by W.-D. Hardt.
The first seminar date will serve to form groups of students and assign a paper to each group.
551-1402-00LMolecular and Structural Biology VI: Biophysical Analysis of Macromolecular Mechanisms
This course is strongly recommended for the Masters Major "Biology and Biophysics".
W4 credits2VR. Glockshuber, T. Ishikawa, S. Jonas, B. Schuler, D. Veprintsev, E. Weber-Ban
AbstractThe course is focussed on biophysical methods for characterising conformational transitions and reaction mechanisms of proteins and biological mecromolecules, with focus on methods that have not been covered in the Biology Bachelor Curriculum.
ObjectiveThe goal of the course is to give the students a broad overview on biopyhsical techniques available for studying conformational transitions and complex reaction mechanisms of biological macromolecules. The course is particularly suited for students enrolled in the Majors "Structural Biology and Biophysics", "Biochemistry" and "Chemical Biology" of the Biology MSc curriculum, as well as for MSc students of Chemistry and Interdisciplinary Natural Sciences".
ContentThe biophysical methods covered in the course include advanced reaction kinetics, methods for the thermodynamic and kinetic analysis of protein-ligand interactions, static and dynamic light scattering, analytical ultracentrifugation, spectroscopic techniques such as fluorescence anisotropy, fluorescence resonance energy transfer (FRET) and single molecule fluorescence spectrosopy, modern electron microscopy techniques, atomic force microscopy, and isothermal and differential scanning calorimetry.
Lecture notesCourse material from the individual lecturers wil be made available at the sharepoint website

Link
Prerequisites / NoticeFinished BSc curriculum in Biology, Chemistry or Interdisciplinary Natural Sciences. The course is also adequate for doctoral students with research projects in structural biology, biophysics, biochemistry and chemical biology.
551-0224-00LAdvanced Proteomics Restricted registration - show details
For master students from the 2nd semester on, also doctoral candidates and post docs.
W4 credits6GR. Aebersold, L. Gillet, M. Gstaiger, A. Leitner, P. Pedrioli
AbstractGoal of the course is to analyze current and newly emerging technologies and approaches in protein and proteome analysis with regard to their application in biology, biotechnology and medicine.
Format: Introduction by instructor followed by discussions stimulated by reading assignments and exercises.
ObjectiveTo discuss current and newly emerging technologies and approaches in protein and proteome analysis with regard to their applications in biology, biotechnology, medicine and systems biology.
ContentBlock course teaching current methods for the acquisition and processing of proteomic datasets.
Prerequisites / NoticeNumber of people: Not exceeding 30.
Students from ETHZ, Uni Zurich and University of Basel
Non-ETH students must register at ETH Zurich as special students Link
551-0364-00LFunctional Genomics
Information for UZH students:
Enrolment to this course unit only possible at ETH. No enrolment to module BIO 254 at UZH.

Please mind the ETH enrolment deadlines for UZH students: Link
W3 credits2VC. von Mering, C. Beyer, B. Bodenmiller, M. Gstaiger, H. Rehrauer, R. Schlapbach, K. Shimizu, N. Zamboni, further lecturers
AbstractFunctional genomics is key to understanding the dynamic aspects of genome function and regulation. Functional genomics approaches use the wealth of data produced by large-scale DNA sequencing, gene expression profiling, proteomics and metabolomics. Today functional genomics is becoming increasingly important for the generation and interpretation of quantitative biological data.
ObjectiveFunctional genomics is key to understanding the dynamic aspects of genome function and regulation. Functional genomics approaches use the wealth of data produced by large-scale DNA sequencing, gene expression profiling, proteomics and metabolomics. Today functional genomics is becoming increasingly important for the generation and interpretation of quantitative biological data. Such data provide the basis for systems biology efforts to elucidate the structure, dynamics and regulation of cellular networks.
ContentThe curriculum of the Functional Genomics course emphasizes an in depth understanding of new technology platforms for modern genomics and advanced genetics, including the application of functional genomics approaches such as advanced microarrays, proteomics, metabolomics, clustering and classification. Students will learn quality controls and standards (benchmarking) that apply to the generation of quantitative data and will be able to analyze and interpret these data. The training obtained in the Functional Genomics course will be immediately applicable to experimental research and design of systems biology projects.
Prerequisites / NoticeThe Functional Genomics course will be taught in English.
551-1126-00LTechnologies in Molecular MicrobiologyW4 credits2VH.‑M. Fischer, B. Christen, M. Christen, further lecturers
AbstractThe lecture course provides an advanced understanding of modern techniques used in molecular microbiology. Current technologies and research directions in molecular microbiology including applied aspects will be illustrated with paper discussions. The format is a lecture course enriched by group activities.
ObjectiveThe lecture course aims at providing principles of modern techniques used in molecular microbiology. Emphasis is on genetic, biochemical, and cellular analysis including also bioinformatics aspects. Discussion of a set of commonly applied technologies will assist students in evaluating current research in molecular microbiology and choosing appropriate methods for their own demands.
ContentImportant genetic, biochemical, biophysical, bioinformatic and structural analysis methods will be presented that are used to gain a deeper understanding of the molecular principles and mechanisms underlying basic physiological processes in prokaryotes. Applied aspects of molecular microbiology and current research in this area will also be covered.

List of topics:
- Analysis of genes, genomes and transcriptomes
- Analysis of proteins, proteomes and microbial systems
- Synthetic biology
Lecture notesUpdated handouts will be provided during the class.
LiteratureCurrent literature references, relevant papers and handouts will be provided during the lectures.
Prerequisites / NoticeThe following lecturers will contribute to the course:

Prof. Beat Christen (ETH)
Dr. Matthias Christen (ETH)
Prof. Hans-Martin Fischer (ETH)
Dr. Jonas Grossmann (FGCZ)
Dr. Florian Freimoser (Agroscope)
Dr. Bernd Roschitzki (FGCZ)
Dr. Roman Spörri (ETH)
227-0396-00LEXCITE Interdisciplinary Summer School on Bio-Medical Imaging Information Restricted registration - show details
The school admits 60 MSc or PhD students with backgrounds in biology, chemistry, mathematics, physics, computer science or engineering based on a selection process.

Students have to apply for acceptance by April 22, 2019. To apply a curriculum vitae and an application letter need to be submitted. The notification of acceptance will be given by May 24, 2019. Further information can be found at: Link.
W Dr4 credits6GS. Kozerke, G. Csúcs, J. Klohs-Füchtemeier, S. F. Noerrelykke, M. P. Wolf
AbstractTwo-week summer school organized by EXCITE (Center for EXperimental & Clinical Imaging TEchnologies Zurich) on biological and medical imaging. The course covers X-ray imaging, magnetic resonance imaging, nuclear imaging, ultrasound imaging, infrared and optical microscopy, electron microscopy, image processing and analysis.
ObjectiveStudents understand basic concepts and implementations of biological and medical imaging. Based on relative advantages and limitations of each method they can identify preferred procedures and applications. Common foundations and conceptual differences of the methods can be explained.
ContentTwo-week summer school on biological and medical imaging. The course covers concepts and implementations of X-ray imaging, magnetic resonance imaging, nuclear imaging, ultrasound imaging, infrared and optical microscopy and electron microscopy. Multi-modal and multi-scale imaging and supporting technologies such as image analysis and modeling are discussed. Dedicated modules for physical and life scientists taking into account the various backgrounds are offered.
Lecture notesHand-outs, Web links
Prerequisites / NoticeThe school admits 60 MSc or PhD students with backgrounds in biology, chemistry, mathematics, physics, computer science or engineering based on a selection process. To apply a curriculum vitae, a statement of purpose and applicants references need to be submitted. Further information can be found at: Link
227-0390-00LElements of MicroscopyW4 credits3GM. Stampanoni, G. Csúcs, A. Sologubenko
AbstractThe lecture reviews the basics of microscopy by discussing wave propagation, diffraction phenomena and aberrations. It gives the basics of light microscopy, introducing fluorescence, wide-field, confocal and multiphoton imaging. It further covers 3D electron microscopy and 3D X-ray tomographic micro and nanoimaging.
ObjectiveSolid introduction to the basics of microscopy, either with visible light, electrons or X-rays.
ContentIt would be impossible to imagine any scientific activities without the help of microscopy. Nowadays, scientists can count on very powerful instruments that allow investigating sample down to the atomic level.
The lecture includes a general introduction to the principles of microscopy, from wave physics to image formation. It provides the physical and engineering basics to understand visible light, electron and X-ray microscopy.
During selected exercises in the lab, several sophisticated instrument will be explained and their capabilities demonstrated.
LiteratureAvailable Online.
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