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Displaying results 41 to 50 of 1436.
Recombinant Protein Expression
Proteins play an important role in infectious diseases. They not only take over central functions in the invasion and replication of pathogens, but also in the defensive reaction of our body or as a drug. For a detailed investigation of proteins, scientists often require them in large amounts and extremely pure state. Read more about how proteins are artificially produced and purified.
Flow Cytometry and Cell Sorting
Our organism is made of many different cells that are specialized to perform specific tasks. As long as they work together in the collective, we will stay healthy – do they change or are they changed by pathogens, we become unbalanced and sick. The Flow Cytometry and Cell Sorting platform provides the instrumentation and expert knowledge for the phenotypic identification and functional analysis of cells at the single cell level.
Compound Profiling and Screening
The World Health Organization (WHO) considers the spread of microorganisms which are resistant to the most common antibiotics an increasing threat to the well-being of the world population. Not only is the number of patients increasing whose infectious disease can no longer be treated, but also in some circumstances patients with other severe diseases will not be treated if the therapy is accompanied with suppression of the immune system and thus, an increased risk of infection. Thus, new active agents for the treatment of infectious diseases are urgently needed, as well as the responsible use of existing antibiotics. Prerequisites for the discovery of new drugs are relevant biological screening assays together with compound libraries of broad chemical diversity. We perform primary screens, based either on own protocols or on protocols developed by cooperation partners and transferred to our infrastructure. In cooperation with partners we also perform secondary assays to optimize first primary hits.
Systems Immunology
To see the immune system with the eyes of mathematics – that is the guiding principle of the department Systems Immunology. Mathematical models help to faster and better understand diseases that are associated with immune functions. Read here how scientists use mathematics to investigate chronic inflammatory diseases, the regulation of adaptive immune responses, and the interaction between the nervous, the endocrine and the immune system.
Neuroinflammation and Neurodegeneration
What kind of role play infections and the associated inflammatory reactions for the progression or even for the onset of neurodegenerative diseases? Recurrent infections and the involved inflammation may trigger a series of processes in the brain that finally lead to neuronal damage due to the immune response. Thus, better understanding of neurodegenerative processes could improve the therapeutic approach in neurodegenerative disease.
Model Systems for Infection and Immunity
In infection research experiments on cells and mice have a pivotal role. Frequently such model systems have to be tailored to allow tackling a specific scientific question. To this end, genetic modification of cell lines and mice is being pursued.
Microbial Immune Regulation
The microbiota encompasses a diverse population of microorganisms that colonize many body sites such as skin and intestine of multicellular hosts. The composition of the microbiota in humans is highly variable and is influenced by nutrition, immune competence, illness and use of medication (especially antibiotics). We are interested to enhance our understanding on how these microbial communities affect human infectious diseases and how they can be manipulated to treat diseases.
Infection Immunology
An infection can be seen as a fight between a microbe and our body’s defence mechanisms. The microbe is trying to multiply and disseminate, while the different components of our immune system will work together trying to stop this process. This is not an easy mission for our body because microbes have learned how to hide, evade or even destroy some of the components of the immune system as well as how to resist antibiotic treatment. The focus of our research is to understand the battle between microbes and our immune defences. If we know the different tricks and mechanisms employed by the microbes to breach our defences we will be able to design new strategies to counteract and disarm the attacking microorganisms.
Immune Regulation
Due to their physiological functions our mucosal surfaces are in direct contact to the environment and thus represent the major port of entry for pathogens. To protect the body from severe infections an effective mucosal immune system is indispensable. We are studying respiratory tract infections with the focus on influenza and pneumococci, which represent the most frequent viral and bacterial infectious agents for pneumonia in humans. A major focus of our research is to study molecular and cellular processes during coinfection with influenza and pneumococci and here in particular the immunological functions of the alveolar epithelium in host defense.
Innate Immunity and Infection
The moment a pathogen, which has successfully entered the body, is recognized, the body quickly mobilizes its defenses. Interferons are molecules that are counted among the body’s first line of defense. They prevent proliferation and the spread of viruses in the body and serve to alert the immune system. Read here about the different ways we use to try and decode this system, all in an effort to find new approaches to infectious disease prevention and therapy.
