Afleveringen
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Artemisinins are very poweful tools in the treatment of malaria, and the emerging loss of their activity has the potential to create a major public health problem. MALARIA TREATMENT
Dr Charlie Woodrow is based at MORU in Bangkok, Thailand, where he coordinates clinical and laboratory studies on resistance to artemisinins. Bringing together diverse datasets of clinical, in vitro and molecular data has helped better understand the emerging resistance, particularly in Myanmar. -
Identifying and addressing ethical issues are key to the success of any clinical trials, particularly when working with vulnerable populations. Dr Phaik Yeong Cheah leads the Department of Bioethics & Engagement at the Mahidol Oxford Tropical Medicine Research Unit (MORU) in Thailand. She is particularly interested in ethical issues in community engagement, data sharing, consent and assent in paediatric research.
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Zijn er afleveringen die ontbreken?
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In settings with high level of poverty and over-stretched health services, researchers have even greater responsibilities to the communities and study participants. SOCIAL AND BEHAVIOURAL RESEARCH
A social scientist and public health researcher based in Kenya, Professor Vicki Marsh aims to understand and strenghten policies based on social and ethical aspects of international collaborations. Improving communications between researchers and the patients and local communities is not only ethically important; it can also lead to better research. -
Melanoma or skin cancer is one of the fastest rising cancer types. When identified early, melanoma is relatively easy to cure, but once it starts to metastasise, it becomes very difficult to treat. DEREGULATION OF TRANSCRIPTION
The interface between signal transduction and transcription regulation coordinates gene expression. Deregulation of transcription is a key factor in cancer. Professor Colin Goding studies how a precise programme of transcription regulation is achieved, particularly in the transition between normal and cancer stem cells, and the parallels with normal stem cell populations. -
Transcription is a tightly regulated process, where chemical modifications initiate the duplication of genetic material. This epigenetic process is often dysregulated in cancer, but it can be targeted with small molecule inhibitors. EPIGENETIC SIGNALLING
Professor Panagis Filippakopoulos is interested in the molecular mechanisms of transcription, where the formation of non-covalent protein complexes is mediated by post-translational modifications. Dysfunction in this epigenetic signalling process is linked to disease, particularly cancer. -
Asthma and COPD (chronic obstructive pulmonary disease) are common conditions that affect the lives of many people. Dr Mona Bafadhel studies the pathophysiology of COPD (chronic obstructive pulmonary disease). There are broadly two inflammatory phenotypes of COPD that are clinically indistinguishable but have different treatment responses. Dr Bafadhel is working on the development of novel therapeutic strategies for COPD, particularly to treat the regular periods of worsened symptoms that patients experience.
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Alteration of gene expression is fundamental to many diseases. A better understanding of how epigenetic proteins affect diseases provides a starting point for therapy development and the discovery of new drug. Professor Paul Brennan research focusses on epigenetics: the mechanisms that control gene expression. He studies how chemical probes interfere with epigenetic enyzmes that can be targeted to treat various diseases. Epigenetics combined with disease biology will ultimately accelerate drug discovery.
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A missing step in a metabolic pathway leads to the build-up of toxic compounds, and the lack of materials essential for normal function. Professor Wyatt Yue explores how genetic defects lead to disease at the molecular level, by determining 3D structures and biochemical properties of enzymes and protein complexes linked to congenital genetic errors. Professor Yue works closely with clinicians and paediatricians to decipher the underlying genetic, biochemical and cellular mechanisms of these diseases. His long-term aim is to help design novel therapeutic approaches for metabolic diseases.
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Economics and health are interlinked in many ways, as seen in the vicious cycle between poverty and ill health. Dr Yoel Lubell leads the economic team at the MORU Mathematical and Economic Modelling Group, based in Bangkok, Thailand. His research focuses on the evaluation of diagnostics, treatments and vaccines for infectious diseases, with the aim of providing guidance on malaria elimination and control of artemisinin resistance in the Mekong region.
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Too high a dose can result in toxicity and side-effects, too low a dose can cause the illness to come back and at worse develop resistance. Professor Joel Tarning is Head of Clinical Pharmacology in our MORU Unit in Bangkok, Thailand. He's working towards drug dose-optimisation using novel pharmacometric modelling approaches. He is particularly interested in antimalarial treatments for children and pregnant women.
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Dr Christiane Dolecek speaks about the research on enteric fever she conducted in Vietman and Nepal. Dr Christiane Dolecek's clinical research focuses on tropical diseases, in particular enteric fever and malaria. She has led enteric fever clinical trials in Vietnam and Nepal with the aim to systematically assess the current WHO recommendations as well as new treatment options.
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Professor Peter Horby is Senior Clinical Research Fellow. His research focusses on epidemic diseases such as Ebola and bird flu, and crosses the disciplines of basic science, medical science and public health. Influenza, SARS & Ebola
Research on emerging infectious diseases can only be conducted during outbreaks. Although virology has improved, a well calibrated and effective public health response is often lacking. Epidemiological and clinical research as well as mathematical modelling will give us answers during the epidemics and help us provide better diagnostics and better treatments. -
Dr Gareth Bond, Associate Member of the Ludwig Institute for Cancer Research, studies the influence of genetic variants on the origins, progression and treatment of human cancer. SNP - single nucleotide polymorphisms
There is great heterogeneity between individuals in their risk of developing cancer, disease progression and responses to therapy. Specific single nucleotide polymorphisms (SNPs) are associated with human cancers. They have the potential to help us identify individuals more at risk of developing cancer, and better target preventative or therapeutic strategies. -
Dr Jenny Taylor is the Programme Director for the Genomic Medicine Theme, Wellcome Trust Centre for Human Genetics. Her research bridges the gap between genetics research and the use of its discoveries in diagnosis or treatment of medical conditions. Clinical diagnoses can be broad descriptions, but today's test results can help better understand the condition as well as target treatment. Cancer is a good example in which personalised medicine can help decide which molecular targeted therapy is most appropriate.
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Identifying genes that increase the risk of bowel or other cancers allows us to offer preventative measures, such as removing tumours at an early stage. A better understanding of how and why cancers grow also helps develop improved treatments. Ian Tomlinson, Professor of Molecular and Population Genetics at the Wellcome Trust for Human Genetics, works on the identification of genes that predispose to colorectal and other cancers. His research focuses on the relative importance of selection and genomic instability.
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Cancer research now generates huge amounts of data, and sophisticated computational tools are needed to answer biological questions. Making sense of this variability at molecular level will help us better tailor treatments to individual cancer patients. Dr Benjamin Schuster-Böckler heads the computational group at the Ludwig Institute for Cancer Research. His work has demonstrated that epigenetic modifications influence the mutational landscape in cancer cells. He studies the effects of DNA-binding proteins on transcription factors, with the aim to understand the regulation (and mis-regulation) of the transcription of important oncogenes and tumour suppressors.
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Video microscopy aims to improve target discovery and drug development and to do so generates large volumes of data. Professor Jens Rittscher has a joint appointment between the Ludwig Institute for Cancer Research, the Target Discovery Institute and the Department of Engineering Science. His research aims to enhance our understanding of complex biological processes through the analysis of image data acquired at the microscopic scale.
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Dr Sebastian Nijman develops new approaches to study signalling networks in cancer cells and uncover specific weaknesses, particularly in breast and lung cancer. This can be used to develop more effective drugs and to better guide treatment decisions. In the context of cancer, genetic diversity means that we respond differently to various treatments. Pharmacogenomics sits at the intersection between genetics and drugs. Better understanding of the genetic landscape of cancer and the recent increase of targeted drugs allow us to better match patients with the best treatments, improving care.
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Microbiology in Thailand Acurately diagnosing infections is particularly challenging in tropical environments. Researchers at the Mahidol Oxford Tropical Medicine Research Unit (MORU) are working to develop effective and practical means of diagnosing and treating malaria and other neglected tropical diseases, such as dengue fever. The development of rapid tests for dengue, similar to pregnancy tests, allow rapid and acurate diagnostics in the field.
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Infectious diseases in South East Asia The Mahidol Oxford Tropical Medicine Research Unit (MORU) is a collaboration between the University of Oxford and Mahidol University, and was established with the Wellcome Trust in 1979. MORU aims to fight the infectious tropical diseases affecting rural communities in Asia and elsewhere in the developing world.
MORU's malaria research aims to directly improve the treatment of the disease globally. It's researchers focus on the treatment of severe malaria, the spread of antimalarial drug resistance, and the pathophysiology of falciparum and vivax malaria. These studies are used to formulate novel adjuvant therapies, and have been translated into recommendations for the use of artemisinin based combination therapies. - Laat meer zien