Transmission, pathogenicity and immune response to microbes are key concepts for understanding infectious disease processes. In this unit of study you will establish a conceptual foundation and, using an integrated approach, explore selected case studies of infection from a body system of origin perspective. You will explore the characteristics of viral, bacterial, fungal and protist pathogens and their virulence mechanisms for establishment and progression of disease. Comprehensive consideration of host immune response and characteristic pathological changes to tissue that arise will then be considered. Upon completion of this unit, you will be able to explain microbial pathogenic processes of infection including: mechanisms for colonisation, invasion and damage to host tissue; the ways in which your immune system recognises and destroys invading microbes; how T cell response is activated and antibodies function. You will learn about pathogenesis, symptoms, current challenges of treatment including antibiotic resistance, control and vaccination strategies. You will develop a holistic perspective of infectious diseases. You will work collaboratively to solve challenging problems in Biomedical Sciences. Practical classes will investigate normal flora, host defences and case studies of medically important microbes with linkage to disease outcome. You will also obtain experience and understanding of modern experimental techniques in microbiology and immunopathology.

Transmission, pathogenicity and immune response to microbes are key concepts for understanding infectious disease processes. In this unit you will establish a conceptual foundation and, using an integrated approach, explore selected infection case studies from a body system of origin perspective. You will explore characteristics of viral, bacterial, fungal and protist pathogens and their virulence mechanisms for establishment and progression of disease. Comprehensive consideration of host immune response and consequent characteristic pathological changes to tissue will be considered. Upon completion, you will be able to explain microbial pathogenic processes of infection including: mechanisms for colonisation, invasion and damage to host tissue; the ways your immune system recognises and destroys invading microbes; how T cell response is activated and antibodies function. You will learn about pathogenesis, symptoms, current challenges of treatment including antibiotic resistance, control and vaccination strategies. This advanced unit has the same overall structure as MIMI2002 but contains a unique science communication exercise in which you will actively participate in small group sessions and be assessed with a short essay. This advanced component explores how recent advances in microbiology, infection and immunity are communicated to the wider public and is based on recent publications with potential high impact for society.

What does it mean when someone tells you: "you have cancer"? Initially you're probably consumed with questions like: "how did this happen?" and "will this cancer kill me?". In this unit, we will explore all aspects of the "cancer problem" from the underlying biomedical and environmental causes, through to emerging approaches to cancer diagnosis and treatment. You will integrate medical science knowledge from a diverse range of disciplines and apply this to the prevention, diagnosis and treatment of cancer both at the individual and community level. Together we will explore the epidemiology, aetiology and pathophysiology of cancer. You will be able to define problems and formulate solutions related to the study, prevention and treatment of cancer with consideration throughout for the economic, social and psychological costs of a disease that affects billions. Face-to-face and online learning activities will allow you to work effectively in individual and collaborative contexts. You will acquire the skills to interpret and communicate observations and experimental findings related to the "cancer problem" to diverse audiences. Upon completion, you will have developed the foundations that will allow you to follow a career in cancer research, clinical and diagnostic cancer services and/or the corporate system that supports the health care system.

Biotechnological advances have given rise to an explosion of original and shared public data relevant to human health. These data, including the monitoring of expression levels for thousands of genes and proteins simultaneously, together with multiple databases on biological systems, now promise exciting, ground-breaking discoveries in complex diseases. Critical to these discoveries will be our ability to unravel and extract information from these data. In this unit, you will develop analytical skills required to work with data obtained in the medical and diagnostic sciences. You will explore clinical data using powerful, state of the art methods and tools. Using real data sets, you will be guided in the application of modern data science techniques to interrogate, analyse and represent the data, both graphically and numerically. By analysing your own real data, as well as that from large public resources you will learn and apply the methods needed to find information on the relationship between genes and disease. Leveraging expertise from multiple sources by working in team-based collaborative learning environments, you will develop knowledge and skills that will enable you to play an active role in finding meaningful solutions to difficult problems, creating an important impact on our lives.

Diagnostic sciences have evolved at a rapid pace and provide the cornerstone of our health care system. Effective diagnostic assays enable the identification of people who have, or are at risk of, a disease, and guide their treatment. Research into the pathophysiology of disease underpins the discovery of novel biomarkers and in turn, the development of revolutionary diagnostic assays that make use of state-of-the-art molecular and cellular methods. In this unit you will explore a diverse range of diagnostic tests and gain valuable practical experience in a number of core diagnostic methodologies, many of which are currently used in hospital laboratories. Together we will also cover the regulatory, social, and ethical aspects of the use of biomarkers and diagnostic tests and explore the pathways to their translation into clinical practice. By undertaking this unit, you will develop your understanding of diagnostic assays and biomarkers and acquire the skills needed to embark on a career in diagnostic sciences.

Clinical science is a multidisciplinary science that combines the principles of experimental science with translational medicine. As a clinical scientist, you will have the capacity to interpret test results, isolate causes of disease, and ultimately develop new treatments that will save lives. Clinical Science will provide you with the breadth and depth of knowledge and skills that will give you a broad foundation of knowledge and open up a range of career opportunities in clinical sciences, including medical research, pharmaceutical development and clinical diagnostics. You will learn the language of the clinical world as you develop expertise in literature searching, study design, data interrogation and interpretation, evidence-based decision-making, and current knowledge in medical research. You will explore how discoveries in the medical sciences are translated into clinical practice, and pose your own clinical questions for investigation. You will study important medical conditions from the areas of infectious and genetic diseases and immunity. The interdisciplinary capstone experience of your study in Clinical Science will be a short placement in a sector of the clinical sciences of your interest, such as a diagnostic lab, a research lab or a clinical trials centre. Consequently, at the end of this unit you will have experienced what it is like to work in interdisciplinary clinical teams, which is essential for both professional and research pathways in the future.