Pathogenesis Of Persistent Human Virus Infections Of Global Significance
Funder
National Health and Medical Research Council
Funding Amount
$6,571,328.00
Summary
The study will investigate why humans cannot eradicate particular viruses (HIV-AIDS, cytomegalovirus and herpes simplex virus), the long term effects of these viruses and ways to improve control. Current treatments can only partly suppress the levels of these viruses, because they persist in certain parts of the body called reservoirs, only to resurge later causing disease. Thus, the overall aim of the research program is to discover the mechanisms by which these viruses are able to successfully ....The study will investigate why humans cannot eradicate particular viruses (HIV-AIDS, cytomegalovirus and herpes simplex virus), the long term effects of these viruses and ways to improve control. Current treatments can only partly suppress the levels of these viruses, because they persist in certain parts of the body called reservoirs, only to resurge later causing disease. Thus, the overall aim of the research program is to discover the mechanisms by which these viruses are able to successfully persist within reservoirs in the human body. The research program brings together a group of 6 leading scientists and clinicians located at 3 sites in 2 Australian cities. The team is comprised of experts in the study of HIV-AIDS, cytomegalovirus and herpes simplex virus who will combine their knowledge and expertise to speed up the process of research on these viruses that are of major health importance. Studies will also utilise a number of cutting edge technologies that now make it possible to much more rapidly and precisely determine how viruses cause disease. Advances in our understanding of how viruses persist may form the basis for treatments aimed at controlling persistent infections and the serious diseases caused by these viruses.Read moreRead less
To study the genetic alterations that give rise to cancer. In particular, exploring how too little death of cells can lead to a tumour. If too few cells in a tissue die, a tumour may develop there. The team is exploring how the cell death process is normally controlled. They plan to characterise the molecules inside cells that determine whether a cell lives or dies and hope that better understanding of those molecules will help to explain how tumours arise. It could also lead to new drugs that c ....To study the genetic alterations that give rise to cancer. In particular, exploring how too little death of cells can lead to a tumour. If too few cells in a tissue die, a tumour may develop there. The team is exploring how the cell death process is normally controlled. They plan to characterise the molecules inside cells that determine whether a cell lives or dies and hope that better understanding of those molecules will help to explain how tumours arise. It could also lead to new drugs that can kill tumour cells more effectively by directly triggering the normal death switch of the cell.Read moreRead less
IMPROVING STROKE OUTCOMES: NEW TARGETS AND THERAPIES
Funder
National Health and Medical Research Council
Funding Amount
$7,212,064.00
Summary
Previously we established a unique collaboration of researchers from the basic and clinical sciences.. The main aim of this ' vertically integrated ' model was to develop new therapies to improve stroke outcomes. We developed a system to identify ' off-the-shelf ' compounds which protect the brain after stroke onset. This involves data assimilation (meta-analysis) in a unique way, an approach which has attracted attention internationally. We are also completing an important clinical trial using ....Previously we established a unique collaboration of researchers from the basic and clinical sciences.. The main aim of this ' vertically integrated ' model was to develop new therapies to improve stroke outcomes. We developed a system to identify ' off-the-shelf ' compounds which protect the brain after stroke onset. This involves data assimilation (meta-analysis) in a unique way, an approach which has attracted attention internationally. We are also completing an important clinical trial using the clot dissolving agent tPA to extend the time during which the drug may be effective beyond the three-hours currently used. In the next phase of our program we plan to expand the basic science component to identify parts of brain cells (axons and dendrites) which may yield important information about new drugs to protect the brain. We will use our novel summary data technique to test drugs in animal models more appropriate to the human stroke paradigm than have been used in the past In clinical studies we will follow our theme of identifying new targets for therapy using sophisticated PET and MRI imaging techniques, both in patients who are at great risk of stroke recurrence after a minor warning stroke and those with stroke caused by bleeding within the brain. These studies will provide information about predictors of recurrent and worsening stroke which may be modified by new therapies. The final stage in identifying new therapies is the Phase III clinical trial. We will complete one of these in which the most appropriate drug preventing further strokes in a major new stroke subtype will be identified. Toward the end of the program, we will commence phase 3 studies of drugs we have selected as being most likely to protect the brain based on our animal experiments. The main benefit of this unique collaborative research model is to efficiently identify new therapies to reduce the burden of stroke, currently the second most common cause of death globally.Read moreRead less