Targeting brain lipid homeostasis to treat Alzheimer's disease. Dementia affects approximately 250,000 people in Australia at an estimated cost (in 2002) of $6.6 billion per annum. The major cause of dementia (accounting for approximately 70% of all cases) is Alzheimer's disease (AD); a progressive neurodegenerative illness for which there is no curative or disease-stalling treatment. Due to increases in life expectancy, the incidence of AD is predicted to triple by 2050 unless disease-modifying ....Targeting brain lipid homeostasis to treat Alzheimer's disease. Dementia affects approximately 250,000 people in Australia at an estimated cost (in 2002) of $6.6 billion per annum. The major cause of dementia (accounting for approximately 70% of all cases) is Alzheimer's disease (AD); a progressive neurodegenerative illness for which there is no curative or disease-stalling treatment. Due to increases in life expectancy, the incidence of AD is predicted to triple by 2050 unless disease-modifying treatments are developed. This research program will provide novel realistic pharmaceutical approaches to treat AD. Even if the onset of AD could be delayed by a few years the personal and financial benefits would be enormous. The potential for this research to generate commercially viable Australian intellectual property is also significant.Read moreRead less
Biological probes for understanding mammalian cellular transport mechanisms. Cellular components are moved around within cells by molecular motors. This fundamental transport mechanism depends on a network of tracks. Blocks in this cellular transport can result in a number of mammalian diseases, particularly within nerve cells. This project will increase our understanding of the mechanisms of cellular transport and, in particular, how molecular motors engage their cargo. This is essential ground ....Biological probes for understanding mammalian cellular transport mechanisms. Cellular components are moved around within cells by molecular motors. This fundamental transport mechanism depends on a network of tracks. Blocks in this cellular transport can result in a number of mammalian diseases, particularly within nerve cells. This project will increase our understanding of the mechanisms of cellular transport and, in particular, how molecular motors engage their cargo. This is essential groundwork for the development of drugs that target this transport mechanism.Read moreRead less