BioPolymer Fibres For Remodelling Mdx And Damaged Muscle
Funder
National Health and Medical Research Council
Funding Amount
$527,286.00
Summary
This project aims to generate new, smart polymers for use in re-building muscle that has degenerated due to disease and-or trauma damage. The merger of smart polymers with biologically based solutions and cells has great potential to improve outcomes of treatments of damaged muscle in diseases such as Muscular Dystrophy.
An Integrated Approach To Identify The Molecular Mechanisms Contributing To The Pathogenesis Of Insulin Resistance: Targeting The Liver And Skeletal Muscle
Funder
National Health and Medical Research Council
Funding Amount
$415,218.00
Summary
The inability of muscle and liver to utilise sugar from the blood is a major problem that contributes to the development of obesity and diabetes. How these problems occur is unknown. The goal of my research is to identify what causes the muscle and liver problem, and whether fixing these problems will reduce obesity and diabetes. Since the number of people with obesity and diabetes is predicted to double over the next decade, we need to understand the cause of these diseases.
Exercise As Medicine For Heart Failure: A Novel Intervention To Improve Outcomes
Funder
National Health and Medical Research Council
Funding Amount
$665,585.00
Summary
Heart failure (HF) is a common, debilitating and expensive disease; prognosis remains poorer than for the most cancers. 30,000 Australians are diagnosed every year and 300,000 live with the HF, at an annual cost of ~$1Billion. Exercise training is effective therapy in HF, because it reverses many of the problems that contribute to the reduced lifespan and impaired quality of life of patients with HF. We will test an exciting new type of exercise that promising greater benefit, at lower risk.
Understanding The Metabolic Consequences Of Impaired AMPKa2 And NNOS� In Skeletal Muscle: Implications For The Metabolic Syndrome
Funder
National Health and Medical Research Council
Funding Amount
$575,527.00
Summary
The inability of muscle to utilise sugar from the blood is a major problem that contributes to obesity and Type 2 diabetes. Since the number of people with these diseases will at least double by 2030, we need to find out what causes this problem. We will examine whether two muscle proteins that are impaired in obesity and Type 2 diabetes are also responsible for impaired sugar utilisation. We think that increasing these muscle proteins will fix the _sugar problem�, and remedy these diseases.
Molecular Regulation Of Metabolism And Body Composition By Ski Via Crosstalk With Nuclear Hormone Receptor Signalling.
Funder
National Health and Medical Research Council
Funding Amount
$558,441.00
Summary
Obesity is a common and burdensome health problem in the community which leads to diabetes and heart disease. A number of factors, including hormones play important roles in determing risk of obesity. This study proposes to investigate whether the Ski gene which is a regulatory factor for many hormones affects metabolism in transgenic mouse models of altered Ski function. The proposed studies may identify Ski as a target for therapy for obesity and improvement in sketal muscle metabolism.
Cytokine Signalling And Insulin Resistance In Obesity.
Funder
National Health and Medical Research Council
Funding Amount
$512,065.00
Summary
Western communities are experiencing an epidemic of obesity that is contributing to diabetes, heart disease, and premature death. This project is investigating why being overweight and obese causes diabetes. Improved understanding about how hormones regulates the body's storage and breakdown of fat and responsiveness to insulin will enable the development of new medicines for the treatment of obesity and the prevention of diabetes.
Rapid functional analysis of genes involved in skeletal development. Abnormalities of the skeleton are of enormous clinical significance in terms of both number of individuals affected and the cost of treatment. Data derived from this project will underpin targeted research on the mechanisms of inherited and common diseases of cartilage and bone, yielding novel diagnostic and therapeutic targets. In addition, the improved knowledge of cartilage and bone cell development will inform new approache ....Rapid functional analysis of genes involved in skeletal development. Abnormalities of the skeleton are of enormous clinical significance in terms of both number of individuals affected and the cost of treatment. Data derived from this project will underpin targeted research on the mechanisms of inherited and common diseases of cartilage and bone, yielding novel diagnostic and therapeutic targets. In addition, the improved knowledge of cartilage and bone cell development will inform new approaches for developing stem cell therapies and the production of novel biomaterials for the repair of bones and joints. The outcomes of this study will therefore benefit the full spectrum of society from infants to the aged.Read moreRead less
The role of heparan sulfate proteoglycans in the control of osteoblast phenotype. Very little is known about how bone cells progress from a naive precursor state, through differentiation and then maturation into adult cells. We wish to purify sugars from the bone cell membrane, extracellular matrix and culture medium, and examine the cellular response following the addition of these various sugar fractions to osteoblast cell cultures in combination with known growth factors. If we can control ....The role of heparan sulfate proteoglycans in the control of osteoblast phenotype. Very little is known about how bone cells progress from a naive precursor state, through differentiation and then maturation into adult cells. We wish to purify sugars from the bone cell membrane, extracellular matrix and culture medium, and examine the cellular response following the addition of these various sugar fractions to osteoblast cell cultures in combination with known growth factors. If we can control the progression of osteoblastic cells through the phases of recruitment, proliferation, differentiation and maturation by the addition of specific sugar fractions then we can potentially control bone formation.Read moreRead less
Using mouse genetics to understand skin development and cell biology. During embryonic development the skin forms a protective barrier which permits life outside the womb and provides a window into the biology of cells. This project aims to use the skin to identify and characterise genes necessary for embryonic development and maintenance, the development of diseases and to explore their broader roles in other organs.