Glaucoma is the second leading cause of blindness in the world affecting approximately 70 million people. Glaucoma can occur at any age but the commonest type occurs in middle to old age. The disease has a genetic basis and can be inherited. As a result we have been studying the genetics of the disease in two large families from Tasmania. We hope to identify the genes involved in disease causation using a number of genetic techniques. Once mutations in a disease gene have been identified from af ....Glaucoma is the second leading cause of blindness in the world affecting approximately 70 million people. Glaucoma can occur at any age but the commonest type occurs in middle to old age. The disease has a genetic basis and can be inherited. As a result we have been studying the genetics of the disease in two large families from Tasmania. We hope to identify the genes involved in disease causation using a number of genetic techniques. Once mutations in a disease gene have been identified from affected individuals we will then be in a position to look for mutations in other family members and identify those individuals at risk of developing disease. Improvements in our understanding of how these genes are involved in disease causation will allow us to offer diagnostic testing to the wider community and develop better therapeutic interventions for treatment.Read moreRead less
Dissecting The Pseudoexfoliation Syndrome With Complementary Genetic, Proteomic And Biophysical Strategies
Funder
National Health and Medical Research Council
Funding Amount
$490,352.00
Summary
Pseudoexfoliation syndrome (PEX) is an eye condition in which flaky material deposits in the eye, greatly increasing the risk of cataract and glaucoma which can lead to blindness. PEX is also associated with heart disease, strokes and aneurysms. Cataract surgery in PEX patients has a higher rate of complications. In this project we will determine the nature of PEX material and why it forms. This knowlege will facilitate better diagnosis and treatment of PEX preventing associated blindness.
Circulating Low -molecular Weight AGEs In The Development And Progression Of Diabetic Complications
Funder
National Health and Medical Research Council
Funding Amount
$297,523.00
Summary
High levels of sugars seen in patients with diabetes leads to damage of many organs including the heart, the eyes and the kidneys. These high sugars cause damage through a number of mechanisms, one being the formation of advanced glycation end products or AGEs, formed by the irreversible reaction between proteins and glucose. This reaction leads to a change in the shape and function of AGE-modified molecules that progressively contributes to organ damage. AGEs also bind and activate specific rec ....High levels of sugars seen in patients with diabetes leads to damage of many organs including the heart, the eyes and the kidneys. These high sugars cause damage through a number of mechanisms, one being the formation of advanced glycation end products or AGEs, formed by the irreversible reaction between proteins and glucose. This reaction leads to a change in the shape and function of AGE-modified molecules that progressively contributes to organ damage. AGEs also bind and activate specific receptors that promote the damage and scarring of tissue. Where the glucose concentration is high, AGEs accumulate much more quickly. This is one reason why patients with good sugar control do better than those who are unable to control their blood sugars. The importance of this AGE pathway is illustrated by the fact that blocking the formation of AGEs is able to prevent kidney damage in animals with diabetes. In addition, exposure to AGEs can cause diabetes-like changes in the absence of high sugars. Our laboratory is a world leader in the study of the advanced glycation and methods blocking this process. The research proposed will investigate circulating levels of AGEs in experimental animals and patients with diabetes, and correlate them with the development and progression of complications of diabetesRead moreRead less