Understanding Local And Regional Determinants Of EDHF And NO Dysfunction In Resistance Arteries In Diabetes
Funder
National Health and Medical Research Council
Funding Amount
$771,295.00
Summary
Diabetes is a serious and increasing health burden worldwide. Most of the sickness and death associated is due to complications arising in the blood vessels. The inner lining of blood vessels in small arteries uses several different mechanisms to ensure proper blood flow, and in diabetes these are impaired. This study will reveal the cellular mechanisms involved and identify pathways for therapeutic intervention to alleviate the debilitating effects of small artery disease.
TARGETING ROS-INDUCED DAMAGE RESCUES THE DIABETIC HEART
Funder
National Health and Medical Research Council
Funding Amount
$487,669.00
Summary
Over 1 million Australians have diabetes. Many of these patients die from cardiovascular disease. We have identified free radicals as a major cause of decreased pumping function and impaired recovery from each heartbeat in the diabetic heart. Stronger antioxidant approaches and-or activation of protective protein pathways is a more effective treatment for reversing impaired function in the diabetic heart, preventing or delaying heart failure in patients with diabetes.
Non-neuronal ATP: Regulation Of Release And Action In The Bladder
Funder
National Health and Medical Research Council
Funding Amount
$451,553.00
Summary
Incontinence disorders are costly and debilitating. How the bladder signals the normal sensation of fullness as well as the urgent need to void urine (urgency) is still not fully understood. The signaling molecule ATP is released during bladder stretch. Using animal and human bladder, we will study how the bladder lining is involved in this signaling process, by measuring how bladder chemicals interact with stretch to modulate ATP release, and how ATP can influence nerve impulses to the brain.
Aberrant Oligosaccharide Processing Of Nox2-oxidase As A Mechanism Of Vascular Oxidative Stress In Atherosclerosis
Funder
National Health and Medical Research Council
Funding Amount
$552,565.00
Summary
Excessive production of free radicals by an enzyme called Nox2 may be a cause of artery disease leading to heart attacks and strokes. This study will identify whether the addition of sugarchains to Nox2 causes it to be expressed at the surface of cells allowing the free radicals it produces to exit the cell and cause damage to the blood vessel wall. Charaterising this new pathway of excessive free radical production may pave the way for new diagnostics and treatments for artery disease.
Targeting Arginase In Peripheral Arterial Occlusive Disease
Funder
National Health and Medical Research Council
Funding Amount
$243,945.00
Summary
Peripheral artery occlusive disease causes narrowing of large peripheral blood vessels which can result in severe pain, gangrene and stroke. Its prevalence is steadily increasing in western countries. This proposal aims to characterize the role of an enzyme (arginase) in PAOD and determine whether it may be a new drug target for treatment of this disease.
NOVEL CGMP-BASED THERAPIES PREVENT LEFT VENTRICULAR REMODELLING
Funder
National Health and Medical Research Council
Funding Amount
$533,433.00
Summary
Over 300,000 Australians are affected by heart failure. Current drugs for cardiac remodelling (the decline in heart pumping function and changed structure that precede heart failure) slow but not reverse disease progression. We have identified a new, nitrovasodilator-based therapy superior to those currently available. We propose it represents a more effective treatment for reversing abnormalities in both structure and function in the remodelled heart, preventing or delaying heart failure.
Opioid Actions On Sensory Neuron Excitability In Vitro
Funder
National Health and Medical Research Council
Funding Amount
$241,018.00
Summary
Morphine and related drugs are very widely used for pain relief, although the way they affect the pain-sensitive cells in the body is not well understood. Use of morphine for extended periods of time often makes morphine less effective for pain relief, which makes it necessary to increase the dose of morphine given. This leads to an increase in the unwanted side effects of morphine, and can eventually lead to morphine becoming ineffective in controlling pain. This study is designed to examine ho ....Morphine and related drugs are very widely used for pain relief, although the way they affect the pain-sensitive cells in the body is not well understood. Use of morphine for extended periods of time often makes morphine less effective for pain relief, which makes it necessary to increase the dose of morphine given. This leads to an increase in the unwanted side effects of morphine, and can eventually lead to morphine becoming ineffective in controlling pain. This study is designed to examine how morphine affects pain-sensitive cells, and to determine how continued use of morphine changes the way pain-sensitive cells respond to morphine. We hope that by understanding how morphine works on pain-sensitive cells, we can understand why it does not work so well after continued use. This information should enable us to design better forms of pain relief than we have now.Read moreRead less
A group of nerves, called sensory nerves, supply most body organs including the uterus, and are well known to transmit information to the brain. It is now known that these nerves are also capable of releasing the chemicals (neuropeptides) from their endings within these body organs to affect their function. In the uterus these chemicals cause the uterus to contract. We have shown that neuropeptides known as tachykinins are effective in lower concentrations when applied to small specimens of uter ....A group of nerves, called sensory nerves, supply most body organs including the uterus, and are well known to transmit information to the brain. It is now known that these nerves are also capable of releasing the chemicals (neuropeptides) from their endings within these body organs to affect their function. In the uterus these chemicals cause the uterus to contract. We have shown that neuropeptides known as tachykinins are effective in lower concentrations when applied to small specimens of uterine tissue taken from non-pregnant women at hysterectomy than when applied to similar uterine specimens taken from pregnant women at caesarean section. The aim of this project is twofold. Firstly, we want to know why the tachykinins are more potent in uterine tissue from non-pregnant women. Possible explanations that we will examine are that tissues from non-pregnant women contain more sites of action at which the peptides can act, or alternatively, that there is decreased breakdown of these tachykinins in uterine tissue from non-pregnant women. This could occur if a substance known to break down the tachykinins in the uterus shows greater activity during pregancy than when a woman is not pregnant. Secondly, we wish to find out if other chemicals (substances that can produce inflammatory responses, and in particular a group of chemicals known as prostaglandins), that are known to be present in greater amounts in the tissues of women during disease states such as dysmenorrhoea, can cause the release of the neuropeptides that we are studying. If they do cause such a release of tachykinins, this could be an important factor contributing to the disease state. Our hypothesis is that tachykinins and the substances which can break them down may play an important role in regulating uterine contractility in non-pregnant and to a lesser degree in pregnant women.Read moreRead less
Opioid Actions On Identified Sensory Neurons In Vitro
Funder
National Health and Medical Research Council
Funding Amount
$371,850.00
Summary
Opioids (in particular morphine) are the gold standard drugs for the relief of most types of moderate to severe pain. Despite the effectiveness of opioids and other analgesics, many people still suffer unrelieved pain. There are 2 main reasons for this. Firstly, there are some types of pain that are refractory to currently used analgesics from the outset, and secondly, chronic conditions may require escalating doses of analgesics for adequate pain relief, and these does may increase until side e ....Opioids (in particular morphine) are the gold standard drugs for the relief of most types of moderate to severe pain. Despite the effectiveness of opioids and other analgesics, many people still suffer unrelieved pain. There are 2 main reasons for this. Firstly, there are some types of pain that are refractory to currently used analgesics from the outset, and secondly, chronic conditions may require escalating doses of analgesics for adequate pain relief, and these does may increase until side effects become intolerable. My studies will provide insight into the reasons that underlie the differential effectiveness of opioids in acute pain conditions, as well as the reasons why opioids lose their effectiveness over time. These studies will also identify molecular targets that may be important for developing analgesics for specific pain conditions. Because the head is the source of many familiar painful conditions, including tooth pain, migraine and temporomandibular disorders, I will be using neurons from the trigeminal ganglion, the part of the nervous system which supplies the sensory innervation to the structures involved in these pain states. By using mice as experimental animals, I will be able to investigate the contribution of neurons that innervate specific parts of the head to these pain states, and study how chronic morphine treatment affects the behavior of these cells. I hope that these studies will provide a basis for designing strategies that improve the effectiveness of existing analgesics, and perhaps lead to the identification of new, better pain relievers.Read moreRead less
The Role Of Connexins In Blood Pressure Regulation: Use Of A Conditional Gene Expression System
Funder
National Health and Medical Research Council
Funding Amount
$583,767.00
Summary
Cell coupling through gap junctions is said to play an important role in regulating blood flow and blood pressure. However data obtained from mice, in which specific gap junctions are deleted, may be compromised by compensatory changes in other junctions. We have validated a new method for rapidly and reversibly altering gap junctions in adult mice with oral sugar. This technique will enable us to directly determine whether interference with cell coupling affects blood flow and blood pressure.