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Linking Early Heart Growth Stress And Adult Cardiopathology: A New Role For Autophagy
Funder
National Health and Medical Research Council
Funding Amount
$524,013.00
Summary
An enlarged heart at maturity is a major risk factor. The goal of this project is to understand how cardiac growth abnormality in the neonate contributes to adult growth pathology. We have recently discovered that a type of stress-triggered cell death (autophagy) is increased in rodent neonatal hearts which later become enlarged, and that this cell death is regulated by the hormone angiotensin II. We will study the mechanisms involved to identify intervention opportunities to normalize growth.
Enkephalin Metabolism In Cardiac Ischemia, Heart Failure And Cardiac Surgery
Funder
National Health and Medical Research Council
Funding Amount
$327,037.00
Summary
It has recently been discovered in animal studies that heart muscle can make its own opioid proteins. Previously, it was thought that only nerves made and released opioids. We have recently found that a class of opioids called enkephalins are made and then depleted from the heart during the stress of oxygen and nutrient deprivation. Enkephalins have been found to have potent metabolic effects on the heart. Previous work has shown that opioids can protect the heart against injury incurred during ....It has recently been discovered in animal studies that heart muscle can make its own opioid proteins. Previously, it was thought that only nerves made and released opioids. We have recently found that a class of opioids called enkephalins are made and then depleted from the heart during the stress of oxygen and nutrient deprivation. Enkephalins have been found to have potent metabolic effects on the heart. Previous work has shown that opioids can protect the heart against injury incurred during disease that restricts energy and oxygen supply to the blood vessels and heart. We wish to demonstrate this for the first time in human heart, and we will explore whether the production of enkephalins is altered by the stresses of cardiac surgery and heart failure. Understanding how the human heart attempts to protect itself in disease and how enkephalins work under these conditions, may prove valuable in the development of new drug therapy with synthetic drugs which mimic the action of enkephalins for heart protection during cardiac surgery, heart transplantation and ischemic heart disease. We will test whether specific enkephalins may be used to improve donor heart viability for transplantation by improving the duration and quality of preservation during storage. Understanding what happens to enkephalin production and metabolism in the failing hearts of patients may allow us to find new therapeutic targets in heart failure.Read moreRead less
A Temporal Profile Of Signaling Via Phosphorylation During Myocardial Ischemia - Reperfusion Injury
Funder
National Health and Medical Research Council
Funding Amount
$369,641.00
Summary
Cardiovascular disease (CVD) is the major cause of death in Australians and sequelae post-myocardial ischemia - reperfusion (I-R) are responsible for the greatest proportion of CVD-related mortality. Despite this burden, there is little known of the molecular events that mediate I-R. This project will utilize cutting-edge technology to elucidate the molecular signaling events that lead to I-R injury, as well as determine the basis for protection afforded by clinical pre- and post-conditioning.
Enhancing The Cardioprotective Effect Of Diadenosine Tetraphosphate: Designing Inhibitors Against Ap4A Hydrolase
Funder
National Health and Medical Research Council
Funding Amount
$442,500.00
Summary
Ischemia describes the condition where blood flow in the blood vessels of the heart is decreased or blocked, preventing delivery of oxygen and nutrients to the heart. Ischemic preconditioning is a phenomenon where short bursts of ischemia, followed by reperfusion, actually protect the heart from a subsequent longer period of ischemia. The biochemical signalling events involved in preconditioning are complex and incompletely defined, but most likely involve multiple pathways, although the mitocho ....Ischemia describes the condition where blood flow in the blood vessels of the heart is decreased or blocked, preventing delivery of oxygen and nutrients to the heart. Ischemic preconditioning is a phenomenon where short bursts of ischemia, followed by reperfusion, actually protect the heart from a subsequent longer period of ischemia. The biochemical signalling events involved in preconditioning are complex and incompletely defined, but most likely involve multiple pathways, although the mitochondrial ATP-dependent potassium channel may be in common with most pathways. Pretreatment with the compound diadenosine tetraphosphate (Ap4A) mimics ischemic preconditioning with noticeable reductions in tissue necrosis (cell death). This treatment has been shown in experimental work to protect the heart during periods of stress such as in heart surgery or recovery from an ischemic event. The biological site of action by Ap4A may be the mitochondria ATP-dependent potassium channel or an associated protein. Ap4A can be degraded by enzymes located inside and on the outside of heart cells, notably by two forms of Ap4A hydrolase. We will use antibody assays to understand the specific localization and amount of Ap4A hydrolase before and after ischemia and after ischemic preconditioning in human heart muscle and blood vessels. We propose to determine the structure of the enzyme and use novel computer methods to screen databases for potential inhibitors. These inhibitors of Ap4A hydrolase activity could aid the design of a potent inhibitor that would prevent Ap4A hydrolase from degrading Ap4A and therefore enhance the cardioprotective properties of Ap4A as well as minimizing side effects from the break down of Ap4A. We will also use these inhibitors and other known non-degradable Ap4A analogues in bioassays to test the relative significance of Ap4A hydrolase present in different cellular locations.Read moreRead less
How Does Oxygen Regulate Ca2+ Channel Function In Cardiac Myocytes?
Funder
National Health and Medical Research Council
Funding Amount
$475,517.00
Summary
Oxygen occupies a key role in cellular metabolism and function. Oxygen delivery to cells is critical and lack of oxygen such as occurs during a heart attack can be lethal. Death occurs commonly by induction of arrhythmia or a disturbance in the heart beat. The abnormal heart beat cannot enable the heart to pump blood efficiently and vital organs are then deprived.Exactly how arrhythmia is induced is not understood. The normal heart beat occurs as a result of propogation of electrical signals thr ....Oxygen occupies a key role in cellular metabolism and function. Oxygen delivery to cells is critical and lack of oxygen such as occurs during a heart attack can be lethal. Death occurs commonly by induction of arrhythmia or a disturbance in the heart beat. The abnormal heart beat cannot enable the heart to pump blood efficiently and vital organs are then deprived.Exactly how arrhythmia is induced is not understood. The normal heart beat occurs as a result of propogation of electrical signals through heart muscle cells. The electrical activity is generated and sustained by movement of salts or ions through membrane proteins known as ion channels. One of these channels, the L-type calcium channel plays a vital role in cardiac excitation and contraction. A reduction in oxygen alters the function of the L-type calcium channel. However, the exact mechanism for this is uncertain. An oxygen sensing mechanism in the cell is responsible for the regulation of channel function during hypoxia. The exact identity of the oxygen sensor is currently the centre of debate. Four hypotheses have been proposed. This proposal aims to examine in detail the four hypotheses of oxygen sensing to definitively determine the identity of the oxygen sensor. This information should increase our understanding of how calcium channels function during stressful conditions such as during a heart attack.Read moreRead less
Identification Of A Plasma Factor Of Remote Ischemic Preconditioning And Its Effect On The Proteome After Heart Surgery
Funder
National Health and Medical Research Council
Funding Amount
$385,197.00
Summary
Heart surgery with the heart placed into arrest causes inflammation and tissue damage due to interrupted circulation. We know that prior brief interruption and restoration of blood supply called remote ischemic preconditioning (IPC) can protect heart and lungs against damage. Our previous studies indicate that IPC involves a circulating factor that protects the tissue by optimizing energy preservation. This knowledge can be applied to organ transplants, protection from stroke and heart attack.
The Role Of Aquaporins In Cardiac Ischaemia And Reperfusion
Funder
National Health and Medical Research Council
Funding Amount
$412,670.00
Summary
We are studying the important clinical problem of why the heart doesn't work very well after it has been deprived of blood. This may occur during a heart attack due to coronary artery disease and during cardiac surgery when the heart is stopped. The problem affects children as well as adults undergoing surgery. The reason the heart doesn't work well is related to energy supply and tissue damage caused during the shortage of blood supply and the period soon after flow is restored. Until the heart ....We are studying the important clinical problem of why the heart doesn't work very well after it has been deprived of blood. This may occur during a heart attack due to coronary artery disease and during cardiac surgery when the heart is stopped. The problem affects children as well as adults undergoing surgery. The reason the heart doesn't work well is related to energy supply and tissue damage caused during the shortage of blood supply and the period soon after flow is restored. Until the heart recovers, inadequate pump function may cause low blood flow problems downstream in vital organs such as the brain and kidneys. Under the microscope, a common feature of affected hearts is swelling of the cells and of the energy producing parts called mitochondria. We have identified, for the first time, unique proteins that allow water to move into and around cells of the heart. These proteins are called 'aquaporins' and early results suggest they are involved in how mitochondria deal with a shortage of blood supply. Interestingly, aquaporins are also affected in diseases that affect muscle strength, and we are using what is known in these diseases to further study the role of aquaporins in the heart. Our experiments to will test heart function from the level of the cell, all the way up to the whole heart. To improve the power of our experiments, we are working with mice that lack the special water transport proteins, as a prelude to developing drug therapy for this important problem. By manipulating aquaporin levels or function, we plan to improve heart preservation during periods of no blood flow, and after surgery. This would importantly reduce the risks associated with heart attack and cardiac surgery by avoiding complications associated with poor pump function.Read moreRead less
STudy Of Risk Assessment To Reduce Complications In Patients Following Noncardiac SurgerY (STRATIFY)
Funder
National Health and Medical Research Council
Funding Amount
$436,000.00
Summary
Cardiac problems account for many complications in patients undergoing major non-cardiac surgery, and even apparently minor cardiac damage is a marker of high risk for subsequent adverse events. Unfortunately, while money and effort is expended on identifying patients at risk, the appropriate response to this risk is quite unclear. The performance of bypass surgery or balloon angioplasty in order to treat the underlying coronary disease of at-risk patients is used in other situations, and reduce ....Cardiac problems account for many complications in patients undergoing major non-cardiac surgery, and even apparently minor cardiac damage is a marker of high risk for subsequent adverse events. Unfortunately, while money and effort is expended on identifying patients at risk, the appropriate response to this risk is quite unclear. The performance of bypass surgery or balloon angioplasty in order to treat the underlying coronary disease of at-risk patients is used in other situations, and reduces longterm risk. However, in many patients undergoing major noncardiac surgery, this approach may be inappropriately aggressive, as these patients are often elderly, have other diseases that make heart operations more difficult and risky than usual, and in any case may have a reduced life expectancy from the disease necessitating the operation. As the most critical issue is to ensure that patients undergo their surgery uneventfully, an alternative is the use of intensive medical therapy to protect the heart. This multicentre study, based at Brisbane hospitals that perform large numbers of major operations, will follow up patients for complications, and outcome (including quality of life) will be assessed six months after the operation. We will address two important questions about the efficacy and cost of risk reduction strategies. First, in patients at higher levels of risk and with a positive stress test, could a combination of medical therapy designed to protect the heart be as effective as current approaches, which include the performance of bypass surgery or coronary balloon angioplasty? Second, in patients identified as being at some risk - but low risk - are drugs sufficiently effective to avoid the need for further testing to quantify risk? As the population continues to age, the numbers of at risk patients undergoing major surgery will increase, and answers to these questions will provide important information to guide their management.Read moreRead less
The properties of Vegf-B suggest that it may play a role in new blood vessel formation (angiogenesis) especially during the development of the heart. Mice with the Vegf-b gene deleted are viable and fertile but display cardiac dysfunction as the animals age and in experimental conditions of ischemia. Comparison of total gene expression in the hearts of mice lacking Vegf-B with those of normal mice will identify genes involved in blood vessel formation during cardiac development and maintenance. ....The properties of Vegf-B suggest that it may play a role in new blood vessel formation (angiogenesis) especially during the development of the heart. Mice with the Vegf-b gene deleted are viable and fertile but display cardiac dysfunction as the animals age and in experimental conditions of ischemia. Comparison of total gene expression in the hearts of mice lacking Vegf-B with those of normal mice will identify genes involved in blood vessel formation during cardiac development and maintenance. The genes identified will be targets for designing potential new drugs and therapies for cardiovascular disease.Read moreRead less
Towards A New Normokalemic Arrest Paradigm For Orthotopic Heart Transplantation
Funder
National Health and Medical Research Council
Funding Amount
$489,634.00
Summary
Innovations from Nature to Heart Transplantation:a Real Heart Stopper Heart preservation is limited to 4-6 hours of cold-ischaemic storage (0 to 4 C). The risk of post-transplant death doubles if the donor heart is stored from 1 to 5 hours, and triples with 7 hrs storage times. We have developed a new preservation solution borrowing from natural hibernators that will permit organs to be safely stored for up to 15 hours, and offering new opportunities to organ donors and recipients worldwide.