Interactions Between H5N1 And The Respiratory Epithelium
Funder
National Health and Medical Research Council
Funding Amount
$623,065.00
Summary
This project examines the hypothesis that the severity of H5N1 infection is due to activation of signalling pathways in the lung not activated by human influenza and leads to fluid accumulation in the lungs death of respiratory cells. This study will improve our understanding of influenza infection and identify targets for treatment of H5N1.
Determining The Cellular Mechanisms Involved In The Airway Response To Topical Citrate
Funder
National Health and Medical Research Council
Funding Amount
$444,491.00
Summary
The air passages of the lungs are lined by mucous membranes. These membranes are covered by a thin layer of fluid to protect the airways from drying. This fluid allows the cilia, the hair like projections on top of the airway cells to beat more effectively to remove mucous and inhaled particles from the lungs. The volume and composition of this fluid is determined by the salt and water movement across the mucous membranes of the airways. These processes are abnormal in cystic fibrosis (CF), the ....The air passages of the lungs are lined by mucous membranes. These membranes are covered by a thin layer of fluid to protect the airways from drying. This fluid allows the cilia, the hair like projections on top of the airway cells to beat more effectively to remove mucous and inhaled particles from the lungs. The volume and composition of this fluid is determined by the salt and water movement across the mucous membranes of the airways. These processes are abnormal in cystic fibrosis (CF), the most common lethal inherited disease affecting Australians. In CF, an abnormal gene disrupts one of the major mechanisms for salt and water movement in the air passages. This abnormal salt transport causes drying of the airway surface which impairs the working of the cilia. This leads to retention of mucous in the airways with repeated bacterial infections damaging the lungs. Over the last 10 years, we have developed a series of simple tests to measure the abnormalities in the CF airway of human subjects. We have isolated an exciting new clinical application for sodium citrate, a substance used in blood transfusions. Citrate appears to alter both the salt transport abnormalities found in CF. This research proposal seeks to better understand the dual effects of citrate and to test similar compounds that may have stronger effects. The ultimate aim of our research is to have sufficient knowledge to work out the best way to develop a new treatment for CF.Read moreRead less
Physiological Function Of Nedd4-2 In Regulating The Epithelial Sodium Channel And Cystic Fibrosis Transmembrane Conductance Regulator
Funder
National Health and Medical Research Council
Funding Amount
$949,572.00
Summary
Optimal transport of sodium and chloride ions is essential for the maintenance of electrolyte balance, blood volume, blood pressure and lung function. We are studying the control of a key sodium channel (the epithelial sodium channel) and a key chloride channel (cystic fibrosis transmembrane conductance regulator) by an enzyme called Nedd4-2. This project will enable us to understand how Nedd4-2 regulates these two ion channels and to study the pathological consequences of the loss of Nedd4-2.
Pain is a debilitating condition that affects the life of one in five Australians and has significant socioeconomic impact. Currently available pain killers often do not work, or have intolerable side effects including sedation and addiction. We have discovered a novel compound that avoids these side effects and provides effective analgesia as well as opioid-sparing effects in a number of relevant animal models. The aim of this project is to progress the compound towards clinical development.
Novel Analgesic Approaches: Harnessing Functional Interactions Between Sodium Channels And Opioids
Funder
National Health and Medical Research Council
Funding Amount
$329,076.00
Summary
Chronic pain is a debilitating condition that affects the life of one five Australians and has significant socioeconomic impact. Currently available pain killers often do not work, or have intolerable side effects. We have discovered that combination treatment with opioids and a novel venom-derived compound discovered by us provides effective pain relief. The aim of this project is to understand the mechanisms underlying this synergistic effect to develop new treatment approaches for pain.
Pain is one of the most frequent and costly health problems faced by Australia. Currently available painkillers often do not work, or have intolerable side effects. We thus need better approaches to treat pain. This project will define the role of the novel pain target Nav1.6 in clinically relevant pain states, including burns pain and chemotherapy-induced pain, with the aim to develop novel treatment approaches and painkillers for these difficult-to-treat conditions.