Correction And Measurement Of The Basic Defects In Cystic Fibrosis
Funder
National Health and Medical Research Council
Funding Amount
$929,335.00
Summary
Airway disease caused by the genetic disease cystic fibrosis (CF) cannot currently be prevented or cured. Current treatments (other than lung transplant) can only slow the inevitable decline in lung health. Early death from lung failure occurs for many with CF. We have developed a gene transfer technique to introduce the corrective gene (CFTR) into CF-diseased airway cells. We have used airways in mice to test and develop this method, to determine if long-lasting genetic correction of the airway ....Airway disease caused by the genetic disease cystic fibrosis (CF) cannot currently be prevented or cured. Current treatments (other than lung transplant) can only slow the inevitable decline in lung health. Early death from lung failure occurs for many with CF. We have developed a gene transfer technique to introduce the corrective gene (CFTR) into CF-diseased airway cells. We have used airways in mice to test and develop this method, to determine if long-lasting genetic correction of the airway cells can be achieved. The gene is introduced into the airway as a single small dose of special delivery-particles (vector) that have been built using highly-modified components of the HIV-1 virus. If ultimately successful in humans with CF, the disease should be halted, or even cured. Our recent work indicates that we have been able to insert the gene into airway progenitor cells, confirming our hypothesis that long-lasting gene expression can be achieved this way. To know if the method would be safe and effective in humans, we must now test the technique in sheep (as a human-size lung) and in marmosets (as a human-like lung) before clinical trials could be considered. We will monitor animals for up to 3 years to be sure the effect of the gene is truly long-lasting, and we will document how the gene-transfer vector disappears from the body. We have also discovered a new way to examine the detail of the very thin fluid layer on the airway surface. This fluid is too shallow in CF airway (allowing bacteria to stick and start disease) and so a successful gene therapy should return the fluid to it's proper depth. This method uses X-ray light from a synchrotron, and we expect it will work without the need to sacrifice animals to measure the airway surface. If successful it also has potential to be used much like a normal X-ray in humans with CF, to test if a gene therapy has worked.Read moreRead less
Synchrotron X-ray Assessment Of Airway Surface Physiology For Cystic Fibrosis
Funder
National Health and Medical Research Council
Funding Amount
$778,228.00
Summary
We seek a cure or long-lasting therapy for the fatal airway disease in cystic fibrosis. Disease is caused by a shallow and dehydrated airway surface liquid (ASL), allowing bacteria to infect the lung. We can introduce a corrective gene into mouse airways where it can be effective for over 1 yr, but no fast, accurate and non-invasive measurement exists to test if treatments are successful. We will develop methods using synchrotron light to directly measure ASL depth changes in live mouse airways.
MPM Non-invasive Imaging Of Biological Interactions Following Drug Delivery With Micro-nanoprojection Patches.
Funder
National Health and Medical Research Council
Funding Amount
$403,612.00
Summary
The overarching aim of my research is to develop and evaluate effective, practical and reproducible physical methods for delivering genes and drugs to specific immunologically-sensitive cells in the skin to ultimately treat and vaccinate against human diseases. I recently patented a method using arrays of nano-scale projections on a patch to accurately, efficiently and safely deliver biomolecules not just to specific skin cells, but also to organelles within them. Conceptually, the delivery devi ....The overarching aim of my research is to develop and evaluate effective, practical and reproducible physical methods for delivering genes and drugs to specific immunologically-sensitive cells in the skin to ultimately treat and vaccinate against human diseases. I recently patented a method using arrays of nano-scale projections on a patch to accurately, efficiently and safely deliver biomolecules not just to specific skin cells, but also to organelles within them. Conceptually, the delivery device is a set of microscopic nanoneedles coated with drug substance and applied to the skin as a small patch. The device is practical, needle-free and pain-free. The aim of this current project is to use the micro-nanoprojection array patches-configured to uniquely deliver biomolecules to cells within given strata-to find: 1) what delivery sites of antigen-expression plasmid- toll like receptor (TLR) agonist lead to strong humoral immune responses in the intact animal. 2) whether delivery of different TLR agonists have different effects on the maturation and migration of the different professional antigen presenting cells (APCs) in the skin, as visualised locally by Multi-Photon Microscopy (MPM). 3) whether differences in APC maturation and migration are associated with different systemic antibody responses. We will identify optimal delivery sites of drugs-vaccines to the skin (layer, cells targeted, duration of delivery) with MPM for desired systemic immune responses. This will have important contributions towards improving immunotherapeutics of major diseases via skin targeting with micro-nanoprojection array patch technologies (and other methods).Read moreRead less
How Do Thick Airway Walls Affect Airway Hyperresponsiveness In Asthma?
Funder
National Health and Medical Research Council
Funding Amount
$382,538.00
Summary
Asthmatic airways narrow too easily, a characteristic called airway hyperresponsiveness (AHR). To understand the cause of asthma we need to understand the cause of AHR. Thickened airway walls could amplify airway narrowing and increase AHR. However, thick airway walls are also stiff, and stiff walls could reduce narrowing and AHR. This project will examine the relationships between AHR and airway wall thickness and stiffness during and after treatment that reduces airway wall thickness.
Does The Pattern Of Ventilation Distribution Predict Airway Hyperresponsiveness?
Funder
National Health and Medical Research Council
Funding Amount
$256,973.00
Summary
The tendency for airways to narrow too easily when stimulated is called airway hyperresponsiveness (AHR). AHR is an important feature of asthma, but it also occurs in other diseases, such as chronic obstructive pulmonary disease (COPD) - an airway disease caused by smoking, and cystic fibrosis. People who have AHR have more severe respiratory disease, regardless of which disease they have, and are more likely to develop poor lung function in old age and to be hospitalised or die from their disea ....The tendency for airways to narrow too easily when stimulated is called airway hyperresponsiveness (AHR). AHR is an important feature of asthma, but it also occurs in other diseases, such as chronic obstructive pulmonary disease (COPD) - an airway disease caused by smoking, and cystic fibrosis. People who have AHR have more severe respiratory disease, regardless of which disease they have, and are more likely to develop poor lung function in old age and to be hospitalised or die from their disease. If we can understand the causes of AHR we will have a better understanding of why some people with respiratory disease have poor outcomes. We have recently discovered that, in asthma, there is a very close relationship between AHR and the uneven distribution of air within the lungs. We believe that structural changes in the airways that cause this uneven distribution make the airways prone to AHR. This raises the possibility that factors that cause uneven ventilation in other respiratory diseases might also predispose the airways to AHR. If this is true, it suggests that there is a single physiological basis for AHR in a range of different diseases, and would allow us to focus research more closely on the causes of uneven ventilation. In this project we will measure the relationship between AHR and uneven ventilation in people with asthma, COPD or cystic fibrosis. The study is important because older people with asthma, particularly those with permanently narrowed airways, are likely to have more structural changes in their airways than young asthmatics, whereas people with COPD and cystic fibrosis have a different pattern of both structural changes and airway inflammation from that in asthma. The study will tell us whether there is a consistent relationship between AHR and uneven ventilation. If so, this would be extremely strong evidence that the factors that cause uneven ventilation contribute to AHR, and will point the way to studies of new treatments.Read moreRead less
Ventilation Heterogeneity And Airway Remodelling In Asthma
Funder
National Health and Medical Research Council
Funding Amount
$522,586.00
Summary
Asthma is a common and important as a cause of significant symptoms and even death. Associated with asthma is narrowing and stiffening of the arways which causes uneven ventilation of the lungs and reduced lung function. We have developed a new technique of imaging the lungs, as well as new lung function tests which measure uneven ventilation and stiffening of airways. This will help us design better medications, and help predict those who are at risk or severe asthma and death.
Novel Neuromechanical Measurements Of The Human Upper Airway In Health And Disease
Funder
National Health and Medical Research Council
Funding Amount
$543,728.00
Summary
Obstructive sleep apnea (OSA) is a common condition, in which the upper airway repeatedly collapses during sleep, causing the oxygen concentration in the blood to drop, carbon dioxide to rise, and the person to arouse in order to re-establish adequate oxygen supply. Consequences of OSA include increased daytime sleepiness, increased risk of accidents, and increased risk of cardiovascular diseases. It most commonly affects middle-aged males, but is also seen in the broader population. OSA is asso ....Obstructive sleep apnea (OSA) is a common condition, in which the upper airway repeatedly collapses during sleep, causing the oxygen concentration in the blood to drop, carbon dioxide to rise, and the person to arouse in order to re-establish adequate oxygen supply. Consequences of OSA include increased daytime sleepiness, increased risk of accidents, and increased risk of cardiovascular diseases. It most commonly affects middle-aged males, but is also seen in the broader population. OSA is associated with obesity and specific shapes of the upper airway and facial structure. These anatomical factors can be compensated for while awake but inadequate activity of the muscles surrounding the upper airway during sleep contributes to an increased predisposition of the airway to collapse. Airway collapse occurs when the muscles are unable to withstand the low pressures in the airway and collapse, obstructing the airway. This project will measure the stiffness and motion of the muscles surrounding the airway, in healthy people and those with OSA, to determine how these influence airway collapsibility. We will use two novel non-invasive Magnetic Resonance Imaging (MRI) techniques, MR Elastography, and MR tagging which will allow us to quantify the airway stiffness, or elasticity, and its motion (deformation). These will be the first direct measurements of the upper airway elasticity and deformation in humans. We will also measure how various treatments, such as CPAP therapy and mandibular advancement affect airway elasticity and deformation, so that their mechanisms can be better understood. This may also explain why some patients do not benefit from these therapies. These studies may lead to new diagnostic and treatment modalities, as well as gaining important insights into the basic mechanisms of airway collapse in humans.Read moreRead less