Silencing Pulmonary Nociceptors To Treat Severe Respiratory Viral Infections
Funder
National Health and Medical Research Council
Funding Amount
$534,173.00
Summary
The lungs receive a rich supply of nerve fibres, many of which play an important role in helping defend against pathogens, including viruses. When viral infections become severe, too much inflammation occurs in the lungs and this creates a serious and difficult to treat clinical problem. Hundreds of thousands of people each year die from the complications of severe lung infections. We are investigating a potential new therapy that targets the lung nerves and relieves excessive inflammation.
Innate Threat Detection Circuits In The Superior Colliculus Co-ordinate Respiratory And Cardiovascular Responses To Visual Stimuli
Funder
National Health and Medical Research Council
Funding Amount
$517,958.00
Summary
Our surroundings affect our bodies: light pollution, traffic, and aircraft noise all significantly affect cardiovascular health. This project will investigate interactions between brain systems that subconsciously scan our surroundings for interesting or threatening features, and those that co-ordinate the cardiovascular and respiratory systems. We will generate new knowledge that describes how the brain detects danger and translates this into signals that contribute to cardiovascular risk.
A novel sensory neural circuit has been identified innervating the airways and lungs. The anatomical organisation of this circuit has been described to some extent in previous studies, however there is a significant gap in knowledge with respect to its functional importance. This project will develop methods to address this knowledge gap and in doing so the project will firstly describe how this circuit controls breathing under normal conditions and secondly how this becomes dysregulated during
Neurotransmission In Functionally Distinct Vasodilator Pathways
Funder
National Health and Medical Research Council
Funding Amount
$809,934.00
Summary
A surprising feature of our body is that there is not enough blood to fully supply all our organs at once. This is why we sometimes faint when we are hot or get cramps when we are exercising. Consequently, the blood vessels change their diameter so that blood can be directed to the organs with greatest demand at any particular time. For example, if the vessel decreases in diameter, less blood flows through it, but if it increases in diameter, more blood flows through it to reach the appropriate ....A surprising feature of our body is that there is not enough blood to fully supply all our organs at once. This is why we sometimes faint when we are hot or get cramps when we are exercising. Consequently, the blood vessels change their diameter so that blood can be directed to the organs with greatest demand at any particular time. For example, if the vessel decreases in diameter, less blood flows through it, but if it increases in diameter, more blood flows through it to reach the appropriate organ. An important function of the nervous system is to control the flow of blood to different organs by changing the diameters of the blood vessels. One set of nerves decreases the diameter of the arteries, and another set of nerves increases the diameter. The nerves do this by releasing special combinations of chemicals when they get a message from the brain to do so. In this project we are especially interested in the nerves which increase blood flow to organs in the head and the pelvis. We will use a wide range of modern methods to find out how these nerves work. In some experiments, we will use sophisticated electrical equipment to measure just how the nerve cells controlling the diameter of the vessels respond to the instructions sent by the brain. In other experiments, we will find out which chemicals the nerves use to make the blood vessels increase in diameter. We also will discover how the various chemicals get released by the nerves at the right times, so that messages from the brain get to the blood vessels as efficiently as possible. One of the special parts of our project is that we will be able to observe directly the connections between the nerve cells and the blood vessels we are studying. Our results will be important for designing new drugs that could help people whose nerves are not working properly, such as in some patients with diabetes or vascular disease.Read moreRead less
Vasomotor Ganglionic Transmission: The Preganglionic Peptide And The Second Gear
Funder
National Health and Medical Research Council
Funding Amount
$451,896.00
Summary
Blood pressure depends on nerve signals that travel from the central nervous system to blood vessels. In the middle of this pathway is a relay station - the sympathetic ganglion cell. Transmission through this relay station has recently been shown to have not only a fixed but also a variable component - the 'second gear'. The project tests if and how three likely candidate peptide molecules, one in the nerves, two in the bloodstream, control this 'second gear' and hence regulate blood pressure.
Gastrointestinal Sensory Function In Normal And Diseased States
Funder
National Health and Medical Research Council
Funding Amount
$691,026.00
Summary
Chronic pain and discomfort from the digestive system is a major health care issue world-wide. There is currently no effective treatment for these problems, which often have no apparent organic cause. Lack of treatment is due to a lack of understanding about how sensations are transmitted from the digestive system to the brain. Our research group has unique and powerful techniques that allow us to probe the basic mechanisms of sensory function, and make rapid progress towards finding drugs that ....Chronic pain and discomfort from the digestive system is a major health care issue world-wide. There is currently no effective treatment for these problems, which often have no apparent organic cause. Lack of treatment is due to a lack of understanding about how sensations are transmitted from the digestive system to the brain. Our research group has unique and powerful techniques that allow us to probe the basic mechanisms of sensory function, and make rapid progress towards finding drugs that reduce specific types of sensory signals from the gut. We shall investigate sensory mechanisms in the upper and lower regions of the gut, where symptoms are most prevalent in diseases such as non-cardiac chest pain, functional dyspepsia and irritable bowel syndrome. Six aspects of sensory nerve endings in the gut are to be investigated: 1. The grouping of endings into functional classes (similar to touch or pressure receptors in skin) 2. How endings respond to chemicals and hormones found in the gut 3. How currently available drugs may be useful in reducing sensitivity 4. The mechanisms by which inflammation affects sensitivity 5. How nerve growth factors may trigger changes in sensitivity 6. How pores or channels in nerve endings determine their functionRead moreRead less