Peripheral Mechanisms Involved In Autonomic Hyperreflexia
Funder
National Health and Medical Research Council
Funding Amount
$229,917.00
Summary
Bladder distension or minor unheeded injuries below the lesion in spinally injured people often lead to episodes of high blood pressure that may cause stroke or death. These events require emergency hospitalization and are expensive as well as dangerous. After spinal injury, the control of sympathetic nerves that supply arteries and regulate blood pressure is lost. However, the nerves below the injury remain in place and the spinal cord below the lesion contains connections that can activate the ....Bladder distension or minor unheeded injuries below the lesion in spinally injured people often lead to episodes of high blood pressure that may cause stroke or death. These events require emergency hospitalization and are expensive as well as dangerous. After spinal injury, the control of sympathetic nerves that supply arteries and regulate blood pressure is lost. However, the nerves below the injury remain in place and the spinal cord below the lesion contains connections that can activate them. Signals from the bladder or skin enter the remaining lower part of the spinal cord and activate the sympathetic supply generating a rise in blood pressure. This project will test the hypothesis that increased sensitivity of arteries to the chemicals released from the sympathetic nerves leads to excessive vessel constriction, contributing to the exaggerated increase in pressure. We will investigate arteries removed from rats with experimental spinal transection. We will test the contractions of the arteries (a) to sympathetic nerve stimulation and (b) to the chemicals noradrenaline, adenosine 5'-triphosphate (ATP) and neuropeptide Y that are normally released during nerve activity. We will determine whether release of noradrenaline and ATP from nerves is normal or augmented using electrochemical and electrophysiological techniques. We will compare the responses with those in normal arteries, those in arteries whose nerves have been silenced by removing all connections from the spinal cord and those in arteries that have lost all their nerve supply. This will enable us to identify whether the mechanisms for release of transmitter substances are modified and whether the arterial muscle is hypersensitive to these substances. The results will help in the design of safer treatment for these potentially lethal emergencies in spinal patients.Read moreRead less
Do Postjunctional Alterations Explain The Effects Of Diabetes On Neurovascular Transmission?
Funder
National Health and Medical Research Council
Funding Amount
$390,886.00
Summary
Diabetes produces disordered skin blood flow that increases risk of skin ulcers and gangrene. The project investigates nervous control of skin blood vessels in diabetes. It is assumed that all affects of diabetes on nerve function are explained by loss of nerves. We hypothesize that some affects of diabetes are due to dysfunction of blood vessels and not to nerve loss. The objective is to identify drug targets to improve blood flow in skin and thereby reduce the risk of skin ulcers and gangrene.
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
Morphological Determinants Of Neurotransmission In Autonomic Ganglia.
Funder
National Health and Medical Research Council
Funding Amount
$450,111.00
Summary
The nervous system consists of billions of nerve cells that are connected together in special ways to process information about the outside world and our internal state and then generate the appropriate responses of our body to this information. To understand the complex working of the brain and its nerves, we have to understand how all these nerves are connected to each other. We are interested in the nerves that control the functions of the internal organs, such as arteries, glands and the gut ....The nervous system consists of billions of nerve cells that are connected together in special ways to process information about the outside world and our internal state and then generate the appropriate responses of our body to this information. To understand the complex working of the brain and its nerves, we have to understand how all these nerves are connected to each other. We are interested in the nerves that control the functions of the internal organs, such as arteries, glands and the gut. The brain controls these functions automatically, so we usually are not directly aware of their activity. The instructions to change the activity of the internal organs are sent from the brain down the spinal cord. The information is then sent from the spinal cord to the organs via a special set of nerves. However, instead of going directly to their targets, these nerves make connections with yet another set of nerves, which then go on to make the final connections with the appropriate target organs. We know a lot about these final nerve cells, including how big they are, how complicated they look, and what kinds of chemicals they use to send messages to the organs that they control. However, we still do not very much about how all these nerves are connected to each other. In this project we will use different types of modern microscopes that use either lasers or electron beams to look directly at the nerves and their connections. We then will use computerised models to construct a detailed map of the pathways taken by the nerves on their way to their target organs. By knowing how the nerves are connected to each other in these pathways, we will be able to understand how the instructions of the brain are modified depending on what other things are going on in the body at the same time. This information will be vital to help us appreciate how the nerves work when we get sick or injured.Read moreRead less