Determination Of Sympathetic Preganglionic Neuronal Phenotype
Funder
National Health and Medical Research Council
Funding Amount
$241,527.00
Summary
The nervous system is the single most complex part of our body. Its function depends on millions of connections between neurons, all of which must form correctly during development. Furthermore, each neuron must select a neurotransmitter with which to talk to its target neuron. A neurotransmitter is a chemical released from a neuron, which passes a signal to a target cell. Some neurotransmitters cause excitation of the target cell, others inhibition. Each neurotransmitter signals to the target c ....The nervous system is the single most complex part of our body. Its function depends on millions of connections between neurons, all of which must form correctly during development. Furthermore, each neuron must select a neurotransmitter with which to talk to its target neuron. A neurotransmitter is a chemical released from a neuron, which passes a signal to a target cell. Some neurotransmitters cause excitation of the target cell, others inhibition. Each neurotransmitter signals to the target cell via receptor molecule, matched to the neurotransmitter. Thus, a neuron is faced not only with making choices about what connections to make within the developing brain, but also it must select from a range of potential neurotransmitters and receptor molecules. We are interested in how neurons select the appropriate neurotransmitter. There are a number of ways that a neuron might be guided to the correct choice. It is possible that it could receive from the target cell a signal that guides the choice of neurotransmitter. We wish to examine this hypothesis to see if it is applicable to the autonomic nervous system, that part of the nervous system that controls functions like changes in blood pressure and heart rate. Our laboratory is expert in identifying the chemistry of autonomic neurons. We will use this knowledge to see what happens when we deliberately perturb the normal connections of autonomic neurons. Do they persist in expressing the neurotransmitters they would have done prior to the perturbation? Alternatively, do they adapt to the change of target via a signal received from the new target cell and express the appropriate phenotype? The results of these experiments will give insights into how the brain develops. The results will be important for both our basic understanding of biology and as a basis for the development of techniques for reversing neuronal damage.Read moreRead less
Plasticity And Regeneration Of Bladder Motor Nerve Circuits After Injury
Funder
National Health and Medical Research Council
Funding Amount
$333,313.00
Summary
Our goal is to determine ways of improving the recovery of bladder-controlling nerves after they are injured, which has devastating effects on bladder function. This can happen because of lumbosacral spinal nerve damage or pelvic surgery. We also expect to establish broad principles that may be tested in other neurological conditions that affect bladder function, such as neurodegenerative disorders (e.g. diabetes) and spinal cord injury.
Modulation Of Autonomic Nerve Growth By Guidance Factors
Funder
National Health and Medical Research Council
Funding Amount
$393,277.00
Summary
Our goal is to understand how adult nerves are affected by injury so that we can devise therapies to make them regrow better. We will focus on nerves that control the urogenital organs because these are often injured during surgical procedures (e.g. prostatectomy, hysterectomy), with devastating effects on patients' quality of life. In this project we will investigate how naturally-occurring growth-inhibitory molecules affect nerve regrowth after injury in the pelvic nervous system.
Mechanosensitive Afferent Nerves And Gastrointestinal Motility
Funder
National Health and Medical Research Council
Funding Amount
$384,693.00
Summary
This project aims to identify the different types of sensory nerves from the gut which cause sensations such as fullness, nausea or pain. These sensory nerves also activate important reflexes that coordinate different regions of the gut to ensure that food is properly digested and propelled. Many studies have examined these sensory nerves and how they can be activated by stretching the gut wall, but very basic questions remain to be answered. We do not know how many different types of sensory ne ....This project aims to identify the different types of sensory nerves from the gut which cause sensations such as fullness, nausea or pain. These sensory nerves also activate important reflexes that coordinate different regions of the gut to ensure that food is properly digested and propelled. Many studies have examined these sensory nerves and how they can be activated by stretching the gut wall, but very basic questions remain to be answered. We do not know how many different types of sensory nerves there are and whether they all respond to stretch in the same way. We cannot identify their specialised endings in the wall of the gut. While these sensory nerves definitely respond to stretch, they are also known to respond to contractions of the gut wall. Despite this, we do not understand how the normal movements of the gut wall activate them, nor why some movements can lead to pain. Most of the experiments will be carried out on small pieces of tissue taken from humanely killed guinea pigs and studied, under highly controlled conditions, in organ baths. The remainder of the study will be on specimens of human gut tissue obtained at surgery. This project will use new techniques to record sensory nerves during both stretch and contraction of the gut wall to understand what activates them. In addition, their endings will be labelled with dye to reveal their different shapes. Using computerised imaging techniques we will identify whether they respond to particular patterns of movement in the gut wall. Lastly we will record from these sensory neurones in live specimens of human colon to see whether the same types of sensory nerves are present in humans as in the small animals. This study will provide the first comprehensive account of sensory nerves to the gut wall that respond to distension, including those that activate pain pathways. This is a pre-requisite for designing new drugs that will target these nerve cells with minimal side effects.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.
What Central Mechanisms Increase Cardiac Sympathetic Nerve Activity In Heart Failure?
Funder
National Health and Medical Research Council
Funding Amount
$401,389.00
Summary
Heart failure is a disabling and deadly syndrome that has reached epidemic proportions in western populations. In heart failure, the activity of the sympathetic nerves to the heart is dramatically increased, leading to development of arrhythmias and sudden death. Using our unique model of heart failure, in which we directly record cardiac sympathetic nerve activity, we aim to determine the mechanisms in the brain that cause this large, detrimental increase in nerve activity.