How Intestinal Motility Activates Sensory Pathways
Funder
National Health and Medical Research Council
Funding Amount
$555,875.00
Summary
Pain and discomfort from the gut are common and unpleasant. We understand how gut sensory nerve cells work, at the cellular, molecular and genetic level. However, movement of the gut wall and contents are the major cause of activation of sensory neurons. We know little about which particular patterns of movement cause pain. This is crucial information for accurately diagnosing human gut disorders, for monitoring effectiveness of treatments and for identifying potential new drug targets.
Imaging The Activation Of Sensory Nerve Endings That Detect Pain In The Colorectum
Funder
National Health and Medical Research Council
Funding Amount
$570,334.00
Summary
Within the gastrointestinal tract are sensory nerve endings that detect painful stimuli. In this project a new technique has been developed that allows us to monitor and record the activation of the particular sensory nerve endings that detect painful stimuli. This project will determine how these sensory nerve endings detect pain and how drugs might be used to relieve these unpleasant sensations arising from the gut wall.
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.
Intramuscular Interstitial Cells Of Cajal; Ion Channels And Their Modulation By Calcium Ions And Neurotransmitters.
Funder
National Health and Medical Research Council
Funding Amount
$523,261.00
Summary
Disorders of gut motility manifest themselves in several ways, as either patterns of hyperactivity or patterns of reduced activity. Under normal conditions gut motility reflects a balance between myogenic, neuronal and hormonal factors but as yet how this balance is normally achieved is not understood. This project will examine the properties of a class of cells, whose importance in both myogenic and neural control mechanisms has only been recognized over the last 10 years. The muscular wall of ....Disorders of gut motility manifest themselves in several ways, as either patterns of hyperactivity or patterns of reduced activity. Under normal conditions gut motility reflects a balance between myogenic, neuronal and hormonal factors but as yet how this balance is normally achieved is not understood. This project will examine the properties of a class of cells, whose importance in both myogenic and neural control mechanisms has only been recognized over the last 10 years. The muscular wall of the gut is made up of two distinct types of cells. One group, smooth muscle cells, contains contractile elements and the coordinated behavior of these cells leads to the contractions of the gut wall, so ensuring the controlled passage of gut contents along the gastrointestinal tract. The other group of cells, Interstitial cells of Cajal, lack contractile elements. One set of these cells have recently been found to be the pacemaker cells of the gut responsible for the initiation of myogenic activity. They generate pacemaker waves which ensure that the gut contracts rhythmically. Another set of these cells are densely innervated, they receive messages from the nervous system and translate these messages into signals which alter the activity of the gut. Thus these cells play a key role in the neural control of the gut. In many disease states, the numbers of interstitial cells of Cajal have been found to be reduced. However as yet we know very little about these cells. This project will, for the first time, examine the properties of the interstitial cells involved in neural control and will determine how they carry out these essential functions.Read moreRead less