The Knotty Problem Of Enterochromaffin Cells And Gastro-intestinal Function: Unravelling Cause And Effect
Funder
National Health and Medical Research Council
Funding Amount
$403,097.00
Summary
It is crucial to understand how the food we eat controls the secretions and movements of a healthy or a diseased gastrointestinal (GI) system. One way control is achieved involves the release of serotonin (5-HT) from the enterochromaffin cells present in the epithelial lining of the intestine. This is the subject of our proposal and our results will help us to understand the causes of GI disorders and help to formulate new treatments.
Is Leaky Gut A Precursor To Inflammatory Bowel Disease?
Funder
National Health and Medical Research Council
Funding Amount
$89,176.00
Summary
Inflammatory Bowel Diseases (IBD) are chronic idiopathic diseases, characterised by episodes of relapse and remission of intestinal inflammation. Whilst the exact cause remains unknown, there is mounting evidence that a defect exists in the gut lining protecting the body in patients who develop IBD allowing bacterial antigens to enter the body. We aim to use novel imaging combined with colonoscopy called confocal endomicroscopy to image the bowel lining at high power to demonstrate this defect.
The Neural Control Of Serotonin Release From Intestinal Enterochromaffin (EC) Cells
Funder
National Health and Medical Research Council
Funding Amount
$117,187.00
Summary
Many functional gastrointestinal problems are believed to be caused by a disruption of the normal functioning of the nerves within the wall of the gut. These nerves are believed to receive information about the contents of the intestine from a specialised class of cell lining the inside wall of the gut called the enterochromaffin cell. The enterochromaffin cell does this job by modulating the release of the transmitter serotonin. In some disorders, like the Irritable Bowel Syndrome (IBS) which c ....Many functional gastrointestinal problems are believed to be caused by a disruption of the normal functioning of the nerves within the wall of the gut. These nerves are believed to receive information about the contents of the intestine from a specialised class of cell lining the inside wall of the gut called the enterochromaffin cell. The enterochromaffin cell does this job by modulating the release of the transmitter serotonin. In some disorders, like the Irritable Bowel Syndrome (IBS) which can affect the upper and lower intestine, the information that serotonin carries can become confused. Thus, the control of the release of serotonin from the enteroendocrine cell is an important process to understand in health and in disease. We will investigate this release directly in isolated tissues from guinea pig small and large intestine and from human large intestine. This study will examine the role of serotonin and the modulation of its release from the enterochromaffin cell. Problems with serotonin release may underlie disease, thus, understanding how this release is controlled will provide a foundation for new and specific therapies that target channels or receptors specific to the release of serotonin. These data could help to develop therapies for gastrointestinal problems such as the IBS, chronic intestinal pseudo-obstruction and gastro-oesophageal reflux disease. The release of serotonin is also intimately linked with the diarrhea associated with cholera and anti-cancer treatments. The proposed study will contribute to the ongoing development of specific therapies that block serotonin receptors on the nerve terminal and will lead to new therapies that compliment existing therapies by modulating the release of serotonin.Read moreRead less
How The Intestinal Microenvironment Controls Propulsion And Mixing Of Food In The Gut: Parallel Transduction Pathways
Funder
National Health and Medical Research Council
Funding Amount
$1,157,350.00
Summary
This project will identify the mechanisms that control the mixing of food with digestive juices, the absoprtion of nutrients from the gut to the blood stream and the excretion of waste. Disruption of these processes causes significant health problems and is associated with normal aging and many diseases. We will identify nutrients and other food components (eg spices) that switch gut from mixing to propulsion and hence identify targets to treat disorders of gut movement.
Bioresponsive Porous Silicon For Site Specific Oral Delivery Of Antibodies For The Treatment Of Inflammatory Bowel Disease
Funder
National Health and Medical Research Council
Funding Amount
$318,768.00
Summary
This proposal aims to develop an oral antibody delivery system for treatment of inflammatory bowel disease (IBD) that affects 75000 Australians. The system will be based on porous silicon nanoparticles acting as a container to protect the antibodies, and bioresponsive coatings acting as gates to enable site specific protein delivery at the inflamed site of GI tract. The project not only holds promise for protein delivery for the treatment of IBD but other diseases like diabetes.
Novel Applications Of Ghrelin Peptides In Mouse Models Of Inflammatory Bowel Disease
Funder
National Health and Medical Research Council
Funding Amount
$243,116.00
Summary
Inflammatory bowel disease (IBD) is a debilitating, chronic condition that often affects patients in the primes of their lives. A limited number of treatments are currently available for these patients and those that are available often have serious side effects, including growth restriction in children. Ghrelin is a natural hormone that has been shown to suppress many features of IBD. This project will investigate the potential of ghrelin as a new treatment for inflammatory bowel disease.
How Spinal Afferent Nerves Cause Vasodilation Of Mesenteric Arteries
Funder
National Health and Medical Research Council
Funding Amount
$353,250.00
Summary
Healthy function of the gastrointestinal tract requires an adequate blood supply during periods of varying demand. Inadequate blood supply to the gut contributes to disorders ranging in severity from mild through to lethal. Reduced blood supply to the gut is a trigger for multiple organ failure syndrome; a leading cause of death in critically ill patients following major surgery, trauma or haemorrhage. It is believed that damage to the lining of the gut, during periods of reduced flow, trigger i ....Healthy function of the gastrointestinal tract requires an adequate blood supply during periods of varying demand. Inadequate blood supply to the gut contributes to disorders ranging in severity from mild through to lethal. Reduced blood supply to the gut is a trigger for multiple organ failure syndrome; a leading cause of death in critically ill patients following major surgery, trauma or haemorrhage. It is believed that damage to the lining of the gut, during periods of reduced flow, trigger inflammatory mechanisms throughout the body. Mesenteric ischaemia is a disorder which occurs as a chronic, non-occlusive form, or as acute episodes, which are often lethal, . Temporary increases in blood supply are also known to play a vital role in protecting the gut from acid, toxins and attack by pathogens. The major mechanism underlying increases in bloody supply is dilation of arterial vessels. This occurs focally, at the site of damage, via local mechanisms, but this is supplemented by a more widespread dilation of arteries upstream, mediated by branches of sensory neurones that innervate blood vessels directly. Currently, there is no information about how these sensory neurones are activated. This is crucial to understand how they work. We hypothesise that these sensory neurones are activated by chemical and mechanical stimuli in the gut wall, which make them release vasodilator chemicals onto the arteries upstream and thus amplify the local increases in blood flow. We will test this by recording from sensory nerves, identifying the ones which project to blood vessels and determine which chemicals and mechanical stimuli they are excited by. We will then fill them with dye, using a method that we have recently developed, to visualise their branching patterns both inside and outside the gut wall. In this way, we will understand how this powerful protective mechanism is activated at times of need, and how it may fail under some circumstances.Read moreRead less
The Role Of The Intestinal Epithelium In Gliadin Peptide Influx In Coeliac Disease
Funder
National Health and Medical Research Council
Funding Amount
$503,566.00
Summary
Food products made from cereals such as wheat are part of the staple diet for much of the world but unfortunately they trigger coeliac disease in 1:100 individuals including more than 100,000 Australians. This project aims to determine where the disease inducing proteins cross the cells that line the intestine to enter the body. It also aims at increasing the health of these cells to produce a barrier that can prevent the disease inducing proteins from entering the body.
Spatio-temporal Analysis Of Rat Intestinal Motility In Physiological And Disease Models
Funder
National Health and Medical Research Council
Funding Amount
$358,750.00
Summary
This project addresses the question of how the movements of the gut are controlled in health and disease. The progress of food along the gut is due to movements of the involuntary muscle of the wall of the intestine. Three fundamental mechanisms are involved. One is the spontaneous ability of the intestinal muscle to contract rhythmically and is driven by a delicate net of pacemaker cells. Fast propulsion of food contents depends on nerve circuits in the gut wall that generate a powerful pumping ....This project addresses the question of how the movements of the gut are controlled in health and disease. The progress of food along the gut is due to movements of the involuntary muscle of the wall of the intestine. Three fundamental mechanisms are involved. One is the spontaneous ability of the intestinal muscle to contract rhythmically and is driven by a delicate net of pacemaker cells. Fast propulsion of food contents depends on nerve circuits in the gut wall that generate a powerful pumping behaviour to prevent over-filling or to eject toxic or irritating substances (eg: some laxatives activate this mechanisms). This is often called peristalsis. A third mechanism consists of activity of nerve cells in the gut, that slowly propagates along the intestine and causes the muscle to contract, sweeping along any remnants. The movements generated by these three mechanisms occur in segments of intestine isolated from rats. The major difficulty up until now has been to relate the actual movements in living animals to these fundamental mechanisms. It is now possible to bridge this gap because we have developed methods to record, display and measure graphically the actual movements. Movements are transformed into spatio-temporal maps which show all of the contractions over a period of time. Coordinated activity is visible in these maps as recognisable patterns or visual objects. Measurements can be readily made with conventional statistics. The literature in gastroenterology is full of descriptions of motility based on indirect methods of recordings. In this project we will be able to correlate the previous indirect methods with the new graphic methods and thus establish a clearer, simpler and more accurate classification of normal patterns of intestinal motility. We will then use this to establish what goes wrong in a number of experimental diseases known to affect adversely the movements of the intestine.Read moreRead less