The Role Of Prostaglandins In The Control Of Intestinal Motility In Physiological And Experimental Inflammatory States.
Funder
National Health and Medical Research Council
Funding Amount
$316,209.00
Summary
Many intestinal disorders are due to inflammations of unknown origin, associated with pain, diarrhoea or constipation. How this occurs is not known. The movements of the intestine are due to the contractions and relaxations of the muscular wall, which are controlled by a network of nerve cells, a kind of a brain in the gut. In inflammatory conditions, a multitude of chemical substances are produced by the sick gut. Among these substances are the prostaglandins that are responsible for increasing ....Many intestinal disorders are due to inflammations of unknown origin, associated with pain, diarrhoea or constipation. How this occurs is not known. The movements of the intestine are due to the contractions and relaxations of the muscular wall, which are controlled by a network of nerve cells, a kind of a brain in the gut. In inflammatory conditions, a multitude of chemical substances are produced by the sick gut. Among these substances are the prostaglandins that are responsible for increasing pain from inflamed parts. However, the gut makes prostaglandins even when there is no inflammation, although it is not clear what do these substances do in the normal intestine. During disease, prostaglandins are made in much larger amounts. If we can establish what they do normally we may be able to establish how they work in disease. Therefore our projects is in two parts. First, we will investigate how prostaglandins normally affect the working of the nerves and muscle controlling intestinal movement. In the second part we will reveal the role of these substances during mild inflammation induced in some laboratory animals to mimic human diseases. All experiments will be carried out on intestines removed from these experimental animals after they are killed humanely. This enables us to study how the experimentally induced diseases affect gut function, especially movement. We will use a method, that has recently been developed in our laboratory, to transform video recordings of gut movements into computer-generated maps. From these pictures, we can see patterns of movement that are too subtle to detect by just watching the videos. We will end our project by establishing if and when prostaglandins are responsible for producing the abnormal intestinal movements seen in disease. This will give clinicians a better basis to develop new drugs against gut disorders.Read moreRead less
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
Interactive and scalable media over software defined networks. A novel API and associated algorithms will be developed to exploit the emerging technology of software defined networks (SDN) for improving the efficiency and responsiveness of interactive media browsing applications. The approach applies to conventional streaming video as well as more interactive services based on scalable media compression and communication technology, notably JPIP (IS15444-9) video. Recent advances in motion codin ....Interactive and scalable media over software defined networks. A novel API and associated algorithms will be developed to exploit the emerging technology of software defined networks (SDN) for improving the efficiency and responsiveness of interactive media browsing applications. The approach applies to conventional streaming video as well as more interactive services based on scalable media compression and communication technology, notably JPIP (IS15444-9) video. Recent advances in motion coding will be combined with new spatio-temporal transforms to develop an efficient inter-frame extension to the JPEG 2000 standard that is fully compatible with JPIP. Each of these innovations is important in its own right, but together they will facilitate a highly compelling interactive media browsing experience.Read moreRead less
Innovations In Cancer Imaging And Targeted Radiotherapy To Improve Human Health
Funder
National Health and Medical Research Council
Funding Amount
$926,980.00
Summary
Through a process of discovery, development and investigation we will create medical devices and methods to improve cancer imaging and targeted radiotherapy. Successful completion of this program will directly impact on the treatment and lives of Australian cancer patients in the foreseeable future.This program will substantially build research capacity and productivity within Australia, raise Australia’s profile in cancer research and foster international collaboration.
Development Of A Non-invasive Magnetic Resonance Based Cartilage Damage Assessment Technique
Funder
National Health and Medical Research Council
Funding Amount
$556,131.00
Summary
This project will develop automated methods for the extraction of 3D maps of cartilage, bone and other anatomy from high field Magnetic Resonance Images of joints in the body.
MR Hip Intervention And Planning System To Enhance Clinical And Surgical Outcomes
Funder
National Health and Medical Research Council
Funding Amount
$668,069.00
Summary
Degenerative hip disorders and osteoarthritis are a major cause of chronic pain and disability. This project will develop a software tool that allows clinicians to assess, monitor and plan patient treatment using magnetic resonance imaging. It will be the first tool that models joint motion using assessments of bone, cartilage and labral tissue. This will help guide treatment selection and improve outcomes from hip surgeries performed on over 20,000 Australians each year.
Compression and communication of single and multi-view video based on overlapping motion hint fields. This project explores a new way of communicating motion for video and multi-view (3D) applications, facilitating efficient interactive access to content. Outcomes will include new compression methods that avoid redundant transmission of motion side information, plus client/server technology that leverages metadata from smart surveillance cameras.
Advancing The Spatial Analysis Of Cells In Tissues To Profile The Tumour Microenvironment
Funder
National Health and Medical Research Council
Funding Amount
$187,918.00
Summary
Tumours are composed of a mix of different cells, including cancer cells, immune cells and other cells supporting tumour growth. These cells are not organised randomly, but rather are distributed in specific patterns. Here we will develop computational methods to detect these patterns and determine what statistical tests should be used to compare samples. This project will give us the tools to investigate how the location of cells in tissues relates to treatment response and survival.