Characterising Post Stroke Neuroplasticity In Humans – Identifying A Critical Window For Rehabilitation
Funder
National Health and Medical Research Council
Funding Amount
$764,419.00
Summary
Despite major investment in care for stroke patients, almost all have persisting disability. Stroke causes loss of brain cells that cannot be replaced. Some recovery is possible through compensatory mechanisms. In addition, intact cells around the stroke undergo growth that is critical for recovery. Animal studies suggest these changes take place in a “critical window” after stroke. Applying therapies in this window should improve outcomes. We will use novel approaches to define the “critical wi ....Despite major investment in care for stroke patients, almost all have persisting disability. Stroke causes loss of brain cells that cannot be replaced. Some recovery is possible through compensatory mechanisms. In addition, intact cells around the stroke undergo growth that is critical for recovery. Animal studies suggest these changes take place in a “critical window” after stroke. Applying therapies in this window should improve outcomes. We will use novel approaches to define the “critical window” in patients after strokeRead moreRead less
Stimulant laxatives are widely used and usually very effective in the short term, but how they work is very poorly understood. Our recent work has shown that they selectively excite sensory pathways from the colon which then trigger defaecation. This points to an undiscovered mechanism that potently affects colonic sensation and motility. This is likely to be a target for new treatments for other colonic disorders such as Irritable bowel syndrome and faecal incontinence.
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.
Chronic inflammation underlies common and debilitating diseases and causes pain by unknown mechanisms. There is an urgent need to gain a deeper understanding of the mechanisms of chronic pain, which will allow the development of improved therapies with fewer side-effects. Our research program investigates the mechanisms of pain that are associated with inflammatory bowel disease and irritable bowel syndrome, with the goal of developing more effective and selective therapies.