Piezo2 And Pain - Is There A Role For Piezo2 In Mechanically Induced Bone Pain?
Funder
National Health and Medical Research Council
Funding Amount
$543,848.00
Summary
Pain associated with bone marrow edema, osteoarthritis, bone cancer and fracture puts a significant burden on individuals, society, and the health care system in Australia. A dominant feature of these includes mechanical disturbances of the bone, and this is a trigger for the pain. In this study, we will determine if a newly discovered mechanically gated ion channel (Piezo2) is a key contributor to mechanically induced bone pain and could be a target for development of drugs to treat it.
Importance Of CGRP Alpha In Pain Processing From The Large Intestine
Funder
National Health and Medical Research Council
Funding Amount
$548,289.00
Summary
This project will determine the mechanisms by which sensory nerve endings detect painful stimuli in the large intestine. The project will use a novel genetically modified mouse (that is only available in our laboratory) which allows us, for the first time, to visualize and record directly from the sensory nerve endings that detect painful stimuli and work out how this process occurs. We also identify a specific gene that is essential for detecting painful stimuli from this organ.
Discovery And Development Of Better Pain Treatments
Funder
National Health and Medical Research Council
Funding Amount
$9,613,850.00
Summary
Many forms of pain remain poorly treated, leading to significant quality of life and economic losses. This Program grant will discover and characterise new peptides from cone snails and spiders that modulate specific channels in nerves that are critical to the transmission of pain signals to the brain. Using advanced chemical and structural approaches, promising leads will be optimised for potency and stability and evaluated in disease and pathway-specific models of pain to establish their clini ....Many forms of pain remain poorly treated, leading to significant quality of life and economic losses. This Program grant will discover and characterise new peptides from cone snails and spiders that modulate specific channels in nerves that are critical to the transmission of pain signals to the brain. Using advanced chemical and structural approaches, promising leads will be optimised for potency and stability and evaluated in disease and pathway-specific models of pain to establish their clinical potential.Read moreRead less
Spinal Cord Injury Pain: Understanding Mechanisms To Develop Treatments
Funder
National Health and Medical Research Council
Funding Amount
$597,675.00
Summary
Spinal cord injury has devastating effects on health and quality of life. Many of the major consequences of injury, such as chronic pain and loss of voluntary voiding, are "invisible" – i.e., they are not as visible as limitations of mobility. Our study aims to define the neurobiological changes that cause development of persistent pain after spinal cord injury and use pharmacological tools to attenuate the development of pain.
Our vestibular system provides us with the important sense of balance. When it fails we suffer debiltating bouts of vertigo and dizziness. A great deal is known about how balance signals are sent from the inner ear to our brains, but virtually nothing is known about the important signals the brain sends to the inner ear. In this study we will use a new perparation develped in our laboratory to examine how these essential brain signals control the function of our balance organs.
Development Of Peripheral Sensory Pathways In Humans
Funder
National Health and Medical Research Council
Funding Amount
$477,504.00
Summary
To receive the appropriate information about the state of our muscles, joints, organs, and skin we need a properly 'connected' sensory system. Recent evidence suggests traumatic events during early development can alter sensory connections within the spinal cord. This can lead to debilitating movement disorders, digestive diseases, and increased pain. In this study we will examine how peripheral sensory fibres connect with the appropriate nerve cells in the human spinal cord during development.
Although chronic pain is a serious clinical problem, treatments for its alleviation have largely failed, in part because they have not been tailored to the specific origin of the pain. This proposal focuses on rheumatoid arthritis, a common and incurrable source of chronic pain. This study will investigate how specific changes in spinal cord nerve cells contribute to chronic arthritic pain. The outcomes will help identify new targets to treat chronic pain in rheumatoid arthritis.
Pain Systems Analysis Highlights PI3K Gamma As A Candidate Regulator Of Nociception.
Funder
National Health and Medical Research Council
Funding Amount
$461,810.00
Summary
Chronic pain will affect most of us at one point in our life, and there is a need for new drugs to manage this condition. The goal of this project is to use our computer modeling of genetic data from multiple species to predict new drug targets, and then use mouse models to look at the mechanism of action for predicted drug targets, and validate one potential drug target in particular for its therapeutic abilities to stop chronic pain.
Ion Channels Underlying Inflammatory And Post-inflammatory Visceral Mechanical Hypersensitivity
Funder
National Health and Medical Research Council
Funding Amount
$453,439.00
Summary
Inflammation causes tissue damage that triggers ion channels within sensory nerve fibres to produce greater signals in response to mechanical events, causing acute pain. In chronic pain, although the inflamed tissue has healed, sensory nerve fibres fail to "reset" back to normal. Often chronic pain is more severe than acute pain. This project will identify which ion channels are responsible for signalling acute and chronic visceral pain, explaining why sensory nerve fibres fail to reset.