Plasticity of gastrointestinal vagal afferents. The aim of this project is to identify how leptin modulates specific subtypes of vagal afferent within the gut and the plasticity of this system under different dietary conditions. This proposed project will substantially increase understanding of the interactions between leptin, known to influence food intake, and vagal afferent satiety signals. It will also increase understanding of how these interactions alter in obesity and ultimately provide t ....Plasticity of gastrointestinal vagal afferents. The aim of this project is to identify how leptin modulates specific subtypes of vagal afferent within the gut and the plasticity of this system under different dietary conditions. This proposed project will substantially increase understanding of the interactions between leptin, known to influence food intake, and vagal afferent satiety signals. It will also increase understanding of how these interactions alter in obesity and ultimately provide targets and/or concepts for the pharmacotherapy of obesity.Read moreRead less
Central pathways regulating visceral pain. This project aims to investigate the neural pathways within the spinal cord and brain processing colorectal pain perception. The project aims to identify the spinal cord neurons relaying colorectal signalling into the brain and the influence of descending modulation from the brainstem upon these pathways. The outcomes will greatly benefit fundamental understanding of the central pathways processing visceral pain.
Using toxins to understand the mechanisms of pain. Toxins have evolved in plants, animals and microbes as part of defensive and/or prey capture strategies, and have proven to be invaluable research tools as well as providing leads for potential new therapies. This project will use subtype-selective toxins to define the role of ion channels in pain, using novel pathway-specific and disease-specific animal models of pain. The findings from this project will provide significant insight into the ne ....Using toxins to understand the mechanisms of pain. Toxins have evolved in plants, animals and microbes as part of defensive and/or prey capture strategies, and have proven to be invaluable research tools as well as providing leads for potential new therapies. This project will use subtype-selective toxins to define the role of ion channels in pain, using novel pathway-specific and disease-specific animal models of pain. The findings from this project will provide significant insight into the neuropharmacology of pain, will lead to the identification of novel molecular targets with analgesic potential and is expected to provide novel treatment approaches for pain.Read moreRead less
New Conus-derived alpha-conotoxin analgesics for the treatment of chronic pain: structure, mode of action, delivery and disposition. Current product deficiencies in the area of pain management are forcing the pharmaceutical industry to develop new strategies for achieving analgesia and reduce their dependence on traditional, addictive opiate-based products. Structural modification of cone snail derived peptides will provide exciting new leads for achieving effective analgesia.