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.
A Novel Technique For Prolonged Silencing Of Visceral Pain Without Opiates
Funder
National Health and Medical Research Council
Funding Amount
$637,383.00
Summary
There has been substantial interest in the community for pain relief without opiates. This project demonstrates a new strategy to suppress pain at the source for prolonged periods, by suppressing activity in the sensory nerve endings that detect pain, not by acting in central pathways like opiates. To do this, we use a harmless virus to shut down a vital sodium channel for pain perception. These experiments use techniques that were recently developed in our lab and cant be performed elsewhere.
Studies Of The Effects Of Asymmetric Hearing Loss On The Brain
Funder
National Health and Medical Research Council
Funding Amount
$920,076.00
Summary
Hearing loss impairs the normal development and maintenance of auditory pathways. Irreversible pathologies persist when hearing is not restored in a timely manner. While cochlear implantation is the accepted treatment for profound sensorineural hearing loss, there is significant variability in outcomes. Some of this variability is linked to the degree of hearing asymmetry. Thus, we propose to study brain changes in the auditory system that accompany asymmetric hearing impairment.
A New Mouse Model That Determines The Effects Of A Unilateral Vestibular Prosthesis On Vestibular Plasticity.
Funder
National Health and Medical Research Council
Funding Amount
$455,678.00
Summary
Much like a cochlear implant restores auditory function, a vestibular prosthesis restores balance function. It is not clear whether the limited results from vestibular prostheses is due the device not stimulating one component (the otoliths) of the vestibular system essential for self-repair. We will test mutant mice that lack otoliths to determine the importance of stimulating the otoliths in restoring function. This work will shape the future direction of prosthesis development.
Neural Basis Of The Functions Of The Primary Visual Cortex: Roles Of Feedforward And Intracortical Inputs
Funder
National Health and Medical Research Council
Funding Amount
$486,280.00
Summary
Signals from the eyes undergo extensive processing at the level of the primary visual cortex so that basic features in the scene such as lines, edges, colours and movement are coded in the activity of individual neurones. This project aims to further our understanding of this process at the basic cellular level. This will not only enable interventions that would help those with poor sight but also give us an insight into basic brain circuitry and its derangement in many neurological disorders.
Mechanisms Underlying Efferent Feedback In The Vestibular System
Funder
National Health and Medical Research Council
Funding Amount
$491,475.00
Summary
The balance system has a remarkable, but poorly understood capacity for self-repair. An intrinsic feedback mechanism, the Efferent Vestibular System or EVS is thought to play a major role in this self-repair. Surprisingly, we know little about EVS function in animals or humans. We will study the EVS in mice and humans to gain a better understanding of how it works. This information will then drive the design of therapies that improve and restore balance in disease, injury, or ageing.
Information Encoding By Temporal Structure Of Afferent Spike Trains
Funder
National Health and Medical Research Council
Funding Amount
$231,175.00
Summary
Our ability to sense, discriminate and interpret touch stimuli underpins some of the most crucial functions of the human hand that relate to object exploration and manipulation. The fundamental mechanism of how nerve impulses generated by tactile receptors are interpreted by the nervous system is not understood. Only by discovering the underlying neural encoding mechanisms can we appreciate the functional impairments in patients and learn to identify them before they become widespread and irreve ....Our ability to sense, discriminate and interpret touch stimuli underpins some of the most crucial functions of the human hand that relate to object exploration and manipulation. The fundamental mechanism of how nerve impulses generated by tactile receptors are interpreted by the nervous system is not understood. Only by discovering the underlying neural encoding mechanisms can we appreciate the functional impairments in patients and learn to identify them before they become widespread and irreversible.Read moreRead less
The Vestibulo-collic Reflex In Humans And Its Use In Diagnosis Of Vertigo
Funder
National Health and Medical Research Council
Funding Amount
$278,691.00
Summary
This project will investigate the vestibulo-collic reflex (VCR): a head-stabilising reflex of the neck muscles. The VCR plays an important role in human balance, but is not well-understood. A form of the reflex is used to test vestibular (balance) function in patients with dizziness and vertigo, however the accuracy and interpretation of the test as it is currently used is not optimal. This project aims to improve the accuracy of the VCR in the diagnosis of balance disorders.
While there has been recent excitement about possible treatments for the symptoms of Autism, advances in understanding the underlying neuroscience of abnormal brain function that underlies autistic tendency are still painfully slow. This application aims to establish fully a physiological mechanism for altered autistic perception, to see if it can be applied to early diagnosis in infants and young children and to establish whether in such plastic young brains it is possible to guide perceptual l ....While there has been recent excitement about possible treatments for the symptoms of Autism, advances in understanding the underlying neuroscience of abnormal brain function that underlies autistic tendency are still painfully slow. This application aims to establish fully a physiological mechanism for altered autistic perception, to see if it can be applied to early diagnosis in infants and young children and to establish whether in such plastic young brains it is possible to guide perceptual learning to permanent improvement.Read moreRead less
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.