Cell Death In The Retina: Analysing The Switch That Triggers Dependency On Target-derived Trophic Factors
Funder
National Health and Medical Research Council
Funding Amount
$428,414.00
Summary
Construction of the developing nervous system in the embryo involves the creation of nerve cells and their connections, but also involves loss of a proportion of these cells prior to maturation. We will study this process of cell death and how developing nerve cells switch on their dependency to survival factors. In so doing we will better understand what happens when brain development goes wrong and also devise new ways to protect nerve cells in the injured or degenerate adult nervous system.
Blood-brain Barrier And White Matter Damage In The Immature Rat Brain Following Systemic Inflammation
Funder
National Health and Medical Research Council
Funding Amount
$353,173.00
Summary
Clinical obstetric and paediatric studies have identified an association between intrauterine infection occurring around two thirds of the way through pregnancy, premature birth and a specific form of damage to the brain of the newborn. This damage mainly affects white matter tracts. These tracts are aggregations of nerve fibres that make the connections between different parts of the brain and may result in cerebral palsy or other neurological disorders. The association between maternal infecti ....Clinical obstetric and paediatric studies have identified an association between intrauterine infection occurring around two thirds of the way through pregnancy, premature birth and a specific form of damage to the brain of the newborn. This damage mainly affects white matter tracts. These tracts are aggregations of nerve fibres that make the connections between different parts of the brain and may result in cerebral palsy or other neurological disorders. The association between maternal infection and brain damage, one form of which is cerebral palsy, is well established from clinical epidemiological studies, but the biological mechanism of this link is unknown. The CIs' group has recently shown that the condition can be reproduced in neonatal rats at a stage of brain development in the rat that is equivalent to the critical time in human brain development when infection may be associated with brain damage. The CIs' group has shown that an induced inflammatory state similar to a bacterial infection, results in damage to blood vessels in the white matter and is associated with changes in white matter, as occurs in affected babies. The purpose of this study is to understand the nature of the damage to white matter blood vessels and the mechanisms by which materials in blood, which in the normal brain do not pass from the blood to the brain across the blood-brain barrier, are able to do so via the inflammation damaged blood vessels. The study also aims to show whether it is components of the blood entering the brain via the damaged blood vessels that are responsible for the damage to white matter in the immature brain. The outcome should lead to development of ways to improve clinical care of women who acquire infections during pregnancy.Read moreRead less
Imaging Atlases Of The Brain Of Humans And Experimental Animals
Funder
National Health and Medical Research Council
Funding Amount
$808,375.00
Summary
This project uses imaging techniques and molecular genetics to produce the next generation of brain maps. It will advance our understanding of the organisation and structure of the brain and spinal cord of humans and experimental animals – paving the way for the development of psychotherapeutic drugs and more accurate interventions on the human brain. The new maps will help those who study the brain of patients with diseases such as Alzheimer’s or Parkinson’s or animal models of these diseases.
Muscarinic Receptors In The Human Brain: In Health And In Sickness
Funder
National Health and Medical Research Council
Funding Amount
$394,408.00
Summary
Schizophrenia is a severe mental illness, with sub-optimal treatment outcomes. New drugs are being designed to provide more effective treatment. To understand the effects of these drugs, we need to know which brain cells have the protein these new drugs target and which cells are affected in schizophrenia. Our project will determine the localisation of this drug target; this knowledge will help the development of better treatments for schizophrenia.
Central Neural Regulation Of Brown Fat Function – Glucose Sensing And CNS Pathways
Funder
National Health and Medical Research Council
Funding Amount
$761,942.00
Summary
Our research aims to identify how specific brain cells detect changes in glucose levels and how ageing and diet affect their function. We identified a subset of nerve cells that detect changes in glucose and the “hunger” hormone ghrelin, their ability to do so adapting with age and nutritional status. This project will investigate the potential of these nerve cells as targets for therapeutic and diet- intervention strategies to target obesity, diabetes and promote healthy ageing.
Investigating Cortical Plasticity And Connectivity In People With Chronic Low Back Pain And Controls Using Combined TMS_EEG
Funder
National Health and Medical Research Council
Funding Amount
$318,768.00
Summary
Little is known about the factors that predispose the development of chronic low back pain or what changes underpin effective treatment. Brain changes, thought to reflect adaptive processes are associated with chronic pain, but the extent of their contribution to CLBP is unknown. By measuring the adaptability of brain changes in people with CLBP I will determine if they differ from healthy controls in a way that predisposes them to develop chronic pain and is related to treatment response.
Understanding The Role Of Caudal Auditory Belt Areas In Perception Of Complex Sounds
Funder
National Health and Medical Research Council
Funding Amount
$773,518.00
Summary
Although the auditory cortex is key to our understanding of several neurological conditions, including language impairments, the functions of many of its areas are still unknown. Using an animal model, we will examine the roles of different auditory areas in separating important sounds from noise. This is a critical role in coordinating our body’s responses to acoustic stimuli. This study will help clarify how these areas contribute to how we normally process sounds, and what deficits are likely ....Although the auditory cortex is key to our understanding of several neurological conditions, including language impairments, the functions of many of its areas are still unknown. Using an animal model, we will examine the roles of different auditory areas in separating important sounds from noise. This is a critical role in coordinating our body’s responses to acoustic stimuli. This study will help clarify how these areas contribute to how we normally process sounds, and what deficits are likely to occur if they are damaged.Read moreRead less
We are able to identify and discriminate objects in the world because of exquisitely detailed and rapid processing of sensory information by neurons in the cortex of the brain. In this project we will examine these operations in neurons in the cortex that receive input from the large face whiskers of the rat. These whiskers are used for fine-grain discrimination and for gauging distance. They are deflected by being actively moved, under muscle control, over objects (active touch) or by being pas ....We are able to identify and discriminate objects in the world because of exquisitely detailed and rapid processing of sensory information by neurons in the cortex of the brain. In this project we will examine these operations in neurons in the cortex that receive input from the large face whiskers of the rat. These whiskers are used for fine-grain discrimination and for gauging distance. They are deflected by being actively moved, under muscle control, over objects (active touch) or by being passively deflected by objects. Deflection results in inputs to the brain that are processed to form the neural basis for very finely detailed perceptual behaviour. In rats, with impoverished visual and auditory senses, the whiskers are the major sensory system for interacting with the world, and are used in navigating the environment and in finding and distinguishing foods. Thus they contribute strongly to the remarkable success of this species. This elegant sensory system has a number of advantages that make it a very good model for the study of brain mechanisms responsible for active fine-grain sensory function. We plan to take advantage of the unique features of this system to define the information processing that occurs in the cortex in this elegantly complex system. This will address an issue relevant to all sensory systems - namely the neural basis of complex fine grain perceptual behaviour. Understanding the mechanisms underlying active tactile perception also has relevance to clinical conditions involving deficits in active touch e.g., in diabetic polyneuropathy (which eventually affects ~50% of diabetics), in leprosy (in which an early sign is damage to active touch). Knowledge of the core brain processes in active touch gained in this study could eventually underpin the ameliorative technologies for such deficits.Read moreRead less