Brain Plasticity Following Changes In Sensory Input
Funder
National Health and Medical Research Council
Funding Amount
$312,576.00
Summary
The research proposed here will investigate the mechanisms our brains use to adapt to changes in sensory input, as occurs following blindness, deafness, nerve damage or loss of a limb. The information gathered will help develop treatments for diseases associated with sensory loss, as well as those associated with deficits in our ability to learn and remember, such as Alzheimer's disease.
Synaptic Integration And Plasticity In The Rat Piriform Cortex
Funder
National Health and Medical Research Council
Funding Amount
$250,500.00
Summary
The human cerebral cortex is the pinnacle of evolution. It is the most complex structure known, responsible for all of those skills - like language and reasoning - that make our species so remarkable. It is also a major site of many brain diseases, like schizophrenia and epilepsy. An understanding of how the cerebral cortex works would be a remarkable achievement, of immeasurable benefit to human health. How can one go about studying such a complex structure? The strategy taken in this project i ....The human cerebral cortex is the pinnacle of evolution. It is the most complex structure known, responsible for all of those skills - like language and reasoning - that make our species so remarkable. It is also a major site of many brain diseases, like schizophrenia and epilepsy. An understanding of how the cerebral cortex works would be a remarkable achievement, of immeasurable benefit to human health. How can one go about studying such a complex structure? The strategy taken in this project is to begin by studying one of the simplest regions of the cerebral cortex, the olfactory (or piriform) cortex. The olfactory cortex is an evolutionarily ancient region of cortex, with a simpler architecture than other cortical regions. Its task is to process the sense of smell, a primitive sense that is more elaborated in lower animals than in humans. The broad goal of our research is to understand, by studying the olfactory cortex of rats, how olfactory processing occurs at the level of nerve cells (neurons). We will use a number of powerful techniques - including microelectrode recording and laser microscopy - to measure the electrical properties of individual neurons. We will also study the synaptic connections between neurons, and how these connections change following memory-inducing stimuli. It is hoped that this work will shed light on how the healthy cortex is able to process and store information, and how brain diseases cause these functions to deteriorate.Read moreRead less
Selective Modulation Of Neural Network Activity Using Focal Brain Stimulation
Funder
National Health and Medical Research Council
Funding Amount
$531,496.00
Summary
Transcranial magnetic stimulation (TMS) has been touted as a viable treatment for a range of psychiatric and neurological disorders. However, the extent to which localised TMS influences widespread brain networks remains unknown. To fill this gap, we will combine neuroimaging and TMS in healthy adults. The project will provide a scientific foundation for the use of brain stimulation as an effective tool for improving function in a range of clinical conditions.
A Role For The Pulvinar Nucleus In Visual Cortical Development And Plasticity
Funder
National Health and Medical Research Council
Funding Amount
$844,435.00
Summary
This project will investigate a part of the brain responsible for processing visual information, the pulvinar. This area has received little attention but has more recently been associated with the capacity for infants to recover vision following injuries such as stroke, as well as in mental health conditions such as schizophrenia. We will take a cell-to-system approach to uncover how this area develops and modulates the processing of visual information.
Schizophrenia affects 1 in 100 people, and yet its causes remain largely unclear. To improve understanding, treatment and management of the disease, the team performing this research will evaluate whether mobile DNA elements found in our genome are activated by stress and thereby alter how brain cells work in individuals affected by schizophrenia. They will also test whether mobile DNA can be blocked by drugs, perhaps revealing new strategies to treat the disease.