Developing A Prototype Of A Next Generation Brain Computer Interface
Funder
National Health and Medical Research Council
Funding Amount
$837,398.00
Summary
Persons affected by quadriplegia and hemiplegia from stroke and spinal cord injury have few treatment options. Brain Machine Interfaces reconnect brain to a prosthetic limb, bypassing damaged nervous system. Our group has developed a BMI that can be implanted minimally-invasively, inside a blood vessel in the brain. We propose to manufacture a world-first device for a human clinical trial pilot study. The aim is to restore mechanical control over the physical environment for a paralysed patient.
Obstructive Sleep Apnoea Phenotypes And Treatment In Quadriplegia
Funder
National Health and Medical Research Council
Funding Amount
$599,635.00
Summary
Losing function in your arms and legs after an injury (quadriplegia) is a catastrophic event. Quadriplegia also results in obstructive sleep apnoea; a condition where the throat closes repeatedly while asleep causing sleepiness, poor concentration and cardiovascular diseases like stroke. Despite most people with quadriplegia having this disease, the cause is unknown. This project will thoroughly investigate obstructive sleep apnoea causes in people with quadriplegia and test a possible treatment
Molecular Targets Of Amino Acid/neurotransmitter Conjugates Of Fatty Acids
Funder
National Health and Medical Research Council
Funding Amount
$846,390.00
Summary
This project investigates endogenous chemicals that affect cells important for detecting and responding to pain. We aim to discover how these compounds affect proteins important for nerve cell function, particularly proteins that have a prominent role in detecting and transmitting painful events. The compounds we examine are not themselves likely to be drugs, but future therapies may involve manipulating the levels of these chemicals in the body, or using drugs that mimic the activity of these c ....This project investigates endogenous chemicals that affect cells important for detecting and responding to pain. We aim to discover how these compounds affect proteins important for nerve cell function, particularly proteins that have a prominent role in detecting and transmitting painful events. The compounds we examine are not themselves likely to be drugs, but future therapies may involve manipulating the levels of these chemicals in the body, or using drugs that mimic the activity of these compounds.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.
The Molecular Basis For Target Selection In The Central Nervous System By Sensory Axons
Funder
National Health and Medical Research Council
Funding Amount
$251,325.00
Summary
The normal function of the brain depends upon the specific connections that nerve cells make with each other. These connections are set up in the developing embryo when nerve cells send out long processes - axons - which grow towards their synaptic targets. How axons select their correct targets from amongst the millions of alternatives in the developing brain is unknown. A better understanding of this problem will help us develop therapies to assist regenerating axons re-establish correct conne ....The normal function of the brain depends upon the specific connections that nerve cells make with each other. These connections are set up in the developing embryo when nerve cells send out long processes - axons - which grow towards their synaptic targets. How axons select their correct targets from amongst the millions of alternatives in the developing brain is unknown. A better understanding of this problem will help us develop therapies to assist regenerating axons re-establish correct connections following injury to the brain or spinal cord. We propose to use a simple model system, the embryo of the fruitfly Drosophila, to find molecules that are involved in this process of neuron target recognition - ' axon targeting' molecules - and to study how they work. Drosophila can be genetically manipulated in ways not possible in higher animals. Furthermore the simplicity of its nervous system means that we can determine the connections of individual nerve cells with a high degree of precision. In the first part of our project, we will examine Drosophila embryos that carry mutations in genes suspected to code for targeting molecules. We will stain individual sensory nerve cells in these embryos with dyes to reveal the anatomy of their axons in the brain. If sensory axons terminate abnormally in the brain of a given mutant, the affected gene is likely to code for an axon targeting molecule. In the second part of the study, we will investigate the functions of candidate axon targeting molecules using two approaches. Firstly, we will seek to determine whether the molecule acts in the sensory axons or in their target cells. Secondly, we will use time-lapse microscopy to study how the homing behaviour of the sensory axons is affected in mutant embryos. The results of these studies will lead us closer to an answer to the question: How do axons recognise their specific target cells in the brain?Read moreRead less
The Role Of Cell Adhesion Molecules In Regulation Of Axon Advance
Funder
National Health and Medical Research Council
Funding Amount
$426,006.00
Summary
All cells contain on their surface a class of molecules, cell adhesion molecules, that enable them to adhere to other cells in tissues. Cell adhesion molecules have long been known to be involved in the guidance of axons to their targets during development. However the molecular mechanisms by which these molecules act are largely unknown. We propose to use the powerful genetic tools available in the fruitfly to dissect the mechanisms by which two cell adhesion molecules promote axon growth.
Ultrafast Photonic Electron Microscopy: Visualising dynamics at the nanoscale. The dynamics of molecular processes are too fast to observe with any microscope so science has instead relied on recording the static before and after states of these changes, inferring what happens in between. This project aims to combine the advantages of ultrafast photonic laser control and electron microscopy to allow the direct visualisation of dynamics at the nanoscale in physical and biological systems. By prov ....Ultrafast Photonic Electron Microscopy: Visualising dynamics at the nanoscale. The dynamics of molecular processes are too fast to observe with any microscope so science has instead relied on recording the static before and after states of these changes, inferring what happens in between. This project aims to combine the advantages of ultrafast photonic laser control and electron microscopy to allow the direct visualisation of dynamics at the nanoscale in physical and biological systems. By providing a view into how order emerges from the thermal chaos of molecular objects this project aims to help to reveal the physical basis for life.Read moreRead less
New generation pulsed magnetron sputtering for the synthesis of advanced materials. Magnetron sputtering underpins the manufacture of many products ranging from semiconductor microelectronics to energy efficient windows. This project will create a new generation sputtering process fully compatible with current technology but capable of synthesising new phases and new film microstructures with greatly enhanced performance.
Prediction of solar activity and space weather by automated analyses of solar radio and magnetic field observations and simulations. This project will build world-recognised capabilities to forecast space weather events at Earth in time to take protective measures. It involves around the clock automated identification and analysis of specific solar radio bursts, forecasting solar activity that results in transients moving Earth-ward, and simulations to predict when these will reach Earth.