Structural-functional connectivity in the brain. This project aims to develop magnetic resonance imaging analysis methods to non-invasively study brain connectivity. Recent advances in imaging can comprehensively describe the brain’s complex network of functional and structural connections (the brain ‘connectome’). This project will simultaneously investigate structural and functional connectivity, and characterise the dynamic properties of the connectome using graph-theoretic approaches. This p ....Structural-functional connectivity in the brain. This project aims to develop magnetic resonance imaging analysis methods to non-invasively study brain connectivity. Recent advances in imaging can comprehensively describe the brain’s complex network of functional and structural connections (the brain ‘connectome’). This project will simultaneously investigate structural and functional connectivity, and characterise the dynamic properties of the connectome using graph-theoretic approaches. This project should give neuroscientists computational tools to comprehensively map the network architecture of the human brain.Read moreRead less
The Genetic And Environmental Determinants Of Amyloid Deposition In Older Individuals: An Amyloid Imaging Study Using The Twin Design
Funder
National Health and Medical Research Council
Funding Amount
$643,267.00
Summary
Alzheimer’s disease is characterised by the deposition of amyloid plaques in the brain. We don’t fully understand how amyloid deposition occurs and what contribution is made by genetic and environmental factors. Amyloid deposition in the brain can now be quantified during life using positron emission tomography. In this study, we will examine brain amyloid in twins, which will determine what proportion of the pathology is attributable to environmental factors that may be modifiable.
Next Generation Brain-Machine Interface: Minimally-Invasive Endovascular Stent-Electrode Array For Robotic Limb Control
Funder
National Health and Medical Research Council
Funding Amount
$1,735,574.00
Summary
Persons affected by quadriplegia and hemiplegia from stroke and spinal cord injury have few treatment options. Brain Machine Interfaces (BMIs) 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 within the brain. We propose to evaluate this device in animal studies, and continue on to a human clinical trial pilot study. The aim is to restore mechanical control over the physical env ....Persons affected by quadriplegia and hemiplegia from stroke and spinal cord injury have few treatment options. Brain Machine Interfaces (BMIs) 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 within the brain. We propose to evaluate this device in animal studies, and continue on to a human clinical trial pilot study. The aim is to restore mechanical control over the physical environment for a paralysed patient.Read moreRead less
Novel cellular functions of the microtubule-associated protein tau: Physiological and pathological implications. The social and economic burden of Alzheimer's disease (AD) is enormous, and by 2040 more than 500,000 Australians will suffer from this disease. A key histopathological hallmark of this and many other related diseases are insoluble deposits of the protein tau. Research into novel functions of tau in signalling and transport (both of which are heavily compromised in diseased brains) wi ....Novel cellular functions of the microtubule-associated protein tau: Physiological and pathological implications. The social and economic burden of Alzheimer's disease (AD) is enormous, and by 2040 more than 500,000 Australians will suffer from this disease. A key histopathological hallmark of this and many other related diseases are insoluble deposits of the protein tau. Research into novel functions of tau in signalling and transport (both of which are heavily compromised in diseased brains) will be followed directly by assay development for tau-directed drug screening. The national benefit of this research is manifold by (a) patenting new data, (b) developing treatment strategies for an un-curable disease, and (c) establishing links to the growing Australian biotech industry (in addition to existing links to international pharmaceutical companies).Read moreRead less
The biological and pathological functions of TDP-43. The social and economic burden of neurodegenerative such as MND is enormous. A key histopathological hallmark of this and many other related diseases are deposits of the protein TDP-43. Our research aims at understanding its largely unknown functions, for example by generating transgenic animal models. These will form the base for the development for a TDP-43-directed drug treatment. The national benefit of this research is manifold: by deciph ....The biological and pathological functions of TDP-43. The social and economic burden of neurodegenerative such as MND is enormous. A key histopathological hallmark of this and many other related diseases are deposits of the protein TDP-43. Our research aims at understanding its largely unknown functions, for example by generating transgenic animal models. These will form the base for the development for a TDP-43-directed drug treatment. The national benefit of this research is manifold: by deciphering basic biological mechanisms, patenting new data, developing treatment strategies for un-curable and fatal disorders, and expanding links to Australian biotech and international pharmaceutical companies.Read moreRead less
Neuronal functions of the microtubule-associated protein tau in development and ageing. The project uses a combination of transgenic mouse strains characterised by neurodegeneration and senescence-accelerated (SAM) mice, to determine the first steps of the aggregation of the protein tau in degenerating neurons, how absence of tau protects from brain atrophy, and in which physiological processes tau is involved. This project provides the biological foundation for a tau-based therapy of senescence ....Neuronal functions of the microtubule-associated protein tau in development and ageing. The project uses a combination of transgenic mouse strains characterised by neurodegeneration and senescence-accelerated (SAM) mice, to determine the first steps of the aggregation of the protein tau in degenerating neurons, how absence of tau protects from brain atrophy, and in which physiological processes tau is involved. This project provides the biological foundation for a tau-based therapy of senescence-associated conditions. It provides the biological foundation for developing effective therapies for human neurodegenerative conditions, by preventing tau aggregation and phosphorylation. We will patent new data and expand our existing links to Australian biotech and international pharmaceutical companies.Read moreRead less
Non-invasive measurement of intracranial pressure by means of transcranial doppler blood flow and central aortic pressure. The investigation will produce a device that will aid doctors measuring brain pressure without drilling holes through the skull. The device will use the technology of an Australian company that has the only patented system to deduce the pressure in the brain by measuring pressure close to the heart and the brain and by recording the pressure pulse wave at the wrist. The comm ....Non-invasive measurement of intracranial pressure by means of transcranial doppler blood flow and central aortic pressure. The investigation will produce a device that will aid doctors measuring brain pressure without drilling holes through the skull. The device will use the technology of an Australian company that has the only patented system to deduce the pressure in the brain by measuring pressure close to the heart and the brain and by recording the pressure pulse wave at the wrist. The community benefit will be in terms of the safety and ease with which changes in pressure in the brain can be detected. It will also advance the world renowned Australian technology in a new area of application.Read moreRead less
Optimizing autonomous system control with brain-like hierarchical control systems. Autonomous robotic systems, those requiring minimal ongoing supervision, have enormous commercial, medical and industry potential. A robotic hand, permitting manipulation of material objects is an integral part of robot function. Many aspects of human hand control, such as learning, fine motor control, context-specific adaptation and recovery from system damage would be greatly beneficial to a robotic hand. Likewi ....Optimizing autonomous system control with brain-like hierarchical control systems. Autonomous robotic systems, those requiring minimal ongoing supervision, have enormous commercial, medical and industry potential. A robotic hand, permitting manipulation of material objects is an integral part of robot function. Many aspects of human hand control, such as learning, fine motor control, context-specific adaptation and recovery from system damage would be greatly beneficial to a robotic hand. Likewise, theories of human hand control could be subject to empirical testing by implementing them in a robotic hand. These advances will greatly benefit our understanding of the human brain, with potentially wide-ranging medical benefits such as novel prosthetic limb design and rehabilitation strategies for stroke patients.Read moreRead less
Industrial Transformation Training Centres - Grant ID: IC170100030
Funder
Australian Research Council
Funding Amount
$4,133,659.00
Summary
ARC Training Centre in Cognitive Computing for Medical Technologies. The ARC Training Centre in Cognitive Computing for Medical Technologies aims to create a workforce that is expert in developing, applying and interrogating cognitive computing technologies in data-intensive medical contexts. This will facilitate the next generation of data-driven and machine learning-based medical technologies. The Centre will provide a world-class industry-driven research training environment for PhD students ....ARC Training Centre in Cognitive Computing for Medical Technologies. The ARC Training Centre in Cognitive Computing for Medical Technologies aims to create a workforce that is expert in developing, applying and interrogating cognitive computing technologies in data-intensive medical contexts. This will facilitate the next generation of data-driven and machine learning-based medical technologies. The Centre will provide a world-class industry-driven research training environment for PhD students and postdoctoral researchers. These researchers will lead the medical technology industry into a new era of data-driven personalised and precision medical devices and applications. The Centre will result in the development of capabilities in the core technologies of machine learning and the practical application of cognitive computing in the area of health.Read moreRead less